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Master Thesis
Vegetation survey and GIS-based zonation of the Fond d'AlbaretzForest, Praslin, Seychelles
Author(s): Farrèr, Claudia; Hertach, Martin
Publication Date: 2009
Permanent Link: https://doi.org/10.3929/ethz-a-005791819
Rights / License: In Copyright - Non-Commercial Use Permitted
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Vegetation Survey and GIS-based Zonation of the FondD’Albaretz Forest, Praslin,Seychelles
Master Thesis in Environmental Sciences
Claudia Farrèr Martin Hertach
March, 2009
Supervision: Dr. Karl Fleischmannand Prof. Peter J. Edwards
Institute of Integrative Biology Zurich
Abstract
The Seychelles flora displays a high degree of endemism and various endemic woody species are
threatened according to the IUCN Red List. The habitats of rare endemic species are often confined to
boulder fields and glacis. Threats are competition by invasive species, forest fires and anthropogenic
habitat degradation. To preserve habitats it is crucial to understand possible interconnections between
the vegetation composition, boulder fields and fire disturbances. We investigated these interconnections
in the area of the Fond D’Albaretz on Praslin Island, which is part of a unique ecological framework and
shelters large interlinked boulder fields.
An extensive database on the vegetation composition was acquired by means of count-plot analysis and
trail transecting. Vegetation zonations were conducted in terms of (i) nativeness, (ii) protection values
and (iii) presence of red listed species. Connection between the occurrence of boulder fields and palms
was studied with a boulder field classification. Spatial data on the occurrence of boulder fields and large
patches of the fern Dicranopteris linearis were gained using satellite images, a geographic information
system (GIS) and the global positioning system (GPS). We also studied post-fire succession by
qualitatively monitoring recently affected areas. To visualize the risk of the induction and the spread of
fire, we produced a fire risk map by including topographic, anthropogenic and vegetation-based
parameters.
Based on prominence values, we found that 75.4% of the vegetation of the Fond D’Albaretz is native
and 20.7% is endemic. Twenty-one different endemic species were found, one of which was classified as
“critically endangered”, one as “endangered”, eleven as “vulnerable”, five as “near threatened” and three
as “least concern”. The vegetation zonation reveals a uniform high protection value of the forest and is
therefore comparable to the Vallée de Mai. We found a significant correlation between the presence of
big boulders and palms (adults and saplings). We also found a moderate significance for the correlation
between the presence of big boulders and threatened species. Interpretation of satellite images and
spatial mapping in the field showed that boulder fields cover an area of 46’437 m2. Resprouting in post-
fire-areas is dominated by endemic species. Most of the area of the Fond D’Albaretz shows a high risk of
spreading or inducing forest fires.
The Fond D’Albaretz is of high ecological importance due to its consistently high protection value, its
comparability to the Vallée de Mai and its relics of original low-altitude forest. The extensive boulder
fields are a hideaway for threatened plant species and protect them from forest fires. The limited
presence of Dicranopteris l. and invasive species suggests that forest fires only rarely affected the Fond
D’Albaretz in the past. The protective force of boulder fields against fires, the absence of preceding
disturbances and the ecological framework seem to be the main reasons for the high ecological value
distinctive of the Fond D’Albaretz. The use of GIS proved to be very valuable and the newly established
fire risk map can be used as a measure to effectively fight forest fires in the future.
Keywords: Ecological importance, Boulder field classification, Protection value, Vegetation zoning,
Dicranopteris l., Red listed woody plant species, Geographic information system, Fire risk map, Fond
D’Albaretz, Praslin, Seychelles.
Acknowledgements
We would like to thank our supervisors Dr. Karl Fleischmann and Prof. Peter J. Edwards from the
Institute of Integrative Biology, ETH, for the possibility to write this master-thesis and for their overall
support.
Special thanks go to Matthieu and Bart LaBuschagne and their families who made this work possible.
Your support with all our daily life and work problems was fantastic. Matt, we thank you for all the
adventurous trips in the forest. We have spent an unforgettable time in the Seychelles!
Many thanks go also to the staff of the Hotel Coco de Mer for cheering up our days, for cooking and
joining us in the staff canteen and for their kindness to provide internet access.
A special thank goes to our neighbours Sudarsana Weliwitigoda and Don Jagath Katugampola with his
wife Ayomi and their daughter Suchali. Thank you for all the good times we spent at your home, the
delicious food and all the nice talks. We will miss you!
Many thanks go to the Plant Conservation Action group (PCA) and especially to Katy Beaver, Frauke
Fleischer-Dogley and Lindsay Chong Seng for administrative help, accommodation and inputs for our
work. It is always a great pleasure to meet you!
We would like to thank Victorin Laboudallon for the insightful walk and helping us with identifying
species.
We are thankful to Justin Prosper from the GIS-Unit at the Policy Planning and Services Division of the
Ministry of Environment on Mahé for providing us with all the needed spatial data of Praslin.
We are grateful to the Praslin Development Fund (PDF), where we thank the chairman Mr. Michel
Gardette for organising us the permit to visit the Fond Ferdinand Nature Reserve and Micheal Gill who
was a great guide in the field and helped us to locate former plots.
Special thanks go to Patrizia Frei for statistical support, inputs for writing the report and unforgettable
two weeks in the Seychelles.
We thank Karsten Rohweder and Hans-Heini Vogel from the Institute of Integrative Biology, ETH, for
providing us with even in the tropics astonishing good working laptops and for their technical support
by finishing our thesis.
Last but not least, we would like to thank our parents for their overall support.
Content
1. Introduction.................................................................................................................................1
2. Methods ........................................................................................................................................4
2.1 General principles .................................................................................................................................... 4
2.2 Trail transecting........................................................................................................................................ 4
2.3 Count-plot analysis................................................................................................................................... 6
2.4 Photo monitoring..................................................................................................................................... 7
2.5 Boulder field classification....................................................................................................................... 8
2.6 Vegetation zoning..................................................................................................................................... 9
2.7 Dicranopteris linearis survey...................................................................................................................... 13
2.8 Boulder field mapping ........................................................................................................................... 14
2.9 Qualitative monitoring of post-fire areas............................................................................................... 14
2.10 Fire risk map......................................................................................................................................... 15
3. Results ....................................................................................................................................... 17
3.1 Fond D’Albaretz - State of the forest ..................................................................................................... 17
3.1.1 General findings ....................................................................................................................... 17
3.1.2 Prominence along trail transects.............................................................................................. 17
3.1.3 Prominence within sampling plots .......................................................................................... 19
3.1.4 Red listed species...................................................................................................................... 21
3.2 Boulder field classification..................................................................................................................... 22
3.2.1 Palms vs. dicotyledonous trees ................................................................................................. 23
3.2.2 Threatened species vs. invasive species .................................................................................... 24
3.3. Vegetation zoning.................................................................................................................................. 25
3.4 Correlation between Dicranopteris l. and invasive species ..................................................................... 26
3.5 Occurrence of boulder fields ................................................................................................................. 27
3.6 Qualitative monitoring of post-fire areas............................................................................................... 27
3.7 Fire risk map........................................................................................................................................... 30
3.8 Trail towards Glacis Noir - State of the forest....................................................................................... 31
3.8.1 Prominence along trail transects.............................................................................................. 31
3.8.2 Vegetation zoning..................................................................................................................... 31
4. Discussion and conclusions ..................................................................................................... 32
4.1 Species composition............................................................................................................................... 32
4.2 Ecological value ...................................................................................................................................... 33
4.3 The role of boulder fields....................................................................................................................... 34
4.4 Future trends .......................................................................................................................................... 34
4.5 Dicranopteris l. and the abundance of invasive species .......................................................................... 35
4.6 Comparison of the Fond D’Albaretz with the adjacent area towards Glacis Noir.............................. 35
4.7 Post fire regeneration ............................................................................................................................. 36
4.8 Fire risk map........................................................................................................................................... 37
4.9 Synthesis ................................................................................................................................................. 37
4.10 The potential for ecotourism............................................................................................................... 39
4.11 Recommendations ............................................................................................................................... 40
4.12 Suitability of methods .......................................................................................................................... 42
Literature ....................................................................................................................................... 44
Appendix ....................................................................................................................................... 46
- 1 -
1. Introduction
Background
The Seychelles are a group of 115 islands situated in the Indian Ocean between the latitudes 4° – 10° S
and longitudes 55° – 56° E and are therefore located within the tropical climate zone. They are divided
into the outer (coralline) and the inner (granitic) islands. There is evidence that the islands split from
Gondwanaland about 65 million years ago. Since then the Seychelles have been isolated from continents
and a unique vegetation has developed containing approximately 50 endemic woody species (Friedmann
1994).
Since the first human settling in 1770, many unique species of the indigenous flora are in danger of
extinction (Swabey 1970) and restricted to patches of relic vegetation. The most serious threats to the
endemic plants of the Seychelles nowadays are, besides a limited regeneration, the invasion by alien
species (Fleischmann et al. 2005) and the local extinction and habitat degradation by forest fires
(Carlström 1996). Invasive species are nonindigenous species capable of establishing and spreading
significantly within natural communities (Les et al. 1999).
A notably high abundance and diversity of endemic species can be found on glacis (Kueffer et al. 2004),
which comprise one of the most important vegetation types of the granitic islands. According to
Fleischmann et al. (2003) glacis are solitary, often monolithic rocks or parts of mountain systems, which
rise abruptly from their surroundings. They belong to the least invaded habitat types (Fleischmann
1997).
Praslin is with an area of 37km2 (Fleischmann 1997) the second largest island of the inner Seychelles
and reaches a height of 367m a.s.l. (Walsh 1984). Whereas the Seychelles are identified as a biodiversity
hotspot (Conservation International) and as a center of plant diversity (WWF and IUCN) (Fleischmann
et al. 2003), Praslin is even more special due to the sheltering of the Vallée de Mai, a UNESCO World
Heritage site. With a mean annual rainfall on Praslin (Bay Ste Anne) of about 2130mm, the climate is
slightly drier than on the other Seychelles islands (Carlström 1996).
Due to forest fires, there are considerable areas of bare erosion slopes on Praslin where often the
possibly native fern Dicranopteris l. can be found (Carlström 1996). It is a robust fern which survives well
in poor soil conditions (Russell et al. 1998). In cleared forest areas it forms large masses (Beaver 1994)
and prevents all other species from growing (Carlström 1996). Thus when establishing after a fire event
it poses a problem because it can prevent trees from regenerating and change the forest structure
(Kueffer et al. 2004). Dicranopteris l. is highly inflammable (Swabey 1970) and might increase the risk of
fire, especially during drought periods (Ikin et al. 2005). A positive aspect of a dense population of
Dicranopteris l. is its extensive root system, which can prevent soil from erosion (Beaver 1994).
The study
To prevent biodiversity-loss and for the relic vegetation to survive, a better understanding of the
interconnections between vegetation composition, tree regeneration, forest fires and the significance of
boulder fields is crucial. The privately owned area of the Fond D’Albaretz on Praslin is an ideal study
site to research those interdependencies and human impacts. The low-altitude forest of the Fond
D’Albaretz is considered an area of special conservation value (Carlström 1996). It is located in the calm
south-east of Praslin in the direct neighborhood of the Praslin Nation Park and the Fond Ferdinand
(Fig. 1), both being floristic hotspots. Two forest fires affected the Fond D’Albaretz in 2008. Over the
steep slopes of the Fond D’Albaretz, a dense network of boulder fields is spread, whose vegetation is very
similar to those of glacis (Plant Conservation Action group 2007).
Introduction
- 2 -
Fig. 1: Map of Praslin showing the study site
The Fond D’Albaretz shows an attractive potential for ecotourism and is owned by the Hotel Coco de
Mer, which aims at keeping up the biodiversity of the forest and protect endemic species by a sustainable
management of the forest. Thus alien or problematic species like Cinnamomum v., Chrysobalanus i. and
Dicranopteris l. are partly removed from time to time and replaced by endemic species. In the last years
approximately 30 nuts of Lodoicea m. and about a hundred seedlings of Deckenia n. and Nephrosperma v.
have been planted. To make use of the ecotouristic potential, a nature trail is maintained. The hotel-
guests have the possibility to visit the Jean-Baptiste Nature Trail several times a week on a guided hike.
Previous studies showed the high ecological quality of the Fond D’Albaretz (Bollier et al. 2004, Héritier
2002). A forest zoning performed by Héritier (2002) distinguished between three different forest types:
“Palm forest with rejuvenation by native species”, “broad-leafed forest with rejuvenation by native species” and
“invaded forest with rejuvenation by native species”. The relationship between boulders and vegetation was
studied by Baader & Hendry (2007) in the La Reserve area on Mahé. They showed a significant
correlation between big boulders and palms, and between small or no boulders and dicotyledonous
trees. Post-fire succession was investigated by Meuwly (2002) in the area of the Fond Ferdinand on
Praslin. Two areas were researched, one burned down in 1989 and one in 1999. Introduced species were
found to use the fire-avoiding strategy whereas native species use the fire resisting strategy and possess a
higher resprouting capacity.
So far the Fond D’Albaretz was only surveyed roughly. To obtain a good database, a more
comprehensive survey was needed. This also applies for the boulder analysis where additional aspects
like the role of boulders for threatened endemic species or the role of boulder fields as a sanctuary
protecting plants from fires can be investigated.
The hypothesis of this study is that the Fond D’Albaretz has an outstanding kind of vegetation because
it is part of a unique ecological framework, there is a lack of severe fire disturbances and human impact
and there is an extensive presence of boulder fields.
Introduction
- 3 -
To test our hypothesis, we aim at the understanding of the following scientific questions:
• What is the species composition and stand structure of the Fond D’Albaretz?
• What is the ecological value of the forest and which areas are of special interest in terms of
protection values and threatened species?
• Can the findings of Baader & Hendry (2007) regarding boulder fields and the prominent
presence of palms be confirmed?
• Are there other correlations between boulder fields and the type of vegetation (e.g. threatened
species)?
• What is the potential of the Fond D’Albaretz forest in terms of ecotourism?
• Does Dicranopteris l. influence tree regeneration and the vegetation composition?
• Is there a difference in the ecological values between the Fond D’Albaretz and his north-western
back side towards Glacis Noir?
• How is the vegetation composition affected by fire events?
• What impact do forest fires have on the succession and regeneration of native and alien plant
species?
• Which areas of the Fond D’Albaretz pose high risk to induce or spread forest fires?
• Is a lack of fire events a reason for the high ecological value of the Fond D’Albaretz?
• Do boulder fields enhance the conservation value of the study site?
Our objectives are:
• … on vegetation survey: Evaluate the stand structure, the state of species rejuvenation and the
species composition of the forest and predict future trends.
• … on the presence of boulder fields: Record the occurrence of boulder fields and the most
abundant plant species along the trails. Determine the corresponding boulder field class.
• … on zoning of the forest: Locate and validate the areas of high ecological significance with the
help of a geographic information system. Develop a forest zoning based on the following
features: (I) nativeness, (II) conservation value (III) presence of red listed plants.
• … on vegetation monitoring: Provide a detailed monitoring methodology and an extensive
database for future surveys.
• … on forest management and invasion monitoring: Give advises for the management of the
forest with a special focus on the spread of alien invasive plant species.
• … on Geographic Information System: Utilize this tool and prove that adequate use of a GIS-
based vegetation research can substantially increase the quality of vegetation surveys.
• … on general description of the burned areas: Visit the two burned areas in the Fond Ferdinand
and the two burned areas in the Fond D’Albaretz and give a general description of the state of
the areas.
• … on post-fire succession: Find out to which extent forest fires have an impact on the
occurrence and regeneration of native and alien invasive species.
• … on the mapping of boulder fields: Develop a map of boulder fields by means of interpretation
of satellite images and mapping directly in the field.
• … on mapping and evaluation the occurrence of the fern Dicranopteris l.: Record all patches of
Dicranopteris l. in the immediate vicinity of the trails within the study site.
• … on fire risk map: Develop a fire risk map for the study site by means of different parameters.
- 4 -
2. Methods
2.1 General principles
To determine the rejuvenation of species it is crucial to distinguish between different life-forms of
plants. Thus all plant-recordings are separated into the three life-forms seedlings, saplings and adults
(Tab. 1).
Tab. 1: Definition for seedling, sapling and adult according to Fleischmann (2005);
dbh: diameter at breast height (80 cm)
Dicotyledonous Trees Palms
Height dhb Leaves True stem
Seedling < 0.5m < 3cm < 100cm no
Sapling 0.5 - 2m < 3cm > 100cm no
Adult > 2m > 3cm > 100cm yes
Basis for the nomenclature are Friedmann (1994) for dicotyledonous and Robertson (1989) for
monocotyledonous plants. The red list status of endemic plants is based on Huber & Ismail (2006).
Global Positioning Service (GPS) was used in the field as a measure to obtain georeferenced data. We
used a Garmin GPSMap 60Csx, which was in any case more accurate than ± 6m. Spatial and
geostatistical analyses and mapping tasks were carried out using ArcGIS 9.2 (ESRI, Redlands, CA,
USA).
2.2 Trail transecting
The aim is to describe the present state of the forest by determining abundances, frequencies,
prominences and rejuvenation of woody plant species. Data gained by performing trail transecting
provide the basis for evaluating the conservation value of the forest and for the forest zoning. The
method is very useful to get an overview of the species composition in a forest area.
While walking along a trail, at every 2m the most abundant seedling, the closest sapling and the closest
adult tree perpendicular to the trail are recorded. The measuring-units are sub-transects of 200m, which
consist of 100 sampling-points. To describe a certain area of interest, sub-transects are summed up to
transects.
The vegetation in the study area is represented by two different transects (Fig. 2): The Jean-Baptiste
Nature Trail consisting of eight sub-transects and the expanded Nature Trail consisting as well of eight
sub-transects. For being able to study differences between the Fond D’Albaretz and the other side of the
hill transecting in two additional sub-transects along the trail towards Glacis Noir was performed (Fig.
2). A total transect length of 3.6km was covered.
Following equipment is required: Measuring tape, standardized protocol sheet, pen, GPS.
Methods
- 5 -
Fig. 2: Map of the study site showing sampling plots and trail-transects.
Data Treatment
To gain prominence values for all recorded species, the data is processed as follows. Abundance classes
(Tab. 2) based on numbers of individual species in sub-transects of 100 plant-recordings are determined
after Fleischmann (1997).
Tab. 2: Abundance-classes adopted from Fleischmann (1997)
Abundance-Class # individuals per
sampling unit
1 1
2 2-4
3 5-8
4 9-16
5 17-32
6 33-64
7 >64
The relative frequency fij of a species i within an individual sampling-plot j is calculated as:
100xn
nf
j
ij
ij = (eq. 1)
where nij is the number of sampling units in sampling-plot j having species i and nj the number of
sampling units in sampling-plot j.
Methods
- 6 -
The prominence values PVij for a species i in sampling-plot j is calculated based on the relative frequency
and the relative abundance of a certain species as:
100100 xa
a
xf
fPV
i k
ijk
k
ijk
i
ij
ij
ij
∑∑
∑
∑+= (eq. 2)
where fij is the frequency of species i in sampling-plot j and aijk the abundance class value of species i in
sampling unit k of sampling-plot j.
2.3 Count-plot analysis
The aim is to gain a plant-inventory expressed by the prominence values of the recorded species. This
method provides information on the stand structure and rejuvenation of the forest.
The sampling plots of 10x10m are divided into four sub-plots of 5x5m (Fig. 3). The northern edge of the
sampling plot is manifested by a marker tree. Starting from the marker tree, the other three edges are
determined by using a compass and a measuring tape.
Fig. 3: Schematic sketch of a sampling plot.
All plants within a sampling plot are counted and recorded according to their life-form (Tab. 1). For
every individual adult broadleaved tree, the diameter at breast height (dbh; 80cm) is measured. For trees
with more than one branch originating from the same trunk, the dbh is summed up. Due to the fact
that palms do not have a secondary growing the height of the trunk up to the point where the most
upper leaf sprouts is measured instead of the dbh. This measurement is done with a clinometer (Suunto
Oy, Finnland) which measures the angle between the ground and the desired top-point of the tree and a
measuring tape that gives the distance from the sampling point to the palm. In a next step, the height h
of palms can be calculated as:
( ) tmeasuremenhdh += )tan(* α (eq. 3)
where d is the measured distance from the tree to the sampling point, α the measured angle and hmeasurement
the height of the clinometer above ground.
0m
10m
5m
Methods
- 7 -
A total of nine permanent sampling plots with each an extent of 10x10m have been established within
the study area (Fig. 2). This leads to a total sampling area of 900m2. The marker trees of all sampling
plots are indicated with yellow plastic bands to allow a resurvey. Additionally, accurate GPS-coordinates
were recorded and sketch-maps were designed (Re. digital appendix G).
Following equipment is required: Measuring tape (25m), yardstick, plastic marker band, standardized
protocol sheet, pen, compass, GPS and clinometer.
Data Treatment
Prominence values are calculated as described in chapter 2.2. As an additional value the relative
dominance can be determined as follows.
Based on the dbh-measurements and counted adult individuals of a species, the relative dominance RDij
of species i in transect j can be calculated as:
100xa
aRD
j
ij
ij = (eq. 4)
where aji is the cumulated dbh-area of species i in sampling-plot j and aj the cumulated dbh-area of all
species in sampling-plot j.
2.4 Photo monitoring
The photo monitoring is performed as an additional measure to document the sampling plots and the
trail transects. The aim is to visually document the actual state of the vegetation. The photo monitoring
gives an insight into the species succession (growth, species recruitment and mortality) within a count
plot and along a trail transect.
Procedure when used in the trail transecting
At each start- and end point of a trail sub-transect two pictures are taken: One general view from the
middle of the transect line due south (1.3m above ground) and one picture of the ground-cover (1.3m
above ground) showing 0.25m2 at the left side of the transect line.
Procedure when used in the count-plot analysis
In every permanent plot one general view of the plot (1.3m above ground) and four ground-cover
pictures in each corner of the plot (1.3m above ground) showing 0.25m2 of the ground are taken. The
general view picture is taken in the northern edge due south giving a view over the whole plot.
The following equipment is required: Digital camera (with standardised settings), measuring tape,
compass, a 0.5m x 0.5m frame for the photo plots, protocol sheet, pen, GPS.
Methods
- 8 -
2.5 Boulder field classification
Developed by Bader & Hendry (2007) this method aims at understanding a possible connection
between the occurrence of boulder fields and palms.
To understand the possible relationship between the occurrence of boulder fields and certain plant
species a modified version of the boulder field classification according to Baader & Hendry (2007) is
performed in this study. To get a more comprehensive database, the trail transecting steps are reduced to
2m instead of 2.22m and therefore the boulder field classification is done every 10m instead of 11.1m.
The boulder field classification is performed together with trail transecting. At every 5th sampling point
(every 10m) the occurrence of boulders is estimated by recording following data: The size (length and
height) of the two main boulder-groups and the ground-coverage by boulders in percent. Additionally
the most abundant plant species (adult and sapling) are recorded. Those recordings are made
perpendicular to the trail for both sides considering a 10m-belt. According to the collected data, the
boulder classes (Tab. 3) can be determined and correlated with the plant species.
Boulder field classification is performed together with trail transecting, i.e. data was collected along a
total length of 3.2km transect-lines.
The following equipment is required: Measuring tape, standardized protocol, pen, GPS.
Data Treatment
The collected field data is classified according to the boulder-classes and the ground-cover by boulders
(Tab. 3). It is assumed that each boulder is a square of a classified size (i.e. boulder size class). If the
obtained data (height and length) do not fit within a boulder class, it was decided that the length is the
determining factor. An exception is made when the height of a boulder fits in class 5 but not the length.
In this case the boulder is classified within class 5. If two different boulder sizes are recorded but they do
not fit the same class, the bigger boulder class is decisive. The ground-cover by boulders is differentiated
between less than 50% and more than or equal to 50%.
Tab. 3: Boulder field classification according to Baader & Hendry (2007)
Class Description Cover Definition
1 Area without boulders 0 -
1a Area without boulders between bluffs of rocks 0 No boulders
2 Boulder field with small boulders ≥ 50% H: ≤ 0.5m, L: ≤ 0.5m
2a Area with a few small boulders < 50% H: ≤ 0.5m, L: ≤ 0.5m
3 Boulder field with mixed boulder sizes ≥ 50% H,L: > 0.5m and ≤ 2m
3a Area with a few different sized boulders < 50% H,L: > 0.5m and ≤ 2m
4 Boulder field with huge boulders ≥ 50% 2m < H ≤ 4m, 2m < L ≤ 8m
4a Area wiht a few huge boulders < 50% 2m < H ≤ 4m, 2m < L ≤ 8m
5 Bluffs of rock - H > 4m, L > 8m
Chi-square-Tests and Mann-Whitney-U-Tests were carried out using SPSS Statistics version 17.0 (SPSS
Inc., Chicago, Illinois, USA). Using this kind of statistics, we assessed (1) the correlations between big
boulders & palms and small or no boulders & dicotyledonous trees, (2) the correlations between
ground-coverage by boulders of more than 50% & palms and ground-coverage by boulders of less than
50% & dicotyledonous trees and (3) the correlations between big boulders & threatened species and
small or no boulders & invasive species.
Methods
- 9 -
2.6 Vegetation zoning
Based on the georeferenced data gained by trail transecting, a forest zoning is performed to locate and
validate important areas in terms of (I) nativeness, (II) protection values and (III) presence of red listed
plants.
Forest zoning based on nativeness
Forests in the Seychelles have been zonated earlier (Baader & Hendry 2007; Héritier 2002; Reinhardt &
Voellmy 2000). The zonation based on the nativeness for the Fond D’Albaretz was developed
considering those previous studies. However, adaptations for the special vegetation structure of the Fond
D’Albaretz had to be made. The aim is to get a zonation of the forest based on the present trees species
within each sub-transect. The zonation mainly distinguishes between native and invasive species. For the
group of native species a distinction is drawn between palm forest (> 50% palms) and native forest (<
50% palms). A further aspect of the zonation is the most prominently rejuvenating group of plants
(palms, native or invasive species). Nine different zones are distinguished (Fig 4): Invaded forest with
native, invasive or palm rejuvenation, native forest with native, invasive or palm rejuvenation and palm forest with
native, invasive or palm rejuvenation. The criterions are specifically described below.
First criterion: Native or invaded forest
A sub-transect is classified as being native if more than 66% of the adult trees are native species. Due to
the fact that invasive species have the ability to displace native species, a forest is classified as invaded
when more than 33% of the adult trees are invasive.
Second criterion: Palm forest or native forest
Within the study area the endemic palm species Deckenia n., Lodoicea m., Nephrosperma v.,
Phoenicophorium b. and Verschaffeltia s. are present. Especially Phoenicophorium b. and Nephrosperma v. are
highly abundant in some areas. Thus it is distinguished between palm and native forest. A forest is
classified as palm forest if more than 50% of the recorded trees are palms.
Third criterion: Native or invasive rejuvenation
Due to the high frequency of invasive saplings along some sub-transects, it is distinguished between
invasive and native rejuvenation. If more than 50% of the saplings are invasive species, the rejuvenation
of the sub-transect is declared as invasive rejuvenation.
Forth criterion: Palm or native rejuvenation
If more than 50% of the saplings are endemic palms, the rejuvenation of the sub-transect is declared as
palm rejuvenation, otherwise as native rejuvenation.
Methods
- 10 -
Fig. 4: Flowchart for the forest zoning based on nativeness
Zonation based on protection values (PtV)
The protection value provides information about the protection priority in terms of conservation of an
area. For each sub-transect (100 enumerated plants) within the study site the protection value after
Fleischmann (1997) is estimated. The ecological parameters used are (i) the diversity of natives (number
of native species per sub-transect), (ii) the singularity (number of red listed species per sub-transect based
on Huber & Ismail (2006)), (iii) the abundance of natives and (iv) invaders and (v) the regeneration
(percentage of native saplings per sub-transect). For each parameter a value between 1 and 3 is assigned
(Tab. 4). These values are entered into the matrices M1 to M3 (Fig. 5). Within M4 all the matrices are
compiled and a single value, the protection value, for each sub-transect is estimated (Fig. 6). In general,
five protection value classes are distinguished: 1, very low; 2, low; 3, medium; 4, high; 5, very high.
Methods
- 11 -
Tab. 4: Ecological parameters with the respective values.
Criterion Value
1 2 3
Diversity of natives 1 < 8 8 - 16 > 16
Singularity 2 < 5 5 - 10 > 10
Total abundance of invaders > 60 30 - 60 < 30
Total abundance of natives < 30 30 - 60 > 60
Regeneration 3 < 34 34 - 66 > 66
1 # native species, 2 # endemic species, 3 Based on an estimation of the occurrence
of native saplings
Diversity natives Abundace invaders M1
3 2 1 M2
3 2 1
3 3 3 2 3 3 3 2
2 3 2 2 2 3 2 2
Singularity
1 2 2 1 Abundance
natives
1 2 2 1
Regeneration M3 M3
3 2 1 M4
3 2 1
3 3 3 2 3 5 4 3
2 3 2 2 2 4 3 2 M2
1 2 2 1
M1
1 3 2 1
Fig. 5: The ecological status matrices M1 – M4.
Fig. 6: Combination of ecological status matrices.
Since most sub-transects within the study site show a protection value of 4, an additional validation is
made. If such a sub-transect features more than 66% endemic trees, the protection value is enhanced to
4+. If it features more than 33% invasive trees the protection value is depreciated to 4-. Thus, a more
detailed classification is obtained.
Diversity natives
Abundance invaders
Abundance natives
Singularity
Regeneration
M 2
M 1
M 3
M 4
Methods
- 12 -
Zonation based on red listed endemics
Various endemic species can be found in the area of the Fond D’Albaretz. To get an overview of the
areas with high occurrence of endemic plants a red list zonation after Baader & Hendry (2007) is
performed with one exception: A forest is classified as invaded when the invasive trees reach an
abundance of 33% instead of 50%. As a further criterion the rejuvenation by native, endemic or
invasive species is included. The red list status of the endemic species is adopted from Huber & Ismail
(2006). It is distinguished between 18 different zones. Six different zones are distinguished according to
adult trees. Each zone is then divided again into three different classes according to the amount of
rejuvenation by endemic, native and invasive species (Fig. 7). The 18 possible zones are: Invaded forest
with native, endemic or invasive rejuvenation, native forest with native, endemic or invasive rejuvenation, endemic
forest with native, endemic or invasive rejuvenation, red list status critically endangered (CR) or endangered (EN)
forest with native, endemic or invasive rejuvenation, red list status vulnerable (VU) or near threatened (NT) forest
with native, endemic or invasive rejuvenation and native forest with red list status vulnerable (VU) or near
threatened (NT) areas with native, endemic or invasive rejuvenation. The criterions are specifically described
bellow.
First criterion: Native or invaded forest
First of all it is distinguished between native or invasive vegetation. A sub-transect is classified as a native
area if more than 66% of the adult trees are native. Due to the fact that invasive species have the ability
to displace native species, a forest is classified as invaded when more than 33% of the adult trees are
invasive.
Second criterion: Native or endemic forest
As a second step it is distinguished between native and endemic areas. If more than 66% of the adult
trees are endemic, the status of the sub-transect is classified as an endemic.
Third criterion: Red list status critically endangered (CR) or endangered (EN)
As a third criterion the state of an endemic area is classified more specifically. Species owing a red list
status of CR or EN are the most threatened ones. If more than 3% of the trees belong to one of these
red list status the sub-transect is classified as CR-EN.
Forth criterion: Red list status vulnerable (VU) or near threatened (NT)
The forth criterion distinguishes between VU-NT-area and an endemic area. If more than 33% of the
endemic trees are in the red list categories VU or NT, the status of the sub-transect is classified as VU-
NT. Otherwise its status classified as an endemic area.
There are also sub-transects with less than 66% endemic trees but more than 33% categorised as VU or
NT. The status of those sub-transects is called native with VU-NT-parts.
Fifth criterion: Native or invasive rejuvenation
Based on the frequency of saplings it is distinguished between invasive and native rejuvenation. If more
than 50% of the saplings are invasive species, the rejuvenation of the sub-transect is declared as invasive
rejuvenation.
Sixth criterion: Native or endemic rejuvenation
If more than 50% of the saplings are endemic species the rejuvenation is classified as endemic
rejuvenation, otherwise as native rejuvenation.
Methods
- 13 -
Fig. 7: Flowchart for the zonation based on red listed endemics
2.7 Dicranopteris linearis survey
The aim is to get an overview of the occurrence of the fern Dicranopteris l. and to understand a possible
relationship between the occurrence of Dicranopteris l. and the kind of species composition, e.g. invasive
woody species.
While walking along trails, all Dicranopteris l. patches bigger than 1m2 and residing within or touching
the 10m-belt perpendicular on both sides to the trail are recorded. For every patch the GPS-coordinates
are taken, the extent of the area is estimated and the height of the mat is measured.
Following equipment is required: Measuring tape, standardized protocol, pen, GPS.
Data treatment
Every recorded patch is allocated to the nearest sub-transect. The total area of Dicranopteris l. per sub-
transect is calculated by summing up all patches belonging to that specific sub-transect.
A spearman correlation test was performed using SPSS Statistics version 17.0 (SPSS Inc., Chicago,
Illinois, USA). We assessed a possible correlation between the occurrence of Dicranopteris l. and the
occurrence of invasive woody species.
Methods
- 14 -
2.8 Boulder field mapping
The aim is to get an overview of the spread and structure of boulder fields within the study area. It is of
interest where individual or groups of boulders are located, what extent they have, how they are
arranged and how continuously they are.
In a first step, satellite images of the study area were interpreted to identify directly visible boulder fields.
A map was produced showing boulder fields which are not covered by dense canopy. In a second step,
this map was taken into the field to georeference boulder fields which are completely covered by canopy
and therefore not visible on satellite images. With the help of GPS those boulder fields were directly
drawn into the map. Special attention was given to the search of very long connected boulder fields. Due
to the extreme topography of the Fond D’Albaretz, it was not possible to access the complete area and to
map all boulder fields. Therefore, we distinguish between recorded features of boulder fields and assumed
features of boulder fields. Recorded features are boulder fields directly visible on satellite images or
boulder fields which were directly georeferenced in the field. Assumed features were given according to
assumed connections between large recorded features of boulder fields.
Only boulder fields with an extent of at least 10x10m and consisting of boulders fitting in class 4 or 5
according to the boulder field classification (Tab. 3) were mapped. As an additional information it was
recorded if a boulder field is covered by litter or not.
Following equipment is required: Measuring tape, standardized protocol (map to sketch boulder fields),
pen, GPS.
2.9 Qualitative monitoring of post-fire areas
Fond Ferdinand
Meuwly (2002) analyzed two areas affected by forest fires within the Fond Ferdinand, one burned in
1999 and the other in 1989. Within both areas three plots were established. Unfortunately we were not
able to relocate the exact positions of the plots due to missing plot markers and therefore no
quantitative re-survey was possible. But with help of GPS, the descriptions of Meuwly (2002) and a local
guide we were able to locate the areas where the plots are supposed to be. We then performed a
qualitative survey of those areas. The aim is to get an impression of possible changes of the vegetation
and the post-fire vegetation regeneration and succession since 2002.
The re-visit of the sites comprised an inventory of the present plant species, including the most
important grasses, the recording of the presence/absence of the fern Dicranopteris l. and estimations of
the canopy openness. In addition to this the size of bare soil and the groundcover with litter and herbs
were estimated. This estimation was made according to Braun-Blanquet (1964), considering the
adaptation made by Meuwly (2002) (Tab. 5) to allow the comparison of the values. Signs of erosion were
also recorded.
Fond D’Albaretz
Like in Fond Ferdinand, the aim of the survey is a general description of the two fire sites and the
evaluation of the state of the post-fire succession.
While surveying the burned areas we recorded the surviving species on the following criteria: (I) species
not resprouting, (II) species resprouting. The resprouting species were further classified into (a) above
ground resprouting and (b) epicormal resprouting. The last criteria was based on living vs. dead plants.
Additionally we recorded the occurrences of herbs, grasses and creepers and the size of bare soil and
litter on the ground again according to Braun-Blanquet (Tab. 5).
Methods
- 15 -
Following equipment is required: Measuring tape, standardized protocol, pen, GPS.
Tab. 5: The Braun-Blanquet coverage (1964) modified after Meuwly (2002)
BB coverage [%]
0 0-5
1 5-15
2 15-25
3 25-50
4 50-75
5 > 75
2.10 Fire risk map
This method is aiming at a visual allocation of fire risk zones, i.e. areas where fires are likely to start, and
from where they can easily spread to other areas (Jaiswal et al. 2002).
Data
In order to map fire risk zones, anthropogenic and natural (topography and vegetation) parameters have
to be regarded and included in a geographic information system. Topographic factors influencing the
spread of forest fires are slope, aspect and altitude (Castro & Chuvieco 1998; Chuvieco & Salas 1996)
because they determine microclimate and airflow. Topographic data was derived from a digital terrain
model (DTM) using the Spatial Analyst extension in ArcGIS (ESRI). Vegetation data origins from the
forest zonation described in chapter 2.6. Anthropogenic influenced localities are areas of high fire risk
because of the ignition source. Following two parameters are regarded in our analysis: Distance from
settlements and distance from roads and trails. Roads and inhabited areas were determined from
satellite pictures. Trails have been mapped during the vegetation survey using GPS. All vector-data was
converted into raster data to allow the computation of the risk values (see bellow) for individual raster-
units.
GIS-analysis
To link the continuous characteristics of the above described data to meaningful values, all parameters
were, in a first step, classified according to the risk to spread or induce forest fires (Tab. 6). In a second
step, for every class a factor was assigned, expressing the fire sensitivity by a numerical value from 1 (very
low risk) to 5 (very high risk).
Topography-based parameters are classified according to physical properties. Steep slopes lose easily
water and have a more efficient convective preheating (Xu et al. 2005), thus they catch easily fire and
spread it efficiently. Highest danger for forest fires is in dry season in the southern hemisphere winter,
which is between May and October (Walsh 1984). The altitude of the sun is around 70° in August
(Time and Date AS 2009). Therefore sunlight is most reflected on slopes facing north and least reflected
on slopes facing south. Anthropogenic influenced areas pose a high ignition risk. Thus, the risk is
decreasing with increasing distance from trails, roads and settlements. Vegetation defines the amount of
fuel available at a site and thus has a significant influence on the risk to spread or induce fire.
Methods
- 16 -
Tab. 6: Parameters influencing the risk to spread or induce fire
Parameter Weight Classes Factors Risk
Topography-based parameters
Slope 3 <10% 1 very low risk
10-25% 2 low risk
25-35% 3 medium risk
35-45% 4 high risk
>45% 5 very high risk
Aspect 1 North (316-45°) 5 very high risk
East (46-135°) 4 high risk
South (136-225°) 3 medium risk
West (226-315°) 4 high risk
Anthropogenic-based parameters
Distance to Settlements 2 <50m 5 very high risk
50-150m 4 high risk
150-300m 3 medium risk
300-500m 2 low risk
>500m 1 very low risk
2 <50m 5 very high risk
Distance to Trails and
Roads 50-100m 4 high risk
100-200m 3 medium risk
200-300m 2 low risk
>300m 1 very low risk
Fuel-based parameter
Vegetation 4 Palm forest with palm rejuvenation 5 very high risk
Native forest with palm rejuvenation 4 high risk
Native forest with native rejuvenation 3 medium risk
Invaded forest with palm rejuvenation 4 high risk
We used following equation in the GIS to determine the risk value (RV) for every individual 2x2m
raster-unit:
12
*4*2*2*1*3 VEDTDSASSLRV
++++= (eq. 5)
where SL is the classified slope, AS the classified aspect, DS the classified distance to settlements, DT the
classified distance to trails and VE the classified vegetation. Finally, a fire risk map was produced based
on RVs classified again into categories from 1 (very low risk) to 5 (very high risk). The detailed
geoprocessing-models are attached in the appendix E.
- 17 -
Fig. 8: Species composition of the
Fond D’Albaretz. Species numbers
are in brackets.
3. Results
3.1 Fond D’Albaretz - State of the forest
3.1.1 General findings
A total of 47 different plant species were found while performing
trail transecting and plot sampling (Fig. 8). Ten species (21%) are
indigenous and 21 (45%) endemic. Five (11%) introduced species
and eleven (23%) invasive species were recorded. 47 species were
enumerated by the Trail transecting method, while plot sampling
revealed only 25 species.
Five of the six endemic palm species of the Seychelles were
recorded within the study site. The palm species present in the
survey area are Deckenia n., Lodoicea m., Nephrosperma v.,
Phoenicophorium b. and Verschaffeltia s. the latter is only growing
where the conditions are more humid. The only endemic palm
species which is not present in our study site is Roscheria m., but it
can be found on the trail leading from the Fond D’Albaretz up
Glacis Noir.
3.1.2 Prominence along trail transects
Based on the PVs of adult tree species in the Fond D’Albaretz research area it has been seen that 75.4%
(PV=150.8) of all PVs attribute to native and 24.6% (PV=49.2) to alien species. 20.7% (PV=41.3) of all
PVs attribute to endemic palms. A similar pattern is found for saplings. About 76.6% (PV=153.2) of the
total PVs of saplings go to native woody species and 23.4% (PV=46.8) go to alien saplings. Palm saplings
account for 29.3% (PV=58.7) of all PVs. Regarding seedlings, the pattern is quite different. Of the total
PVs for seedlings 66.0% (PV=132.1) attribute to native and 34.0% (PV=67.9) attribute to alien species
(Fig. 9).
Fig. 9: Vegetation composition of the Fond D’Albaretz (Jean-Baptiste Nature Trail and expanded Nature Trail
together), the Jean-Baptiste Nature Trail and the expanded Nature Trail. A: Adults; Sa: Saplings; Se: Seedlings.
The most prominent adult species are the two endemic broad-leafed trees Paragenipa w. (PV=17.7) and
Pouteria o. (PV=14.1) together with the endemic palm Phoenicophorium b. (PV=17.8) (Tab. 7). Further to
that prominent species are as well Dillenia f. (PV=11.9), Canthium b. (PV=10.9), Nephrosperma v.
50%
25%
75%
0%
100%
Endemic species
(21)
Indigenous species
(10)
Alien species (5)
Invasive species (11)
25%
0%
50%
75%
100%
Fond D’Albaretz Jean-Baptiste
Nature Trail
Expanded
Nature Trail
A Sa Se A Sa Se A Sa Se
Invasive species
Alien species
Indigenous species
Endemic species
Results
- 18 -
(PV=10.6), Erythroxylum s. (PV=9.7) and Deckenia n. (PV=9.1). The most prominent invasive species in
the survey area are Cinnamomum v. (PV=11.1) and Adenanthera p. (PV=9.3).
The three most prominent adult species show also high PVs for saplings: Paragenipa w. (PV=18.2),
Pouteria o. (PV=17.6) and Phoenicophorium b. (PV=27.3). Less consistent with the prominence of adult
trees are the PVs for saplings of Deckenia n. (PV=10.7) and Canthium b. (PV=12.0). The most prominent
invasive saplings are Chrysobalanus i. (PV=16.6) and Cinnamomum v. (PV=13.5). Adenanthera p. is less
prominent, having a PV of 2.2. The most prominent seedlings are Cinnamomum v. (PV=27.3),
Phoenicophorium b. (PV=22.2) and Pouteria o. (PV=20.8).
Next to the PVs of the different species, a general trend for the future prominence is given in Tab. 7 by
comparing the PVs of adults and saplings.
Tab. 7: Prominence values of adult species and saplings recorded and their future trends. ↑: PV of saplings minus
PV of adults ≥ 2; ↗: PV of saplings minus PV of adults between 0.1 and 1.9; →: PV of saplings minus PV of adults
= 0; ↘: PV of saplings minus PV of adults between -0.1 and 1.9; ↓: PV of saplings minus PV of adults ≤ -2. The
highest PVs are marked with bold letters.
Species PV Diff. Trend Species PV Diff. Trend
A Sa A Sa
Adenanthera p.2 9.3 2.2 -7.2 ↓ Haematoxylum c. 2.8 3.3 0.5 ↗
Allophylus p. 3.2 5.6 2.4 ↑ Intsia b. 3.7 0.7 -3.0 ↓
Allophylus s.1 0.7 0.0 -0.7 ↘ Leucaena l.2 0.0 0.7 0.7 ↗
Alstonia m.2 1.1 0.0 -1.1 ↘ Lodoicea m.1 1.4 0.9 -0.5 ↘
Anacardium o.2 5.2 3.1 -2.1 ↓ Ludia m.1 2.8 1.5 -1.4 ↘
Aphloia s.1 0.0 0.7 0.7 ↗ Mangifera i. 0.0 0.7 0.7 ↗
Artocarpus a. 0.7 0.0 -0.7 ↘ Memecylon e.1 5.6 5.2 -0.4 ↘
Averrhoa b. 0.5 0.0 -0.5 ↘ Nephrosperma v.1 10.6 19.0 8.4 ↑
Bambusa v. 0.7 0.0 -0.7 ↘ Northea h.1 0.7 0.0 -0.7 ↘
Canthium b. 10.9 12.0 1.1 ↗ Ochna c.2 0.7 1.7 1.0 ↗
Calophyllum i. 5.8 5.9 0.1 ↗ Pandanus m.1 1.8 0.9 -0.8 ↘
Casuarina e.2 5.9 1.5 -4.4 ↓ Pandanus s.1 5.3 0.9 -4.4 ↓
Chrysobalanus i.2 6.8 16.6 9.8 ↑ Paragenipa w.1 17.7 18.2 0.5 ↗
Cinnamomum v.2 11.1 13.5 2.5 ↑ Phoenicophorium b.1 17.8 27.3 9.5 ↑
Clerodendrum s.2 0.5 0.0 -0.5 ↘ Pouteria o. 14.1 17.6 3.5 ↑
Craterispermum m.1 0.7 0.0 -0.7 ↘ Premna s. 0.7 0.0 -0.7 ↘
Deckenia n.1 9.1 10.7 1.6 ↗ Psidium c.2 0.5 0.0 -0.5 ↘
Dillenia f.1 11.9 7.0 -5.0 ↓ Psychotria p.1 0.0 0.7 0.7 ↗
Diospyros s.1 2.2 0.7 -1.5 ↘ Syzygium w.1 2.5 0.0 -2.5 ↓
Dracaena r. 5.1 13.2 8.1 ↑ Tabebuia p.2 3.3 3.5 0.2 ↗
Drypetes r.1 0.7 0.0 -0.7 ↘ Terminalia c. 1.2 0.0 -1.2 ↘
Erythroxylum s.1 9.7 2.2 -7.5 ↓ Verschaffeltia s.1 2.4 0.7 -1.7 ↘
Euphorbia p. 0.7 0.0 -0.7 ↘
Ficus l. 1.9 0.7 -1.2 ↘ 1 Endemic species
Gastonia c.1 0.0 0.7 0.7 ↗ 2 Invasive species
Comparison of the vegetation along the Jean-Baptiste Nature Trail and the expanded Nature Trail
In order to identify differences in the vegetation composition in terms of native and alien species the
two trails are reviewed separately. For statistical reasons, both trails comprise the same number of sub-
transects.
Results
- 19 -
For each trail 37 different species were recorded. 27 species are found along both trails. Nine invasive
and 19 endemic species are found along the Jean-Baptiste Nature Trail whereas eight invasive and 16
endemic species are found along the expanded Nature Trail. The five endemic palms growing within the
study site were recorded along both trails.
Whilst along the Jean-Baptiste Nature Trail the amount of native trees based on total PVs along this trail
is 76.2%, the amount along the expanded Nature Trail is 74.7%. Endemic species along the Jean-
Baptiste Nature Trail account for 50.3% whereas 18.4% of all adult PVs are endemic palms. Along the
expanded Nature Trail the endemics account for 53.2% whereas 22.8% are palms. The amount of
invasive species along the Jean-Baptiste Nature Trail accounts for 20.3% of all adult PVs and along the
expanded Nature Trail for 24.1%.
Generally the sapling composition (endemics, indigenous, alien, invasives and palms) is similar along
both trails.
The seedling composition along the two trails is quite different. For example the amount of invasive
seedlings based on the PVs along the Jean-Baptiste Nature Trail is 26.9% whereas along the expanded
Nature Trail the invasive seedlings account for 40.2%.
An overview of the most prominent species growing along the two trails is given in Tab. 8.
Tab. 8: Prominence Values of the 14 most prominent species along the Jean-Baptiste Nature Trail and the
expanded Nature Trail. The species are sorted by descending prominence values of adults. The highest PVs of
adults, saplings and seedlings are marked with bold letters.
Jean-Baptiste Nature Trail Expanded Nature Trail
A Sa Se A Sa Se
Paragenipa w. 1 19.6 16.9 16.5 Phoenicophorium b. 1 18.3 31.6 19.2
Phoenicophorium b. 1 17.4 23.7 24.5 Paragenipa w. 1 15.8 19.7 14.2
Pouteria o. 16.1 19.2 24.5 Cinnamomum v. 2 14.0 17.2 34.0
Dillenia f. 1 14.2 8.6 0.0 Nephrosperma v. 1 13.4 23.2 19.2
Canthium b. 12.6 15.0 20.9 Pouteria o. 12.1 15.9 16.1
Erythroxylum s. 1 12.3 1.3 1.6 Adenanthera p. 2 11.1 4.9 24.9
Deckenia n. 1 9.3 12.4 14.5 Dillenia f. 1 9.7 4.9 0.0
Cinnamomum v. 2 8.0 10.5 22.1 Canthium b. 9.2 8.3 10.3
Nephrosperma v. 1 7.7 15.4 18.5 Pandanus s. 1 9.1 2.1 0.0
Adenanthera p. 2 7.5 0.0 10.8 Deckenia n. 1 8.9 8.7 1.9
Chrysobalanus i. 2 7.1 16.2 13.3 Memecylon e. 1 8.2 5.8 7.9
Anacardium o. 2 6.8 5.6 0.0 Erythroxylum s. 1 7.1 3.3 0.0
Dracaena r. 6.4 13.9 4.8 Casuarina e. 2 6.6 0.0 0.0
Calophyllum i. 6.1 9.0 0.0 Chrysobalanus i. 2 6.5 17.2 15.0
1 Endemic species, 2 Invasive species
3.1.3 Prominence within sampling plots
A set of nine permanent sampling plots were established and investigated. Four plots are located along
the Jean-Baptiste Nature Trail and five along the expanded Nature Trail. They lay between 65 (plot I)
and 230m a. s. l. (plot C). Adult species-diversity in terms of species occurrence is lowest in plot I (ten
species) and highest in plot C and F (16 species). In average 12.7 different adult species were recorded
with a standard deviation of 2.4. Based on PVs, native species account for 100% of the adult vegetation
Results
- 20 -
in plot B and H. The lowest proportion of adult native vegetation was found in plot E with 55%. In
average, 85% of the adult vegetation is native with a standard deviation of 15%. A summary of the
results of the individual plots is given bellow. For the location of the sampling plots, refer to Fig. 2. A
general documentation of the plots is given in the digital appendix G.
Plot A
The endemic species Paragenipa w. (PV=74.5) and Phoenicophorium b. (PV=22.8) and the indigenous
Pouteria o. (PV=35) are not only dominating in their adult form but are also present as saplings and
seedlings. Together with Deckenia n. (PV=7.6) and Dillenia f. (PV=7.6) they represent 74% of all PVs of
the adult flora. The plot shows an above-average species-quantity of 14 different species of which ten are
native. Abundant and successfully rejuvenating alien species are Adenanthera p. (PV=29.7) and
Anacardium o. (PV=22.8). They are as prominent as the palm Phoenicophorium b. A lot of seedlings of
Cinnamomum v. (PV=44.1) are found but no saplings.
Plot B
Endemic species make up 92% of all PVs of the adult flora and 92% of all PVs of saplings in this plot.
Only ten different species were found, the smallest number of all plots, whereof nine species are native.
Paragenipa w. (PV=88.7) is the most prominent adult species, followed by the palms Phoenicophorium b.
(PV=54.5) and Deckenia n. (PV=31). Also present are the indigenous species Pouteria o. (PV=15.6) and
the endemic palm Nephrosperma v. (PV=10.3). All adult species found here are successfully rejuvenating.
The only alien species found is Cinnamomum v. which is only present as seedling (PV=20).
Plot C
With 16 recorded species, plot C owns the highest species-quantity of all sampling-plots. 13 species are
native whereof nine are endemic. The most prominent species is the endemic palm Phoenicophorium b.
(PV=66.1), closely followed by Paragenipa w. (PV=60). Less prominent native adult species are Canthium
b. (PV=22.4), Memecylon e. (PV=12.7), Diospyros s. (PV=9.7), Nephrosperma v. (PV=9.7) and Syzygium w.
(PV=9.7). Together, the native species constitute 95% of the adult vegetation based on PVs. Successful
rejuvenation is achieved by Paragenipa w. and Nephrosperma v. Pouteria o. is present as sapling (PV=28.6).
The sole adult alien species is Adenanthera p. (PV=9.7). It seems that it is not successfully rejuvenating
because only a few seedlings (PV=7.9) and no saplings were found.
Plot D
Based on PVs, 93% of the adult vegetation in plot D is native. With 14 recorded species, the quantity of
different species is above average. Only the two species Cinnamomum v. and Chrysobalanus i. are alien and
both of them are also invasive. Eight of the twelve native species are endemic. The highest prominence
value for adults is reached by Phoenicophorium b. (PV=53.3) followed by Nephrosperma v. (PV=34.4),
Paragenipa w. (PV=27.1), Deckenia n. (PV=17.2), Memecylon e. (PV=17.2), Canthium b. (PV=14.5), Diospyros
s. (PV=7.2), Erythroxylum s. (PV=7.2) and Pouteria o. (PV=7.2). Cinnamomum v. (PV=14.5) is the only alien
species present in its adult form. This species was also found as saplings (PV=44) and seedlings
(PV=107.8) which demonstrates the successful rejuvenation of this species. Chrysobalanus i. is
establishing because it is present as sapling (PV=40) and seedling (PV=7).
Plot E
The adult vegetation of plot E consists only to 57% of native species based on PVs. This is the lowest
share observed in all sampling plots. In addition to that, only ten different species were recorded, which
is also the lowest numbers observed. However, thereof seven are native. The clearly dominating species
in the survey area is the alien Cinnamomum v. (PV=53.7) which rejuvenates extensively. Saplings of
Cinnamomum v. make up a PV of 121.4 and seedlings a PV of 46.5. The other prominent alien species is
Adenanthera p. (PV=36.9).
Results
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The native vegetation consists of Phoenicophorium b. (PV=51.2), Nephrosperma v. (PV=37.6) and Pouteria o.
(PV20.7). Those species are rejuvenating successfully with the only exception of Nephrosperma v.
Plot F
With 16 different species recorded, plot F scores – together with plot C – the highest species-quantity.
13 out of 16 are native, whereof eight are endemic. Based on PVs, 92% of the adult vegetation is native.
Dominated by Paragenipa w. (PV=70.1) and Phoenicophorium b. (PV=52.5) the adult native vegetation
consists also of Pouteria o. (PV=26.2), Dillenia f. (PV=18.4), Dracaena f. (PV=8.2) and Erythroxylum s.
(PV=8.2). Only the two most prominent species show sufficient rejuvenation. Sole adult alien species is
Adenanthera p. (PV=16.4) which rejuvenates successfully. Cinnamomum v. (PV=19.5) and Ochna c.
(PV=3.1) are only present as seedlings.
Plot G
Made up of 72% natives (based on PVs), plot G has the second lowest share of native adult vegetation.
Twelve different species were recorded, what is bellow average. However, only the two species
Adenanthera p. and Cinnamomum v. are alien. The palms Phoenicophorium b. (PV=103) and Verschaffeltia s.
(PV=13.3) dominate the native vegetation over the less prominent species Canthium b. (PV=13.3) and
Paragenipa w. (PV=13.3). Phoenicophorium b. intensively rejuvenates and scores a PV of 150 for saplings.
Adenanthera p. (PV=30.7) and Cinnamomum v. (PV=26.5) are prominent but only Cinnamomum v. is
rejuvenating sufficiently.
Plot H
The adult vegetation is made up of only four native species, whereof two are endemic. As in plot B, no
adult alien species are present. Twelve different species were found in total, whereof four are alien.
Paragenipa w. (PV=137.8) clearly dominates the adult native vegetation over Canthium b. (PV=24),
Phoenicophorium b. (PV=20.7) and Pouteria o. (PV=17.5). In terms of saplings, Canthium b. (PV=76.2) and
Erythroxylum s. (PV=35.4) are dominating. The alien species Alstonia m. and Tabebuia p. are present as
saplings. Adenanthera p. and Cinnamomum v. are present as seedlings.
Plot I
Only ten different species are recorded, which is the lowest species-quantity observed. Seven species are
native, whereof four are endemic. Based on PVs, 82% of the adult vegetation is native.
The native adult flora consists of the endemic palm Phoenicophorium b. (PV=123.7) and the indigenous
tree species Pouteria o. (PV=40.8). Phoenicophorium b. is the only species present as saplings which leads to
a PV of 200. The adult alien vegetation comprises Adenanthera p. (PV=17.8) and Cinnamomum v.
(PV=17.8). Seedlings of Chrysobalanus i. are also recorded.
3.1.4 Red listed species
Based on prominence values, about half (51.8%) of the adult trees within the Fond D’Albaretz are
endemic. In total, 21 different endemic species are present (Tab. 9).
Two adult trees of the very rare species Drypetes r. (PV=0.7) were found within the study site, one of
them was recorded in sub-transect 1G (Fig. 2). According to Huber & Ismail (2006), this species is
classified as critically endangered (CR) and therefore the most threatened species found within the study
site. Both individuals are located within boulder fields and thus well protected. One developing seed was
found but no sign of rejuvenation.
Craterispermum m. (PV=0.7) is the only endangered (EN) species found in the survey area. Five adult
species were found in remote areas off the trails and one specimen along sub-transect 1G. They are not
located directly in boulder fields but in the vicinity of them. Five of the six discovered specimens are
Results
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located on an altitude of more than 200m a. s. l. One specimen was flowering and another one was
surrounded by a few seedlings.
The vulnerable (VU) endemic species Dillenia f. (PV=11.9) and Nephrosperma v. (PV=10.6) are quite
common. Ludia m. (PV=2.8), Syzygium w. (PV=2.5) and Verschaffeltia s. (PV=2.4) are less common and
restricted to certain areas. Ludia m. can be found at the border of boulder fields, Syzygium w. is restricted
to ridges of higher altitude and Verschaffeltia s. is present in the vicinity of rivers. 10 specimens of
Lodoicea m. were found, most of them off the trails. Only two examples of Northea h. were found, both
located in boulder fields in the vicinity of the Drypetes r. Some specimens of Allophylus s. were found,
located in shaded boulder fields.
Besides Pandanus m., all recorded species of the categories near threatened (NT) and least concern (LC)
are very abundant.
Tab. 9: Overview of the endemic species recorded within the study site by trail transecting and count-plot analysis
Species Red list classification
(Huber & Ismail, 2006)
PV
adult
PV
sapling
# adults recorded
in sampling plots
Drypetes riseleyi CR 0.7
Craterispermum microdon EN 0.7
Allophylus sechellensis VU 0.7
Aphloia theiformis var. seychellensis VU 0.7
Dillenia ferruginea VU 11.9 7.0 4
Gastonia crassa VU 0.7
Lodoicea maldivica VU 1.4 0.9
Ludia mauritiana var. sechellensis VU 2.8 1.5
Nephrosperma vanhoutteanum VU 10.6 19.0 13
Northea hornei VU 0.7
Psychotria pervillei VU 0.7
Syzygium wrightii VU 2.5 1
Verschaffeltia splendida VU 2.4 0.7 1
Deckenia nobilis NT 9.1 10.7 7
Diospyros seychellarum NT 2.2 0.7 2
Pandanus multispicatus NT 1.8 0.9
Pandanus sechellarum NT 5.3 0.9
Paragenipa wrightii NT 17.7 18.2 110
Erythroxylum sechellarum LC 9.7 2.2 2
Memecylon elaeagni LC 5.6 5.2 5
Phoenicophorium borsigianum LC 17.8 27.3 91
3.2 Boulder field classification
In total, 1289 boulder-recordings were taken. In 707 recordings (55%), no boulders were present (Fig.
10). Boulders (classes 2, 2a, 3, 3a, 4, 4a and 5) were found in 566 recordings (45%). With regard to life-
forms, in 641 (50%) of the total 1289 recordings adult individuals were found and in 648 cases (50%)
saplings.
Results
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Fig. 10: Number of recordings in each boulder class.
3.2.1 Palms vs. dicotyledonous trees
In 631 recordings (49%) the most abundant plant species were palms and in 658 recordings (51%)
dicotyledonous trees. Fig. 11 shows the correlation between boulder classes and the presence of palms
vs. dicotyledonous trees, for adults (a) and saplings (b).
Fig. 11: Comparison between the numbers of recordings of palms vs. dicotyledonous trees for each boulder class.
(a) is showing adult trees and (b) saplings.
1. Correlation between boulder classes and the presence of palms and dicotyledonous tree species
In order to be able to compare the boulder classification by Baader & Hendry (2007) in the La Reserve
Forest on Mahé with the results of the Fond D’Albaretz Forest, the set of boulder classes was simplified
to five classes. Subclasses were added to their main classes (e.g. 3a to 3) and subclass 1a was added to
class 5.
Adult palms show a significantly higher correlation with the presence of big boulders than adult
dicotyledonous trees. The mean boulder class for adult palms is 3.03 and the mean boulder class for
adult dicotyledonous tree species is 1.81 (Chi-square-Test, p<0.001, chi-square-value=113.829; Mann-
Whitney-U-Test, p<0.001).
Results
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A similar pattern can be observed for palm-saplings and dicotyledonous tree saplings. The mean boulder
class for palm-saplings is 2.32 and the mean boulder class for dicotyledonous tree saplings is 2.01 (Chi-
square-Test, p=0.055, chi-square-value=9.246; Mann-Whitney-U-Test, p=0.007).
2. Correlation between ≥ 50% ground-coverage by boulders and the presence of palms and dicotyledonous trees
The boulder classes 1, 1a, 2a, 3a and 4a were aggregated to the class “< 50%” and the boulder classes 2,
3, 4 and 5 to the class “≥ 50%”.
The presence of adult palms shows a significantly higher correlation with the occurrence of ≥ 50%
ground-coverage by boulders than the presence of adult dicotyledonous trees (Chi-square-Test, p<0.001,
chi-square-value=38.784; Mann-Whitney-U-Test, p<0.001).
A significantly higher correlation with the presence of boulders covering more than 50% of the ground
can also be observed for palm-saplings (Chi-square-Test, p=0.003, chi-square-value=8.915; Mann-
Whitney-U-Test, p<0.001).
3.2.2 Threatened species vs. invasive species
In 389 cases of the total 1289 boulder-recordings, threatened (red list status CR, EN and VU) or
invasive species were recorded. The histogram is shown in Fig. 12.
Fig. 12: Comparison between the numbers of recordings of threatened species vs. invasive species for each boulder
class.
Correlation between the presence of big boulders and the presence of threatened versus invasive species
Boulder-classes were simplified to five classes. Subclasses were added to their main classes (e.g. 3a to 3)
and subclass 1a was added to class 5.
Comparing red-listed species with alien invasive species, the Mann-Whitney-U-Test finds moderate
evidence (p=0.054) that the presence of threatened species (adults and saplings) shows a better
correlation to the presence of big boulders. However, the Chi-square-Test shows no evidence (p=0.202,
chi-square-value=5.959). The mean boulder class for threatened species is 2.31 and the mean boulder
class for invasive species is 2.03.
Results
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3.3. Vegetation zoning
Forest Zoning
The dominating forest type is native forest with palm rejuvenation (ten out of sixteen sub-transects) (Fig.
13a). In total, four distinguished forest zones are found. Along the Jean-Baptiste Nature Trail all sub-
transects are classified as native forest whereof three show native rejuvenation and five palm
rejuvenation. The expanded Nature Trail is dominated by native forest with palm rejuvenation too (five
sub-transects). However, two sub-transects (2C and 2D) are classified as palm forest with palm
rejuvenation and one (2E) as invaded forest with palm rejuvenation.
Vegetation zoning according to the red list status
Eight of sixteen sub-transects are classified as VU-NT-area with endemic rejuvenation, which is the most
prominent vegetation-class (Fig. 13b). Seven different zones were found. Four sub-transects are classified
as native area with VU-NT-parts, two of it with native and two with endemic rejuvenation. There is one
sub-transect (1G) classified as CR-EN-area along the Jean-Baptiste Nature Trail. Along this sub-transect
an adult Drypetes r. (CR) was recorded. Two sub-transects are classified as native area, one with endemic
and one with native rejuvenation. The only sub-transect (2E) classified as an invaded area was found
along the expanded Nature Trail. However, the rejuvenation of sub-transect 2E is endemic.
Vegetation zoning according to Protection Values
In general, the study site shows high to very high protection values (Fig. 13c). Within the study area of
the Fond D’Albaretz 15 of 16 sub-transects have a protection value of 4 (high), whereof eight sub-
transects gained the appreciation to 4+ and only one (2E) the depreciation to 4-. The highest protection
value of 5 is only found in sub-transect 2B.
Fig. 13: Vegetation zonation maps for the Fond D’Albaretz area, with respect to (a) the type of forest = forest zoning,
(b) the IUCN status of occurring red listed plant species = red list zoning and (c) the need to protect the area due of
its ecological value = protection value zoning.
Results
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3.4 Correlation between Dicranopteris l. and invasive species
The total area occupied by Dicranopteris l. in the immediate vicinity of the three trails is estimated to be
8640m2. The spatial allocation to the individual sub-transects is shown in Tab. 10. The average area
covered by Dicranopteris l. per sub-transect is 480m2 with a standard deviation of 565m2. The abundance
of invaders is determined with the data gained by trail transecting.
Tab. 10: Abundance of invaders and Dicranopteris l. area per sub-transect.
Sub-Transect Abundance of invaders Dicranopteris l. Area
[%] [m2]
1A 32.5 1
1B 20.5 160
1C 20.5 300
1D 11.4 769
1E 19.5 15
1F 12.2 109
1G 12.8 273
1H 7.3 134
2A 16.7 600
2B 20.0 2054
2C 25.7 0
2D 20.0 4
2E 30.6 30
2F 22.2 885
2G 25.6 320
2H 23.8 536
3A 25.0 1316
3B 34.2 1134
No correlation between the occurrence of Dicranopteris l. and the abundance of invasive species in the
vicinity of the Dicranopteris dominated areas was found (two-sided Spearman-correlation, p=0.883).
However, along transect 3 there was a significantly larger area of Dicranopteris l. per sub-transect found
than along transect 1 (t-Test, p=0.001).
Results
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3.5 Occurrence of boulder fields
A total area of 46’437m2 boulder fields was mapped. Most of the boulder fields were actually recorded
or checked in the field whereas only a small part was assumed (Fig. 14). It is striking to see that boulder
fields are strongly linked to each other and that they obviously fragment the forest.
Fig. 14: Map of recorded and assumed boulder fields within the study area.
3.6 Qualitative monitoring of post-fire areas
All areas have been visited in November 2008.
Fond D’Albaretz: General description of the burned area in May 2008
Due to the fire event, the area is spread with dead trunks. However, some species were able to either
survive (without resprouting) or to re-grow (resproute) after the fire event (Tab. 11). Especially
individuals of Lodoicea m. and also Phoenicophorium b. and Deckenia n. were able to survive best after the
fire. For Phoenicophorium b. and Deckenia n. also resprouting was often observed. There is a lot of bare
soil present (>75%) and grasses, herbs and creepers are starting to establish themselves. The ground is to
15-25% covered with leaf litter. Only few alien species are growing in the burned area, one of it being
the invasive Clerodendrum s. However, no Adenanthera p. seedlings, as was expected, were found. The
estimated canopy openness is 76-100%.
Fond D’Albaretz: General description of the burned area in September 2008
A lot of plants have died during the fire. Dead trunks are spread all over the area. Some plants survived
or were able to re-grow (resprouts) after the fire event (Tab. 11). In November 2008, a few species, e.g.
Phoenicophorium b., were already resprouting. Only few grasses and no creepers and herbs were present in
Results
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the burned area. There was a lot of bare soil present (50-75%) but in some areas the ground was almost
totally covered with leaf litter (25-50%). Along the eastern border of the burned area a lot of seedlings of
the species Paragenipa w., Pouteria o., Phoenicophorium b., Cinnamomum v. and Adenanthera p. were
establishing and considerable amounts of Adenanthera p. seeds were found. The canopy openness was 51-
75% whereas a lot of leafs building the canopy were dead. The fire also burned a small part of the Jean-
Baptiste Nature Trail (Fig. 2). To enhance the regeneration of this area, about 630 seedlings of different
indigenous and endemic species have been planted in October 2008. Most of them were doing fine in
November 2008 aside from Canthium b. A detailed list of the re-introduced planted species is attached in
the appendix F.
Tab. 11: Overview of the recorded species and their state within the two burned areas in the Fond D’Albaretz
Surviving species Resprouting species Barely never
surviving Other species
above ground
resprouting epicormic shoots
Casuarina e.2 Adenanthera p.2 Anacardium o.2 Canthium b. Clerodendrum s.2
Chrysobalanus i.2 Anacardium o.2 Dillenia f.1 Curculigo r.1
Deckenia n.1 Cinnamomum v.2 Erythroxylum s.1 Flagellaria i.
Dillenia f.1 Deckenia n.1 Pouteria o. Passiflora s.
Lodoicea m.1 Dillenia f.1 Syzygium w.1 Scleria s.
Paragenipa w.1 Dracaena r. Stachytarpheta j.
Phoenicophorium b.1 Haematoxylum c. Turnera u.
Syzygium w.1 Intsia b.
Lodoicea m.1
Paragenipa w.1
Phoenicophorium b.1
Pouteria o.
Burned in M
ay 08
Syzygium w.1
Chrysobalanus i.2 Nephrosperma v.1 Erythroxylum s.1 Canthium b. Curculigo r.1
Deckenia n.1 Paragenipa w.1 Pouteria o. Pandanus m.1 Flagellaria i.
Dillenia f.1 Phoenicophorium b.1
Paragenipa w.1 Pouteria o.
Phoenicophorium b.1
Syzygium w.1 Burned in Sept. 08
1 Endemic, 2 Invasive
Fond Ferdinand: General description of the burned area in 1989
On-site of plot 7, on the top of a ridge, a lot of bare soil is visible (15-25%) and the ground is heavily
affected by soil erosion. Further down the hillside, at plot 9, erosion plays only a minor role and at plot
8 in the valley, no sign of erosion was observed. In areas affected by erosion the vegetation is generally
less dense. Within the whole area a lot of Lophoschoenus h. is growing and at plot 8 and 9 an even bigger
variety of species of herbs and grasses was recorded.
Adult trees are mostly arranged in vegetation patches. On top of the ridge those patches are separated by
areas of eroded soil whereas further down the hillside they are more and more linked to each other by
belts of herbs and grasses. Due to the fact that there is no closed vegetation, there is also no closed
canopy and the canopy openness is between 76-100%. In the whole area only few saplings and seedlings
are present, mostly within or next to the vegetation patches. The ground-cover with leaf litter is about 5-
15%. The trees on top of the ridge are growing very slowly and are quite small, whereas the trees further
Results
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down the hillside are doing much better and are taller. To enhance regeneration of the vegetation the
two alien species Acacia m. and Acacia p. were planted. They were doing very well in November 2008.
There is also Dicranopteris l. present on-site of plot 7. An overview on the recorded species is given in
Tab. 12.
Fond Ferdinand: General description of the burned area in 1999
The ground is mostly covered with leaf litter (50-75%) and only little bare soil is visible (15-25%). A lot
of Lophoschoenus h. and Costularia f. was observed. Curculigo r. and Flagellaria i. are present in a less
extensively. Almost no herbs were seen. To improve tree regeneration Acacia m. and Acacia p. were
planted, producing most of the litter covering the ground. On-site of plot 3 it looks a bit different. Due
to the fact that this area is very exposed, a lot of bare soil is present and sings of erosion are visible. Only
few Acacia sp. were planted. Even though the Acacia sp. and also some indigenous species are growing
well, there is a canopy openness of 76-100% and therefore no closed canopy. At plot 1 and 2 the canopy
openness is between 51-75%. The whole area comprises only few juveniles, most of them being
Phoenicophorium b. and Deckenia n. A lot of Acacia sp. seeds are spread on the ground but only few
seedlings are establishing. Dicranopteris l. was only recorded in small patches. An overview on the species
recorded is given in Tab. 12. Around plot 3 Aspargus s. is growing. The area of plot 2 was cleared from
the invasive Chrysobalanus i. However, in November 2008 it was already coming back (personal
communication with Micheal Gill, Praslin, 2008). On the hillside, erosion-barriers were constructed
with wood from cleared Tabebuia p. trees. These barriers prevent erosion and stabilize the soil to support
reforestation in steep slopes.
Tab. 12: List of the woody species of the areas burned in 1989 and 1999 in the Fond Ferdinand
Area burned in 1989
(Plots 7, 8, 9)
Area burned in 1999
(Plots 1, 2, 3)
Acacia m.2, P Erythroxylum s.1 Acacia m.2, P Nephrosperma v.1
Acacia p.2, P Intsia b. Acacia p.2, P Pandanus m.1
Adenanthera p.2 Lodoicea m.1 Anacardium o.2 Paragenipa w.1
Alstonia m.2 Nephrosperma v.1 Canthium b. Phoenicophorium b.1
Canthium b. Paragenipa w.1 Casuarina e.2 Syzygium w.1
Casuarina e.2 Phoenicophorium b.1 Cinnamomum v.2, S Tabebuia p.2
Chrysobalanus i.2 Pouteria o. Chrysobalanus i.2
Deckenia n.1 Scaevola s. Deckenia n.1
Dillenia f.1 Syzygium w.1 Dillenia f.1
Dodonaea v. Tabebuia p.2 Dodonaea v.
Dracaena r. Intsia b.
1 Endemic, 2 Invasive, P Planted, S Only seedlings
Results
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3.7 Fire risk map
The first fire risk map (Fig. 15) produced in the Seychelles clearly demonstrates a high fire risk in the
whole area of the Fond D’Albaretz. Due to the steep slopes, the availability of trails and the excessively
present fuel most of the areas investigated exhibit a high risk for the spread or the induction of fire. A
very high risk is only found in steep areas very near to trails, the main-road and to settlements. Medium
risk is restricted to flatter areas on ridges or in valleys. Low risk areas are very confined and are only
found on plateaus in great distance to trails. No very low risk areas were found.
Fig. 15: Fire Risk Map of the Fond D’Albaretz visualizing the risk to spread or induce fire.
Results
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3.8 Trail towards Glacis Noir - State of the forest
3.8.1 Prominence along trail transects
Along the two sub-transects of the Glacis Noir Trail, 19 different species were recorded. Two species are
indigenous, twelve endemic and five invasive. Based on PVs of adult tree species, 70.4% of all PVs
attribute to native and 29.6% attribute to invasive species. In terms of saplings 73.5% attribute to native
and 26.5% attribute to invasive species. Regarding seedlings 61.0% is accredited to native and 39.9%
accredited to invasive species. The most prominent species along the Glacis Noir Trail are Paragenipa w.
(PV=20.2), Nephrosperma v. (PV=18.9) and the invasive Chrysobalanus i. (PV=20.2). Further species are
Canthium b. (PV=15.5), Deckenia n. (PV=13.8), Dillenia f. (PV=13.8), Memecylon e. (PV=12.5) and
Phoenicophorium b. (PV=15.1). Next to Chrysobalanus i., the alien species Casuarina e. (PV=12.5) and
Cinnamomum v. (PV=15.1) are also very common. The most prominent sapling species is Chrysobalanus i.
with a PV of 34.5 followed by Phoenicophorium b. (PV=30.5). The most prominent seedling species are
Cinnamomum v. (PV=34.7) and Chrysobalanus i. (PV=32.5).
3.8.2 Vegetation zoning
Forest Zoning
One sub-transect is classified as native forest and one as invaded forest (Fig. 16a). Both sub-transects
show a rejuvenation dominated by invasive species.
Vegetation zoning according to the red list status
Sub-transect 3A is classified as valuable VU-NT-area whereas sub-transect 3B is classified as an invaded
area (Fig. 16b). Both sub-transects again show invasive rejuvenation.
Vegetation zoning according to Protection Values
The two sub-transects along the Glacis Noir Trail show high protection values (Fig. 16c). Sub-transect 3A
obtained an appreciation to 4+ and sub-transect 3B a depreciation to 4-.
Fig. 16: Vegetation zonation maps for the trail towards Glacis Noir, with respect to (a) the type of forest = forest
zoning, (b) the IUCN status of occurring red listed plant species = red list zoning and (c) the need to protect the area
due of its ecological value = protection value zoning.
- 32 -
4. Discussion and conclusions
4.1 Species composition
The quantitative results show that the vegetation of the Fond D’Albaretz is to a great extent dominated
by endemic species whereof the most prominent ones are Phoenicophorium b. and Paragenipa w. About
half of all individual endemic trees recorded were palms. Indigenous species represent one forth,
whereas Pouteria o. is the most dominating species. Alien species account for only a small amount of the
recorded trees, whereas the invasives account also for about one forth. The most dominating invasive
species are Cinnamomum v. and Adenanthera p. In terms of seedlings, invasive species account for about
one third. Especially Cinnamomum v. and also Adenanthera p. are very common. However, prominence
values of saplings and adults reveal clearly that only very few are actually able to grow up.
A comparison with the Vallée de Mai (Tab. 13) shows that the Fond D’Albaretz has a quite high tree
density. With a look at the palm density one can see that in both areas a high amount of trees are palm
species, in the Vallée de Mai slightly more than in the Fond D’Albaretz. Whereas the tree density is
higher, a very low species regeneration is generally found in the Fond D’Albaretz compared with the
Vallée de Mai. What comes along with a higher tree density is a lower light intensity on the ground
which might influence species recruitment. Under reduced light conditions it is getting harder for new
seedlings to establish. Thus the lower regeneration might be explained by the light climate, although
Fleischmann et al. (2005) could not find any correlation between the light climate and a possible
influence on the regeneration. Since the tree density within the Fond D’Albaretz is a factor of three
higher we think that it might be reasonable that the reduced light conditions on the ground might have
an influence on the regeneration. However, further research with a broader range of tree densities would
be needed.
Tab. 13: Tree density and regeneration within the Fond D’Albaretz and the Vallée de Mai
Fond D'Albaretz Vallée de Mai (1998)*
Mean SE Mean SE
Total tree density (ha-1) 3411 961 1271 343
Total palm density (ha-1) 1244 613 646 119
Total regeneration (saplings/tree) 0.3 0.1 1.2 0.4
Palm regeneration (saplings/tree) 0.3 0.2 2.0 0.8
*Data from Fleischmann et al., 2005
The high amount of native species is also visible in the forest zoning where only one out of 16 sub-
transects was classified as invaded forest. All others were classified as native or palm forest. This finding
characterises the Fond D’Albaretz by definition as a “native and palm forest area”.
The vegetation of the Jean-Baptiste Nature Trail was zoned by Héritier in 2002. Five sub-transects were
classified as broad-leafed forest, two as palm forest and one as invaded forest, all with rejuvenation by
native species. Our study classified all those sub-transects as native forest. To some extent, the shift of
this classification is caused by the different zoning criterions. Héritier (2002) classified the forest (broad-
leafed and palm forest) according to the most frequent tree species whereas our study classified
according to the abundance of native and palm species. If we had used Héritier’s classification, some
transect would have been classified as palm forest, event though they comprise more than 50% native
non-palm species. Thus, our approach seems more suitable for a general classification whereas Héritier’s
approach seems more suitable to classify according to the most frequent species. The criterion for
invasive forests was the same for both studies. Another cause which contributes to this inconsistency in
Discussion and conclusions
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classification is possibility the selection of different starting points of the sub-transects. The sub-transect
classified as “invaded forest” by Héritier (2002) is quite close to a settlement. There the human impact
provides more habitats for invaders and also some invasive fruit trees are planted. Thus it seems
reasonable that by a shift of the starting point more invasive species were recorded by Héritier (2002).
Another possibility, next to those methodological reasons, is that due to an active site management, like
clearing of invasive species (personal communication Matthieu LaBuschagne 2008), the prominence of
invaders might have decreased and thus the native vegetation composition may have improved since
2002.
With only one sub-transect classified as “invaded forest” and none with the classification “invasive
rejuvenation”, the study site does not seem to be heavily invaded with alien plant species. If we consider
that in the direct neighbourhood of the Fond D’Albaretz, several sub-transects within the area of the
Fond Ferdinand and up to Glacis Noir were classified as “invaded forest with rejuvenation of invasive species”
(Héritier 2002) and also in the Praslin National Park several sub-transects were classified as “invaded
forest“ (Reinhardt et al. 2000), the Fond D’Albaretz study site shows a relative low prominence of
invasive species. Also with respect to the forest succession and species rejuvenation it is presumed that
also in the future the forest will be dominated by native and especially endemic species.
4.2 Ecological value
The zonation based on protection values clearly revealed the high ecological value of the Fond
D’Albaretz. This finding is supported by the high mean protection value of 4.1 and the fact that the
lowest protection value of 4- was only assigned once. All other sub-transect have a PtV of four or higher.
By comparing the Fond D’Albaretz with the Vallée de Mai (Tab. 14), we want to highlight the
importance of the Fond D’Albaretz in terms of its ecological importance on a broader scale. The Vallée
de Mai is an area of high ecological importance and due to its status as a World Heritage Site by
UNESCO (Fleischmann et al. 2005) a good reference for a comparison. The protection values of the
two compared sites are on a comparable high level. The Fond D’Albaretz comprises one sub-transect
classified with a PtV of 5, whereas the Vallée de Mai only comprises sub-transects with PtVs of 4. The
total abundance of native species is slightly higher for the Vallée de Mai whereas the share of native
species is slightly higher for the Fond D’Albaretz. The state of singularity can not be compared due to
the different number of sub-transects performed. However, if we consider a typical species increase with
an increasing area, the singularities in both areas are on a similar level. The comparison between the
Fond D’Albaretz and the Vallée de Mai shows that the ecological value of the Fond D’Albaretz in terms
of protections values and abundances of native species is absolutely comparable to the values of the
Vallée de Mai.
Tab. 14: Comparison of the Fond D’Albaretz with the Vallée de Mai.
Protection
value
Abundance
native species
Native share of
species diversity Singularity2
Number of
Transects
Fond D'Albaretz 4.1 77.9 % 66.0 % 21 16
Vallée de Mai 1 4.0 88.1 % 57.5 % 14 7
1 Data from Reinhardt & Voellmy (2000) 2 Red list species according to Procter (1974)
It is quite striking to see how the so called “red list zonation” parallels the high ecological value of the
Fond D’Albaretz area. It is a habitat which harbours a lot of threatened species. Most of the area
contains a significant amount of species classified as VU or NT. And there are also species present
Discussion and conclusions
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classified as CR or EN. For example the very rare Drypetes r. which suffered from exploitation and
habitat loss (Carlström 1996, Friedmann 1994) enjoys a relatively well conserved habitat.
The Fond D’Albaretz ranges from sea-level to a height of 250m a.s.l. The original flora of this height
before human exploitation is described in the literature (Friedmann 1987, Vesey-Fitzgerald 1940). This
low altitude forest comprised a typical plant community dominated by endemic palms (Deckenia n.,
Nephrosperma v., Phoenicophorium b.) and nowadays rare species like Craterispermum m., Dillenia f., Drypetes
r. or Medusagyne o. Due to timber-exploitation and the extension of settlement-areas, these days only
relics of this original vegetation composition can be found. Parts of the Fond D’Albaretz are indeed such
relics, e.g. the western part of the Jean-Baptiste Nature Trail or the northern part of the expanded
Nature Trail. The plant composition of those regions is very similar to the original vegetation in terms of
high endemism, the presence of rare species and the low abundance of alien species.
In summary three lines of evidence clearly demonstrate the ecological importance of the Fond
D’Albaretz: (1) A consistently high protection value was found over the whole study area, (2) a
comparison with the Vallée de Mai revealed similar high levels of ecological values and (3) relics of low-
altitude forest were identified.
4.3 The role of boulder fields
A characteristic feature of the granitic island of the Seychelles is the presence of boulder fields. Those
accumulations of granitic rocks of different shapes and sizes produce a special reserve for plant species.
The cumulative existence of very rare species in boulder fields is well documented in the literature
(Fleischmann et al. 1996, Procter 1984) but not fully understood yet. Our study offers a contribution to
better understand the dynamics of boulder fields.
Baader & Hendry (2007) give statistical evidence that endemic palms establish and grow better between
big boulders and in boulder fields, whereas dicotyledonous trees rather occur between small boulders or
in areas without boulders. Concerning the presence/absence of boulders, to their knowledge this was
the first study which associates the geomorphic characteristics of a site with the vegetation structure. We
were now able to confirm those findings with a more extensive database. In addition to that, we were
also able to prove statistically that endemic palms establish and grow better in areas where boulders
cover 50% or more of the ground, whereas dicotyledonous trees prefer areas with a coverage of less than
50%. Obviously those two findings are closely related: In the Seychelles it seems that endemic palms are
adapted to the special conditions of boulder fields. The more and the bigger the boulders, the higher is
also the coverage by boulders.
Concerning threatened species, we found an indication that they establish and grow better between big
boulders and in boulder fields than do invasive species. However, this indication is only based on a
probability of a P-value near 0.05. This possible correlation could be caused by the adaptation of
threatened species to extreme conditions in boulder fields such as temperatures exceeding 50° C or
relative humidity dropping below 30% (Fleischmann et al. 1996). Due to the uniqueness of boulder
fields and evolutionary reasons, invasive species do not have such an adaption and are not able to
compete with the well adapted endemic (mostly threatened) species.
4.4 Future trends
In general, more or less stable population structures of endemic, native, alien and invasive trees can be
predicted in future. However, a shift in prominence values of individual species within the group of
endemic, native, alien and invasive species is likely. One expected shift concerns the group of endemic
species: For the future vegetation of the Fond D’Albaretz it seems feasible that this group will be
Discussion and conclusions
- 35 -
dominated even more by palms, especially by Phoenicophorium b. and Nephrosperma v. which show high
PVs for saplings, and less by endemic broad-leafed trees. This trend is also supported by the findings of
forest zoning where most sub-transects are classified as “forest with palm rejuvenation”. Deckenia n. also
shows an increasing trend in prominence, whereas the two palms Lodoicea m. and Verschaffeltia s. will
probably decrease their prominence, since their rejuvenation is not sufficient. Most of the other
endemic species show a decreasing trend. Some of them are very rare and sometimes no saplings were
recorded at all. The endemic Paragenipa w. will still be very prominent in the future. For the alien
species, no big changes are expected. Within the group of invasive species it seems likely that
Chrysobalanus i. and Cinnamomum v., will increase their prominence, whereas other species like
Adenanthera p. will rather decrease.
The Fond D’Albaretz forest will have stable shares of native and alien vegetation. Changes are only
suggested within vegetation classes, e.g. palms will increase their prominence within the class of endemic
species.
4.5 Dicranopteris l. and the abundance of invasive species
Statistical tests could not prove a correlation between the occurrence of Dicranopteris l. and the
abundance of invasive species. Dicranopteris l. is an efficient invader on disturbed and eroded areas
(Carlström 1996). It is able to effectively build a dense ground-coverage so that no seedlings of other
species can establish. Needless to say this includes invasive as well as native species. But concerning the
occurrence of alien species, this could be one of the reasons why no correlation between the occurrence
of Dicranopteris l. and the abundance of invasive species could be found.
However, we qualitatively observed that when the dense mat of Dicranopteris l. is unravelled for construct
a trail, juveniles of typically invasive species like Chrysobalanus i. or Tabebuia p. are able to establish
themselves. Endemic species are probably not able to compete with those species in such sites. Therefore
it is crucial to avoid the development of large Dicranopteris l. mats because they impair the regeneration
of the former forest after a disturbance and the rehabilitation of infested areas is extremely difficult.
4.6 Comparison of the Fond D’Albaretz with the adjacent area towards Glacis Noir
The main slopes of Fond D’Albaretz are directed towards south and south-west. For being able to
compare this side of the Fond D’Albaretz with its northern extensions towards Glacis Noir, vegetation
data along the trail towards Glacis Noir was collected.
Along the trail towards Glacis Noir, slightly higher abundances of invasive species were recorded.
Especially Chrysobalanus i. is a very abundant species in this region. The forest zonation reveals a
remarkable difference between the two sides: Both sub-transects along the Glacis Noir Trail show an
“invasive rejuvenation” dominated by invasive species whereas in the Fond D’Albaretz area no sub-transect
shows rejuvenation dominated by invasive alien tree species. However, in terms of protection values, the
two sides are comparable. But due to the high abundance of invasive saplings, this could change in
future. One of the two sub-transects is already classified as “invaded forest” and because of the invasive
rejuvenation the adult vegetation will certainly be more dominated by invasives in future.
Another striking difference between the two sides is the presence of areas infested by Dicranopteris l. The
back side of Fond D’Albaretz towards Glacis Noir comprises significantly bigger areas of Dicranopteris l.
per sub-transect than along the Jean-Baptist Nature Trail. This leads to the assumption that here, in
comparison to the core of the Fond D’Albaretz area, more disturbances, most probably fire events, have
occurred in the past which favoured the infestation by Dicranopteris l. Large patches of such post-
disturbance-areas can be seen along the trail towards Glacis Noir, they are composed of a typical plant
community dominated by Dicranopteris l. and Chrysobalanus i.
Discussion and conclusions
- 36 -
4.7 Post fire regeneration
Fond D’Albaretz
Within five months two fires affected the Fond D’Albaretz area. It is obvious to see in our results (Tab.
15) that the area burned in May had five months more to evolve than the area burned in September in
such a way that the ground-cover comprising mainly herbs and grasses is better developed. Besides this,
more species have already started to resprout. The proportion of bare and exposed soil is bigger because
most of the leaf litter is already decomposed and eroded. The canopy is much more open because all
dead trees lost their leaves already whereas in the area burned in September, the dead leafs still hold on
to the trees.
Tab. 15: Comparison of the qualitatively estimated ground cover with herbs and grasses, leaf litter and bare soil
after Braun-Blanquet adapted by Meuwly (2002) and the canopy openness of the two burned areas within or next
to the Fond D’Albaretz in May and September respectively.
Herbs and
grasses (BB)
Bare soil
(BB)
Leaf litter
(BB)
canopy
openness %
Fond D'Albaretz (May) 1 5 2 76-100
Fond D'Albaretz (Sept.) 0 4 3 51-75
Most of the surviving or resprouting species are endemic (palms and broad-leafed trees). This finding
agrees with reports by Meuwly (2002) and observations by Fleischmann after a fire on Mt. Capucin,
Mahé in 1994 (personal communication Karl Fleischmann 2009). Based on this data we presume that
the capacity of resprouting after a fire is higher by endemic species compared to introduced taxa. If this
assumption proves right the data would provide one more link between the Seychelles endemics and a
typical fire adapted Gondwanaland vegetation.
Fond Ferdinand: Comparison with the observations of Meuwly (2002)
Since Meuwly’s visit in 2002 of the area burned in 1989, the ground-cover with leaf litter has decreased,
the ground-cover with herbs remained more or less the same and there is also about the same amount of
bare soil present (Tab. 16). On the steep hillside near the top of the ridge the vegetation is in an even
worse condition than in 2002. The building of erosion barriers, like they were built in the area burned
in 1999, might help to reduce soil erosion.
Within the area burned in 1999 less bare soil was recorded in 2008 than in 2002 (Meuwly) whereas the
leaf litter cover and the ground-cover with herbs and grasses increased (Tab. 16). Direct signs of fire
disturbances, e.g. burned trees, cannot be seen anymore. But there are several trees which survived the
fire and show fire marks like fire scars on the stem.
Tab. 16: Ground cover with herbs and grasses, leaf litter and bare soil after Braun-Blanquet adapted by Meuwly
(2002) of the two areas burned in the Fond Ferdinand in 1989 and 1999 respectively.
Herbs and
grasses (BB)
Bare soil
(BB)
Leaf litter
(BB)
Fond Ferdinand 1989 (visited 2002) 2 2 3
Fond Ferdinand 1989 (visited 2008) 2 2 1
Fond Ferdinand 1999 (visited 2002) 0 3 1
Fond Ferdinand 1999 (visited 2008) 1 1 4
Based on the vegetation density and ecosystem diversity of the area burned in 1989, a recovery time after
a fire disturbance more than 10 years was determined by Meuwly (2002). But he also mentioned that the
Discussion and conclusions
- 37 -
recovery is heavily dependent on the specific site characteristics. Our observations in the area burned in
1989 confirmed this hypothesis. Whereas in the areas of the two plots located further down the hillside
the vegetation seems to recover successfully, the area of the plot on top of the ridge shows still a high
amount of bare soil and erosion prevents the vegetation-patches to properly link to each other. It seems
likely that in steep areas recovery takes longer due to a more intense soil erosion. The construction of
erosion barriers or planting of suitable species could help to enhance regeneration. Such suitable species
could be soil stabilizer like the two sedges Lophoschoenus h. and Costularia f. A further promising species
to plant is Phoenicophorium b. because of its enormous phenotypic plasticity and its high litter
production.
The species compositions of the two burned areas within the Fond Ferdinand have not changed since
2002 except for the presence of Dicranopteris l.: Meuwly (2002) does not mention any Dicranopteris l.,
whereas we recorded various patches. The two recently burned areas at the Fond D’Albaretz also don’t
comprise Dicranopteris l. patches. We therefore suppose that it takes quiet some time until Dicranopteris l.
establishes after a fire disturbance. In addition the establishment of invasive species is heavily depending
on propagule pressure and habitat conditions.
4.8 Fire risk map
The risk depicted in the fire risk map is composed of the likelihood of ignition and the risk to spread a
fire. However, most forest fires are caused unintentionally or intentionally by humans. In this context,
the fire risk map can help to predict, where the fire is likely to spread and where it possibly can be
stopped.
It is striking to see that often on ridges the risk is lower than on the adjacent slopes. Although there are
trails following ridges the influence of the slope on the fire risk seems stronger than the one of the
vicinity to trails. This demonstrates the high influence of topography on the risk of spreading fires. The
topographic roughness of the Fond D’Albaretz is probably a main factor explaining why the Fond
D’Albaretz has an overall high risk. The available fuel is certainly also an important factor determining
the risk. However, there is not much difference in the availability of fuel within the study site. Human
presence is certainly the most important ignition source and combined with steep slopes it can result in
a very high fire risk like in the south-west of the Fond D’Albaretz.
Unfortunately detailed data on forest fires in the area of the Fond D’Albaretz was not available and no
relationships between forest fires and single parameters influencing the risk to spread or induce fire
could be analyzed using the linear regression method. We propose the development of a Praslin-wide
fire risk map for further research. Fire data for Praslin should be available to an extent which allows the
performance of a linear regression study. GIS-data can be obtained from the GIS-Unit at the Policy
Planning and Services Division of the Ministry of Environment on Mahé. The Praslin-wide fire risk map
could be a very useful tool to prevent fires and support fire-fighting.
4.9 Synthesis
In our work hypothesis, we proposed, besides the unique ecological framework of the south-eastern
Praslin, the presence of boulder fields and the lack of severe fire disturbances and human impact as
main reasons for the high ecological value of the Fond D’Albaretz. We found several lines of evidence
supporting this hypothesis.
The boulder field mapping clearly revealed the high presence of interlinked boulder fields within the
study area (Fig. 17). The distribution of boulder fields can be described as a network following valleys
towards the sea. Boulder field classification revealed that boulder fields are a hideaway for threatened
Discussion and conclusions
- 38 -
plant species, which are obviously better adapted to the micro-climatic conditions of boulder fields than
invasive plant species. It could also be proved that endemic palm species prefer growing between big
boulders. Therefore, the Fond D’Albaretz provides a vast habitat for threatened and endemic palm
species.
The combination of the fire risk map, the boulder field map and the locations of few selected rare plant
species all show that these rare species are to a great extent restricted to high fire risk areas enclosed by
boulder fields (Fig. 17). For example, only two specimens of Drypetes r. and two of Northea h. were found,
all located within or enclosed by boulder fields. At first sight this seems not logical because areas with a
high fire risk may have burned in the past and the rare species were therefore locally extinct. However,
due to the isolation by boulder fields, they may have survived in certain locations or rather the fire was
not able to burn the vegetation in those sites because of the boulder fields. Therefore, we propose that
boulder fields have a protective power against fire and that they are able to stop the spread of forest fires
and therefore protect vegetation-patches between big boulder fields.
Fig. 17: Map showing the fire risk, boulder fields and locations of selected rare plant species.
The comparison with the back side of the Fond D’Albaretz suggests that the Fond D’Albaretz has been
less affected by fire disturbances in the past. The presence of the fern Dicranopteris l. is significantly
higher on the northern backside than on the south side of the Fond D’Albaretz. This fern is able to
invade burned and eroded areas (Carlström 1996) and is therefore an evidence for fire disturbances in
the past. Dicranopteris l. is also highly inflammable (Swabey 1970) and poses a high risk to induce or
spread fire. Additionally our results show a higher presence of invasive species on the northern back side
of Fond D’Albaretz, especially for saplings. It is known that introduced species will spread into gaps
caused by fire (Meuwly). We can therefore suggest that the forest on the back side must have been more
fire-disturbed because an undisturbed stable native forest could not have been invaded by alien species
by that extent. A third evidence for a reduced amount of disturbance of the Fond D’Albaretz forest is
personal observation by local people. Reportedly there was no fire event for at least 25 years before the
two fires in 2008 (personal communication Matthieu LaBuschagne 2008).
Discussion and conclusions
- 39 -
4.10 The potential for ecotourism
A main reason for the degradation of forests in general is the motivation to gain economic value out of
areas, e.g. through agricultural use or construction of settlements. An approach to preserve forests and at
the same time gain an economic value is ecotourism, which is defined as “Nature-based tourism that
involves education and interpretation of the natural environment and is managed to be ecologically
sustainable” (Commonwealth Department of Tourism, 1994). A sustainable ecotouristic use is desirable
because it raises people’s awareness of the beauty and uniqueness of the forest and demonstrates that it
must not be destroyed. This experience might motivate tourists to donate for conservation actions,
which are crucial in terms of forest preservation.
These days, the Fond D’Albaretz is already used for ecotourism. Several times a week, tourists have the
opportunity to experience the beauty of the forest on guided walks. However, only a small portion of the
forest (the eastern part of the Jean-Baptiste Nature Trail) is shown and we suggest that there is a huge
potential to expand the adventure for tourists. The potential is founded in the special characteristics of
the Fond D’Albaretz:
• Our results clearly showed that the forest is of outstanding ecological quality throughout.
• Due to its unique character as a relic of an original low-altitude forest, one can feel the
prehistoric time when the Seychelles were still a part of Gondwanaland.
• Sheltering a lot of threatened species, the Fond D’Albaretz is a hotspot in terms of floristics and
biodiversity.
• There is an outstanding scenic potential which can be enjoyed from several easily accessible
view-points.
• The size of the Fond D’Albaretz is optimal for an ecotouristic use: It is large enough that
different plant communities, habitats and scenes can be found and small enough that one can
keep the overview.
• It is an example for human influence on an intermediate forest system.
• The presence of modern threats, e.g. human-caused forest fires or invasive species, clearly shows
the fragility of such a relic forest.
• The fire-succession-process after a disturbance can impressively be shown along the Jean-Baptiste
Nature trail.
• It is a great adventure to explore the nature of the Fond D’Albaretz along the trails.
• The location in the south-east of Praslin is ideal because of its calmness and virginity.
We attest the Fond D’Albaretz an overall importance and suggest implementing the above mentioned
points into a comprehensive ecotourism concept. A first action could be to offer walks on the western
side of the Jean-Baptiste Nature Trail and on the expanded Nature Trail. The comparison of the species
composition along the Jean-Baptiste Nature Trail and the expanded Nature Trail does not show
significant differences. Whereas the eastern part of the Jean-Baptiste Nature Trail is already visited
weekly by tourists, the expanded Nature Trail is nowadays not used much by tourists. Actually, the
expanded Nature Trail is as interesting for tourists as the Jean-Baptiste Nature Trail and has some
specialities to show: In the vicinity of sub-transect 2E the ruins of an old house are visible, giving a good
impression of the impact of humans on the species composition of a forest: In the vicinity of the ruins,
commercial fruit trees like Mangifera i. or Artocarpus a. can be found and also the prominence of
Cinnamomum v. is higher than in other regions.
Due to the remoteness of the expanded Nature Trail, the management of the Hotel Coco de Mer
anticipates the construction of small huts to enable two-day-walks. Based on the present research this
idea indeed bears the potential of not only making tourists aware of how forest ecology in the Seychelles
works, but also to offer people unique contacts with a floristic hotspot in a beautiful, well conserved
surrounding.
Discussion and conclusions
- 40 -
However, there is always a trade-off between the potential damage tourism can do and the benefits of
making people aware of the natural beauty. Construction in remote forest areas and especially a higher
frequency of human presence also pose risks for the vegetation. Thus the concept of guided and
monitored walks should be extended to minimize the impact on the vegetation. We are confident that
the positive aspects of ecotourism outweigh the risk for potential damages.
There are a lot of threatened areas of special conversation value in the Seychelles. We suggest the
concept of ecotourism of the Fond D’Albaretz as a model for nature conservation. A win-win-situation
can be achieved: Valuable areas can be preserved and lead to an increased touristic attractiveness of the
Seychelles. A label could be designed for hotels which preserve nature by means of ecotourism. This
could also build up pressure on hotels which do not follow the idea of ecotourism.
4.11 Recommendations
General site management
The current management actions like removing invasive and planting endemic species should be
continued and if possible expanded. We strongly recommend the documentation of plantings and
cuttings. Especially threatened species should be monitored and even georeferenced with GPS. In order
to organize the management of the Fond D’Albaretz forest properly, we strongly recommend developing
a detailed management plan for the next few years containing objectives, aims and specific actions. It is
also important to define specific tasks and allocate them to competent people. Conservation actions
guided by a management plan are more purposeful than on an ad-hoc basis. It is an ideal mean, to
obtain and improve the ecological value, the scenic potential and the touristic attractiveness of the Fond
D’Albaretz.
With regard to a long term management it would be favourable to have an own plant nursery, which can
deliver desired species and fulfil the special requirement of the Fond D’Albaretz. In case of a fire event,
rehabilitation action would be easier due to the existence of adequate saplings.
To recognize eventual changes in vegetation we recommend a repeating vegetation monitoring. The
baseline was established in this work. Special attention should be given to rehabilitated sites where alien
invasive species were taken out and endemic species were newly planted. It is important to gain more
knowledge about how invasive species can be reduced the best and which species should be planted
afterwards.
Construction work like maintaining and expanding of trails, taking out invasive trees or building the
projected huts should be done very carefully because disturbed sites pose a high potential for invasion.
The canopy should remain as closed as possible and no erosion should be caused.
Management to protect the forest from fire disturbances
To protect the forest from fire events or to prevent the spread of fires we recommend the building of so
called “shaded fuel breaks”. They can efficiently hinder a fire to spread and thus protect the forest.
Instead of logging all plants along a trail, only the understory vegetation should be removed and soil
disturbance should be minimized. By building such shaded fuel breaks it is important to be aware of the
potential of disturbed areas to become invaded. The cleared area on the forest ground represents an
optimal habitat for invaders like Dicranopteris l. or Chrysobalanus i. These two species are able to bridge
adjacent sides separated by shaded fuel breaks. Thus, the canopy should be as closed as possible to
hinder invasive species to come in. The shaded fuel breaks should be maintained regularly to prevent
invasive species to establish and to keep the protective power against the spread of fires.
Discussion and conclusions
- 41 -
Due to the fact that the Jean-Baptiste Nature Trail is maintained and walked weekly, this trail already
acts as a minor fuel break. The fuel breaks protecting the Fond D’Albaretz could be enlarged along the
border of the property and along the expanded Nature Trail.
It is planned to build a fire tower on top of the Jean-Baptiste Nature Trail which collects rain water for
the case of a fire event. This stored water can be used to extinguish fire on-site and is cheaper and faster
than flying sea water in with a helicopter. To fight small fires the building of a fire tower seems
appropriate. However, for extensive fire events the stored water in the fire tower is by far not enough
and other sources and measures are crucial.
Management after a fire disturbance
After a fire event it is very important to protect the soil from erosion and to hinder invasive plant species
to establish. The building of erosion barriers can help to prevent the soil from erosion, especially in
steep areas. Even tough still a lot of nutrients are washed out by rain the hillsides can be stabilized and
the establishment of vegetation supported. Fire-disturbed areas provide a good opportunity for aliens to
establish. Probably the first species coming up are the invasives Adenanthera p. and Clerodendrum s. and
other species which have seeds distributed by birds (personal communication Michael Gill 2008). Also
the fern Dicranopteris l. will most probably establish sooner or later and then prevent other species from
growing. Thus it is very important to support the regeneration-process with maintaining actions like
planting of suitable native species and removing invasive species. Such suitable species are soil stabilizer
like the two sedges Lophoschoenus h. and Costularia f. or species with a high litter production. The
endemic palm Phoenicophorium b. proved to be a helpful species to rehabilitate disturbed areas. It is
robust and due to its high phenotypic plasticity the species can adapt to different habitat types. The leaf
litter produced by Phoenicophorium b. needs a long time to decompose and thus provides a good
protection against erosion.
To gain knowledge about the success of planted species, rehabilitated areas should be monitored. It is
important to distinguish between the planted and the non planted individuals that accurate conclusion
can be drawn. For future post-fire rehabilitation it is of interest which species survive the best and which
of the planted species are able to establish. Especially with regard to the planted endemic species it is of
great interest how they are able to develop in the future.
Fire risk map
Due to the fact that forests on Praslin are repeatedly affected by fire events, we recommend the
development of a Praslin-wide fire risk map. The required spatial data is available besides of locations
and extents of forest fires in the past. Therefore, we recommend creating a database where all fire events,
including date, exact location and extent are recorded. With those data, it would be possible to analyse
which parameters have the biggest influence on the risk to spread or induce fires.
The approach of ecotourism
Ecotourism has the great opportunity to benefit the conservation of the Fond D’Albaretz. To achieve
benefits, we recommend aiming at following targets:
• Generate money for management: It should be ensured that nature tourists contribute
financially to the preservation of the Fond D’Albaretz forest. To raise enough money for a
comprehensive management, the offer should be extended. This can be achieved by offering
guided walks on the western part of the Jean-Baptist Nature Trail and the expanded Nature
Trail or by the possibility for 2-day-walks with accommodation in a hut. There are numerous
other ideas to raise more money for conservation actions: Tourists could buy an endemic
sapling and plant it at an appropriate site, individual walks could be offered for people
interested in specific topics like birds or orchids, “marriage ceremonies in nature” could be
arranged etc.
Discussion and conclusions
- 42 -
• Involve local people and let them profit economically: If enough money can be raised to
establish a management system, jobs will be generated and local people can be hired. If they
profit from the forest, they will less likely have a negative impact on it and acts of arson, e.g. fire
spreading, can be averted.
• Raise people’s awareness of the importance of conservation: This affects not only tourists but
also local decision makers. The Hotel Coco de Mer could serve as a motivation for others to
anticipate an ecotouristic approach.
To avoid negative impacts of a higher human presence in the forest, tourists should be instructed and
guided. Clear rules should be defined and showed on a sign at the entrance of the forest.
4.12 Suitability of methods
Trail transecting
The trail transecting method is very useful and is quite easy to perform. With a relative small
expenditure of time a good overview on the species composition of a forest area can be obtained. Due to
the fact this method is more or less repeatable along the same trails it is possible to compare the gained
data with earlier findings.
Count-plot analysis
Count-plot analysis provides useful information on the stand structure of a forest type. It is
recommended to use this method together with trail transecting. Whereas trail transecting gives an
overview on the species composition of a whole area, the count-plot analysis is only representative for a
small area but provides additionally information about regeneration and tree density.
Photo monitoring
The photo monitoring has to be seen as a complementary method together with trail transecting or
count-plot analysis. It provides a snapshot of the actual state of the vegetation. Performed for several
years the changes in the vegetation can be visualized.
Boulder field classification
This method established by Baader & Hendry (2007) for a palm forest on Mahé was also very useful for
our study site. Due to the fact that it can be performed while doing trail transecting there is no big
additional time needed. The specification between nine different boulder classes also seemed useful
within our study site and it is recommended to retain this classification.
Forest zoning based on nativeness and on red listed endemics
Forest zonings give a good overview on the different parts of a forest and its structural composition. Due
to the fact that each forest has his individual species composition it seems advisable to adapt the
criterions and the zones in each case. Whereas Baader & Hendry (2007) differentiated between several
palm forests, in our study site such a classification would not have been reasonable. However, if the
forest zoning should be comparable with other studies one should rely more or less on the same
criterions.
Zonation based on protection values (PtV)
The protection value gives a good general idea of the protection priority of an area and is very useful to
compare different forest areas. Due to the fact that the protection value is calculated quite broad and
only five levels are distinguished we got for most of the sub-transects the same value. Thus an additional
quantification was done to distinguish the protection value of each sub-transect better. Thereby also
small differences within the sub-transect became visible.
Discussion and conclusions
- 43 -
Dicranopteris linearis survey
The Dicranopteris l. survey, like it was performed for this study, was very useful to get an overview of the
spread of the fern along the sub-transects. However, for doing scientific research about the spread and
establishment of Dicranopteris l. a more precise method should be developed.
Boulder field mapping
Owing to the combination of satellite imagery and field trips a bright overview on the boulder fields
within the study site could be gained. Especially in the vicinity of the trails a lot of information about
the location, extent and structure of boulder fields were gathered. However, it was not possible to cross
the forest everywhere and to ensure that all boulder fields are mapped.
Qualitative monitoring of post-fire areas
This method was designed to deal with the lost plots at Fond Ferdinand. No quantitative resurvey was
possible and time was scarce. The qualitative monitoring method used enabled us to gain a lot of useful
information. However, quantitative methods likes trail transecting and count-plot analysis are
recommended. Due to the fact that these two methods are more precise, it is possible to repeat the
monitoring in future research projects the same way and changes in the vegetation can be observed
better.
Fire risk map
The GIS-analysis effectively integrates different risk-parameters to a single map which visualizes the fire
risk of the whole area. High fire risk areas can be identified and possible spreads of fire estimated.
However, due to a lack of fire data, no linear regression could be performed to investigate the
importance of the different risk factors.
- 44 -
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- 46 -
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix -
A Plant List Fond D’Albaretz
B Monitoring Protocols
C Sampling Plots: Data
D Trail Transects: Data
E Fire Risk Map: Geoprocessing Models
F List of planted species in the burned area
- Digital Appendix - The digital appendix can be found on the CD.
G Sampling Plots: General descriptions, Data,
Photo-Monitoring and Sketches
H Trail Transects: Photo-Monitoring, Data
I Literature
K Report
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix A -
Plant List Fond D’Albaretz
Plant List Fond D'Albaretz (Based on Trail Transecting and Count Plot Analysis)
Species Creol name StatusRed list status
(Huber&Ismail, 2006)
Adenanthera pavonina Agati Invasive
Allophylus pervillei Bois cafoul Indigenous
Allophylus sechellensis Bois cafoul trois feuilles Endemic VU
Alstonia macrophylla Bois jaune Invasive
Anacardium occidentale Cajou Invasive
Aphloia theiformis var. seychellensis Bois merles Endemic VU
Artocarpus altilis Bread fruit Alien
Averrhoa bilimbi Bilimbi Alien
Bambusa vulgaris Bambou jaune Alien
Calophyllum inophyllum Takamaka Indigenous
Canthium bibracteatum Bois dur rouge Indigenous
Casuarina equisetifolia Cèdre Invasive
Chrysobalanus icaco Prune de France Invasive
Cinnamomum verum Cannelle Invasive
Clerodendrum speciosissimum Modestie rouge Invasive
Craterispermum microdon Bois doux Endemic EN
Deckenia nobilis Palmiste Endemic NT
Dillenia ferruginea Bois rouge Endemic VU
Diospyros sechellarum Bois sagaye Endemic NT
Dracaena reflexa Bois chandelle blanc Indigenous
Drypetes riseleyi Bois maré petite feuille Endemic CR
Erythroxylum sechellarum Café marron petite feuille Endemic LC
Euphorbia pyrifolia Bois du lait Indigenous
Ficus lutea Afouche grande feuille Indigenous
Gastonia crassa Bois banane Endemic VU
Haematoxylum campechianum Campèche Alien
Intsia bijuga Gaïac Indigenous
Leucaena leucocephala Cassie Invasive
Lodoicea maldivica Coco de Mer Endemic VU
Ludia mauritiana var. sechellensis Prunier marron Endemic VU
Mangifera indica Manguier Alien
Memecylon elaeagni Bois calou Endemic LC
Nephrosperma vanhoutteanum Latanier millepatte Endemic VU
Northea hornei Capucin Endemic VU
Ochna ciliata Bois démon Invasive
Pandanus multispicatus Vacoa de montagne Endemic NT
Pandanus sechellarum Vacoa marron Endemic NT
Paragenipa wrightii Café marron grande feuille Endemic NT
Phoenicophorium borsigianum Latanier feuille Endemic LC
Pouteria obovata Bois mon père Indigenous
Premna serratifolia Bois siro Indigenous
Psidium cattleianum Gouyave de Chine Invasive
Psychotria pervillei Bois couleuvre Endemic VU
Syzygium wrightii Bois pomme Endemic VU
Tabebuia palida Calice du pape Invasive
Terminalia catappa Badamier Indigenous
Verschaffeltia splendida Latanier latte Endemic VU
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix B -
Monitoring Protocols
Farrèr & Hertach (2008), Fond D'Albaretz Project
Plot-Nr.: Date: Slope:
Marker tree (Coordinates and description):
Soil Granulation Degradation
(from central point of plot)
□ Clay (< 2mm) □ natural conditions
□ Silt (2-50mm) □ 0% □ close to natural conditions
□ Sand (50-2000mm) □ 1-25% □ altered, visible human impact:
□ Gravel □ 26-50% …
□ Stones □ 51-75% □ degraded
□ Blocks/Boulders □ 76-100% □ heavily degraded
Dicranopteris l.
North
East
South
West
Litter
Corner
North
East
South
West
General view
Herb-layer
Corner Litter (Species) Plant species Surrounding area other observations
North
East
South
West
r 1-2 individual
General Description
Canopy Openness
BB-Category Cover
BB-Category + Covering < 1% of the area
1 Covering 1-5% of the area
4 Covering 50-75% of the area
5 Covering > 75% of the area
2 Covering 5-25% of the area
3 Covering 25-50% of the area
BB-Category Species (dominating species is underlined)
Plant species
Surrounding area
Dead trees
other observations
Photo Monitoring
Farrèr & Hertach (2008), Fond D'Albaretz Project
Date: GPS-Coordinates of marker tree:
[m]Adult (T: h >2m, dhb>3cm;
P: leaves > 100cm, true stem)
Sapling (T: 0.5-2m, dhb <3cm;
P: leaves>100cm, no stem)
M. prom. Seedling (T: <0.5m,
<3cm; P: <100cm, no stem)Comments / Geographic features
0 PhM, Boulder-F., GPS-Point
2
4
6
8
10 Boulder-F.
12
14
16
18
20 Boulder-F.
22
24
26
28
30 Boulder-F.
32
34
36
38
40 Boulder-F.
42
44
46
48
50 Boulder-F.
52
54
56
58
60 Boulder-F.
62
64
66
68
70 Boulder-F.
72
74
76
78
80 Boulder-F.
82
84
86
88
90 Boulder-F.
92
94
96
TRAIL TRANSECTING
Subtransect-Nr.:
Nr.Adult (T: h >2m, dhb>3cm;
P: leaves > 100cm, true stem)
Sapling (T: 0.5-2m, dhb <3cm;
P: leaves>100cm, no stem)
M. prom. Seedling (T: <0.5m,
<3cm; P: <100cm, no stem)Comments / Geographic features
98
100 Boulder-F., GPS-Point
102
104
106
108
110 Boulder-F.
112
114
116
118
120 Boulder-F.
122
124
126
128
130 Boulder-F.
132
134
136
138
140 Boulder-F.
142
144
146
148
150 Boulder-F.
152
154
156
158
160 Boulder-F.
162
164
166
168
170 Boulder-F.
172
174
176
178
180 Boulder-F.
182
184
186
188
190 Boulder-F.
192
194
196
198
200 Boulder-F.
Farrèr & Hertach (2008), Fond D'Albaretz Project
Plot-Nr.: Date:
Adults, dbh (cm) North East South West Tot
Sapling, height (cm) Tot
Seedling, # Tot
West
Count Plot Analysis
North East South
North East South West
SUBTRANSECT: SIDE: □ LEFT, □ RIGHT
length (m) height (m) No length (m) height (m) No
0
10
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160
170
180
190
200
1 Distance form the start of the trail subtransect Class Description Cover2 % boulder-coverage of the ground within 10m-belt 1 03 If the sizes of several boulders within one 10m-belt vary significantly, 1a 0
a second estimation for this boulder sizes can be noted here 2 ≥ 50%4 Total number of individual boulders counted within the 10m-belt 2a < 50%
3 ≥ 50%
3a < 50%
4 ≥ 50%
4a < 50%
Farrèr & Hertach (2008), Fond D'Albaretz Project 5 -Bluffs of rock H > 4m, L > 8m
Boulder field with huge boulders 2m < H ≤ 4m, 2m < L ≤ 8m
Area wiht a few huge boulders 2m < H ≤ 4m, 2m < L ≤ 8m
Boulder field with mixed boulder sizes H,L: > 0.5m and ≤ 2m
Area with a few different sized boulders H,L: > 0.5m and ≤ 2m
-
Area without boulders between bluffs of rocks No boulders
Area with a few small boulders H: ≤ 0.5m, L: ≤ 0.5m
Boulder field with small boulders H: ≤ 0.5m, L: ≤ 0.5m
Definition
Area without boulders
Remarks Adult (T: h >2m, dhb>3cm;
P: leaves > 100cm, true stem)
Sapling (T: 0.5-2m, dhb <3cm;
P: leaves>100cm, no stem)Remarks
BOULDER FIELD CLASSIFICATION
Boulders (within 10m perpendicular to trail, every 10m) Plants (most p. species within 10m perpendicular to trail)
[m] 1
% 2 Size of Boulder Size of Boulder 2
3
Total 4 Classes
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix C -
Sampling Plots: Data
Sampling Plot A
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 29.7 5.1 20.2 14.4
Allophylus p. 0.0 0.0 0.0 13.4
Anacardium o. 22.8 11.4 40.4 0.0
Calophyllum i. 0.0 0.0 0.0 5.1
Chrysobalanus i. 0.0 0.0 0.0 4.2
Cinnamomum v. 0.0 0.0 0.0 44.1
Deckenia n. 7.6 1.0 0.0 0.0
Dracaena r. 0.0 0.0 20.2 8.6
Dillenia f. 7.6 6.3 0.0 0.0
Ludia m. 0.0 0.0 0.0 4.2
Nephrosperma v. 0.0 0.0 0.0 8.0
Paragenipa w. 74.5 40.9 29.3 5.4
Phoenicophorium b. 22.8 14.5 40.4 44.4
Pouteria o. 35.0 20.8 49.5 48.2
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot B
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Allophylus p. 0.0 0.0 0.0 5.3
Canthium b. 0.0 0.0 0.0 5.3
Cinnamomum v. 0.0 0.0 0.0 20.0
Deckenia n. 31.0 4.2 16.3 6.9
Dracaena r. 0.0 0.0 16.3 5.3
Ludia m. 0.0 0.0 0.0 5.3
Nephrosperma v. 10.3 2.2 0.0 21.6
Paragenipa w. 88.7 80.9 48.8 18.4
Phoenicophorium b. 54.5 11.9 73.8 59.5
Pouteria o. 15.6 0.7 45.0 52.3
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot C
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 9.7 1.0 0.0 7.9
Allophylus p. 0.0 0.0 0.0 12.0
Allophylus s. 0.0 0.0 0.0 5.1
Canthium b. 22.4 2.3 0.0 8.3
Chrysobalanus i. 0.0 0.0 28.6 0.0
Cinnamomum v. 0.0 0.0 0.0 20.4
Deckenia n. 0.0 0.0 57.1 6.8
Diospyros s. 9.7 0.3 0.0 2.6
Dracaena r. 0.0 0.0 28.6 5.1
Ludia m. 0.0 0.0 0.0 7.7
Memecylon e. 12.7 0.5 0.0 43.5
Nephrosperma v. 9.7 0.3 28.6 13.5
Paragenipa w. 60.0 58.4 28.6 13.2
Phoenicophorium b. 66.1 31.0 0.0 40.5
Pouteria o. 0.0 0.0 28.6 13.3
Syzygium w. 9.7 6.3 0.0 0.0
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot D
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Allophylus p. 0.0 0.0 0.0 11.2
Allophylus s. 0.0 0.0 0.0 6.9
Canthium b. 14.5 0.5 0.0 3.4
Chrysobalanus i. 0.0 0.0 40.0 7.0
Cinnamomum v. 14.5 21.7 44.0 107.8
Deckenia n. 17.2 10.8 10.7 0.0
Diospyros s. 7.2 9.5 0.0 3.4
Dracaena r. 0.0 0.0 0.0 6.7
Erythroxylum s. 7.2 0.3 0.0 0.0
Memecylon e. 17.2 1.6 0.0 6.9
Nephrosperma v. 34.4 24.3 0.0 14.6
Paragenipa w. 27.1 2.9 10.7 7.3
Phoenicophorium b. 53.3 28.0 54.7 10.8
Pouteria o. 7.2 0.3 40.0 14.1
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot E
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 36.9 17.5 0.0 78.8
Chrysobalanus i. 0.0 0.0 0.0 7.3
Cinnamomum v. 53.7 40.0 121.4 46.5
Dracaena r. 0.0 0.0 0.0 7.3
Ludia m. 0.0 0.0 0.0 10.9
Memecylon e. 0.0 0.0 0.0 3.6
Nephrosperma v. 37.6 29.1 0.0 15.6
Paragenipa w. 0.0 0.0 0.0 3.6
Phoenicophorium b. 51.2 13.3 39.3 11.0
Pouteria o. 20.7 0.2 39.3 15.3
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot F
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 16.4 1.9 22.5 6.2
Allophylus p. 0.0 0.0 0.0 3.1
Allophylus s. 0.0 0.0 0.0 3.3
Calophyllum i. 0.0 0.0 0.0 3.1
Canthium b. 0.0 0.0 0.0 12.2
Cinnamomum v. 0.0 0.0 0.0 19.5
Dillenia f. 18.4 43.5 0.0 0.0
Dracaena r. 8.2 1.3 0.0 3.1
Erythroxylum s. 8.2 0.6 0.0 3.1
Ludia m. 0.0 0.0 0.0 9.7
Memecylon e. 0.0 0.0 0.0 3.1
Nephrosperma v. 0.0 0.0 0.0 16.2
Ochna c. 0.0 0.0 0.0 3.1
Paragenipa w. 70.1 43.7 90.0 17.2
Phoenicophorium b. 52.5 6.4 87.5 65.8
Pouteria o. 26.2 2.7 0.0 31.4
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot G
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 30.7 24.8 0.0 41.5
Allophylus p. 0.0 0.0 0.0 9.2
Allophylus s. 0.0 0.0 0.0 4.7
Canthium b. 13.3 0.7 0.0 0.0
Cinnamomum v. 26.5 0.9 50.0 85.5
Dracaena r. 0.0 0.0 0.0 13.6
Ludia m. 0.0 0.0 0.0 16.0
Nephrosperma v. 0.0 0.0 0.0 4.5
Paragenipa w. 13.3 0.7 0.0 0.0
Phoenicophorium b. 103.0 71.2 150.0 11.1
Pouteria o. 0.0 0.0 0.0 13.9
Verschaffeltia s. 13.3 1.7 0.0 0.0
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot H
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 0.0 0.0 0.0 5.5
Alstonia m. 0.0 0.0 17.7 0.0
Canthium b. 24.0 0.3 76.2 36.3
Cinnamomum v. 0.0 0.0 0.0 5.5
Dracaena r. 0.0 0.0 0.0 5.5
Erythroxylum s. 0.0 0.0 35.4 5.5
Memecylon e. 0.0 0.0 17.7 0.0
Nephrosperma v. 0.0 0.0 0.0 10.9
Paragenipa w. 137.8 92.8 0.0 19.8
Phoenicophorium b. 20.7 0.5 17.7 59.7
Pouteria o. 17.5 6.4 17.7 51.5
Tabebuia p. 0.0 0.0 17.7 0.0
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Sampling Plot I
Saplings Seedlings
[PV1] [dbh-dom.
2] [PV
1] [PV
1]
Adenanthera p. 17.8 0.3 0.0 23.0
Allophylus s. 0.0 0.0 0.0 8.0
Calophyllum i. 0.0 0.0 0.0 7.8
Chrysobalanus i. 0.0 0.0 0.0 11.9
Cinnamomum v. 17.8 10.9 0.0 97.1
Dracaena r. 0.0 0.0 0.0 3.9
Nephrosperma v. 0.0 0.0 0.0 8.0
Paragenipa w. 0.0 0.0 0.0 3.9
Phoenicophorium b. 123.7 87.8 200.0 19.0
Pouteria o. 40.8 0.9 0.0 17.4
1 PV: Prominence Value
2 dbh-dom.: Relative dominance in % based on cumulated dbhs
Adult Trees
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix D -
Trail Transects: Data
Trail Transecting Data Adult: Fond D'Albaretz (Jean Baptiste Nature Trail & expanded Nature Trail)
Ad
en
an
the
ra p
.
Allo
ph
ylu
s p
.
Allo
ph
ylu
s s.
Als
ton
ia m
.
An
aca
rdiu
m o
.
Art
oca
rpu
s a
.
Ave
rrh
oa
b.
Ba
mb
usa
v.
Ca
nth
ium
b.
Ca
lop
hy
llu
m i.
Ca
sua
rin
a e
.
Ch
ryso
ba
lan
us
i.
Cin
na
mo
mu
m v
.
Cle
rod
en
dru
m s
.
Cra
teri
spe
rmu
m m
.
De
cke
nia
n.
Dille
nia
f.
Dio
spy
ros
s.
Dra
cae
na
r.
Dry
pe
tes
r.
Ery
thro
xylu
m s
.
Eu
ph
orb
ia p
.
Fic
us
l.
Ha
em
ato
xylu
m c
.
Ints
ia b
.
Lod
oic
ea
m.
Lud
ia m
.
1A 1 3 3 4 4 3 2 2 1 10 3 1
1B 1 1 16 2 5 6 3 4 5 8
1C 2 2 4 3 1 2 4 6 4 4 2 2
1D 1 1 1 2 1 12 1 5 2
1E 4 2 3 6 1 1 12 3 1 3 2 2 1
1F 2 3 9 1 9 6 2 1 2
1G 2 1 1 2 1 2 2 18 1 4 5 4
1H 1 4 3 2 1 6 5 1 2 3
2A 2 2 5 1 10 5 5 4 1 2 2 1
2B 4 1 1 5 4 2 8 1 1 1
2C 16 3 2 6 1 3 1
2D 6 1 1 5 4 3
2E 5 1 1 4 1 1 36 1 2
2F 7 1 3 3 2 1 1 4 1 10 2 3 2
2G 3 3 2 2 1 5 3 9 7 1 1
2H 1 3 6 12 1 4 2 7 2 1
Sum 52 10 3 2 20 3 1 3 64 20 14 26 106 1 2 35 99 11 19 4 48 2 5 13 10 4 8
Frequency 13 5 1 2 8 1 1 1 15 9 10 10 13 1 1 14 14 3 8 1 13 1 3 4 6 2 5
%-Frequency 4.96 1.91 0.38 0.76 3.05 0.38 0.38 0.38 5.73 3.44 3.82 3.82 4.96 0.38 0.38 5.34 5.34 1.15 3.05 0.38 4.96 0.38 1.15 1.53 2.29 0.76 1.91
1A 1 0 2 0 2 0 0 0 2 2 2 2 2 0 0 1 4 0 0 0 2 0 0 1 0 0 0
1B 0 0 0 1 1 0 0 0 4 2 0 3 3 0 0 2 2 0 0 0 3 0 0 3 0 0 0
1C 2 2 0 0 2 0 0 0 2 1 2 0 2 0 0 3 2 0 0 0 2 0 2 2 0 0 0
1D 1 0 0 0 0 0 0 0 1 0 1 2 0 0 0 1 4 0 1 0 3 0 0 0 0 2 0
1E 0 2 0 0 2 0 0 2 3 0 1 1 4 0 0 2 1 0 2 0 2 0 0 2 1 0 0
1F 2 0 0 0 2 0 0 0 4 1 0 0 0 0 0 0 4 0 3 0 2 0 1 0 2 0 0
1G 2 1 0 1 0 0 0 0 2 1 0 0 2 0 0 2 5 0 1 2 3 0 0 0 0 0 2
1H 1 0 0 0 0 0 0 0 2 0 0 2 0 0 2 1 3 3 1 0 2 0 0 0 2 0 0
2A 2 2 0 0 0 0 0 0 3 0 1 0 4 0 0 3 0 3 2 0 1 2 0 0 2 0 1
2B 2 0 0 0 0 0 0 0 1 0 1 3 2 0 0 2 3 1 1 0 0 0 0 0 0 0 1
2C 4 0 0 0 0 0 0 0 0 2 2 0 3 0 0 1 2 0 0 0 0 0 0 0 0 0 1
2D 3 0 0 0 0 0 0 0 1 0 0 1 3 0 0 2 2 0 0 0 0 0 0 0 0 0 0
2E 3 0 0 0 0 0 1 0 1 2 1 1 6 0 0 1 0 0 0 0 2 0 0 0 0 0 0
2F 3 0 0 0 1 2 0 0 2 2 1 1 2 0 0 1 4 0 2 0 2 0 0 0 0 2 0
2G 2 0 0 0 2 0 0 0 2 2 1 3 2 0 0 0 4 0 0 0 3 0 0 0 1 0 1
2H 0 1 0 0 2 0 0 0 3 0 0 0 4 1 0 2 2 0 0 0 3 0 2 0 1 0 0
Abundance 28 8 2 2 14 2 1 2 33 15 13 19 39 1 2 24 42 7 13 2 30 2 5 8 9 4 6
%-Abundance 4.38 1.25 0.31 0.31 2.19 0.31 0.16 0.31 5.16 2.35 2.03 2.97 6.10 0.16 0.31 3.76 6.57 1.10 2.03 0.31 4.69 0.31 0.78 1.25 1.41 0.63 0.94
Prominence Value 9.34 3.16 0.69 1.08 5.24 0.69 0.54 0.69 10.89 5.78 5.85 6.79 11.07 0.54 0.69 9.10 11.92 2.24 5.09 0.69 9.66 0.69 1.93 2.78 3.70 1.39 2.85
indigenous alienendemic invasive
Me
me
cylo
n e
.
Ne
ph
rosp
erm
a v
.
No
rth
ea
h.
Och
na
c.
Pa
nd
an
us
m.
Pa
nd
an
us
s.
Pa
rag
en
ipa
w.
Ph
oe
nic
op
ho
riu
m b
.
Po
ute
ria
o.
Pre
mn
a s
.
Psi
diu
m c
.
Sy
zyg
ium
w.
Ta
be
bu
ia p
.
Te
rmin
alia
c.
Ve
rsch
aff
elt
ia s
.
To
tal
2 36 7 14 4 100
2 29 8 9 1 100
36 18 10 100
5 1 33 23 10 98
1 3 26 14 15 100
2 2 24 25 10 1 1 100
1 13 37 5 1 100
7 9 29 15 9 3 100
11 10 2 11 22 3 1 100
8 9 1 1 19 27 4 3 100
21 2 7 31 1 1 5 100
2 3 8 8 42 8 9 100
5 11 6 21 5 100
1 4 4 16 28 3 2 2 100
1 2 7 24 13 15 1 100
1 4 23 17 6 2 8 100
32 78 2 2 4 35 340 348 127 2 1 8 16 3 15 1598
8 13 1 1 3 7 16 16 16 1 1 4 5 2 3 262
3.05 4.96 0.38 0.38 1.15 2.67 6.11 6.11 6.11 0.38 0.38 1.53 1.91 0.76 1.15 100
0 0 0 2 0 0 6 3 4 0 0 0 2 0 0 40
0 2 0 0 0 0 5 3 4 0 0 1 0 0 0 39
0 0 0 0 0 0 6 5 4 0 0 0 0 0 0 39
0 3 0 0 1 0 6 5 4 0 0 0 0 0 0 35
1 2 0 0 0 0 5 4 4 0 0 0 0 0 0 41
0 0 2 0 0 2 5 5 4 0 0 0 1 0 1 41
0 1 0 0 0 0 4 6 3 0 0 1 0 0 0 39
3 4 0 0 0 0 5 4 4 0 0 2 0 0 0 41
4 4 0 0 2 0 4 5 2 0 1 0 0 0 0 48
3 4 0 0 1 1 5 5 2 0 0 2 0 0 0 40
0 5 0 0 0 2 3 5 1 0 0 0 0 1 3 35
2 2 0 0 0 3 3 6 3 0 0 0 0 0 4 35
0 3 0 0 0 4 3 5 3 0 0 0 0 0 0 36
1 2 0 0 0 2 4 5 2 0 0 0 2 2 0 45
1 2 0 0 0 3 5 4 4 0 0 0 1 0 0 43
1 2 0 0 0 0 5 5 3 2 0 0 3 0 0 42
16 36 2 2 4 17 74 75 51 2 1 6 9 3 8 639
2.50 5.63 0.31 0.31 0.63 2.66 11.58 11.74 7.98 0.31 0.16 0.94 1.41 0.47 1.25 100
5.56 10.60 0.69 0.69 1.77 5.33 17.69 17.84 14.09 0.69 0.54 2.47 3.32 1.23 2.40 200
Trail Transecting Data Sapling: Fond D'Albaretz (Jean Baptiste Nature Trail & expanded Nature Trail)
Ad
en
an
the
ra p
.
Allo
ph
ylu
s p
.
An
aca
rdiu
m o
.
Ap
hlo
ia s
.
Ca
nth
ium
b.
Ca
lop
hy
llu
m i.
Ca
sua
rin
a e
.
Ch
ryso
ba
lan
us
i.
Cin
na
mo
mu
m v
.
De
cke
nia
n.
Dille
nia
f.
Dio
spy
ros
s.
Dra
cae
na
r.
Ery
thro
xylu
m s
.
Fic
us
l.
Ga
sto
nia
c.
Ha
em
ato
xylu
m c
.
Ints
ia b
.
Leu
cae
na
l.
Lod
oic
ea
m.
Lud
ia m
.
Ma
ng
ife
ra i.
Me
me
cylo
n e
.
Ne
ph
rosp
erm
a v
.
Och
na
c.
Pa
nd
an
us
m.
Pa
nd
an
us
s.
1A 2 4 6 1 9 1 3 1 1 3 3
1B 9 1 21 1 6 1 1 1 2 6
1C 1 4 1 2 2 11 2 2 1 2 1
1D 1 2 4 12 1 2 3 13
1E 4 1 12 2 4 5 1 2 1 8
1F 2 1 3 7 2 8 1 1 1
1G 1 1 3 1 3 2 10 1 10 1 4
1H 2 3 1 10 2 1 2 1 2 5 14
2A 13 2 1 5 8 1 4 25
2B 2 19 5 1 1 2 18
2C 1 3 15 1 16
2D 5 2 1 1 2 12 2
2E 1 3 13 1 1 10
2F 1 2 2 7 4 1 4 5
2G 9 3 3 1 1 7 2
2H 1 4 3 5 5 5 1 1 6
Sum 3 23 5 1 49 15 2 103 66 56 11 1 50 3 1 1 6 1 1 3 2 1 14 150 4 2 2
Frequency 3 6 4 1 12 7 2 15 13 10 9 1 14 3 1 1 4 1 1 1 2 1 6 16 2 1 1
%-Frequency 1.57 3.14 2.09 0.52 6.28 3.66 1.05 7.85 6.81 5.24 4.71 0.52 7.33 1.57 0.52 0.52 2.09 0.52 0.52 0.52 1.05 0.52 3.14 8.38 1.05 0.52 0.52
1A 0 0 2 0 2 3 1 4 0 0 1 0 2 0 0 0 1 0 1 0 0 0 0 2 2 0 0
1B 0 0 0 0 4 0 1 5 1 3 1 0 1 1 0 0 2 0 0 0 0 0 0 3 0 0 0
1C 0 0 1 0 2 1 0 2 2 4 2 0 2 0 0 0 1 0 0 0 0 0 0 2 1 0 0
1D 0 0 1 0 2 0 0 2 0 4 1 0 2 0 0 0 0 0 0 2 0 0 0 4 0 0 0
1E 0 2 1 0 4 2 0 2 3 0 0 0 1 0 0 0 2 0 0 0 0 0 1 3 0 0 0
1F 0 0 0 0 2 1 0 2 3 2 0 0 3 0 0 0 0 1 0 0 1 0 0 1 0 0 0
1G 0 1 0 1 2 1 0 2 2 4 1 0 4 0 0 0 0 0 0 0 0 0 1 2 0 0 0
1H 0 2 0 0 2 1 0 4 2 1 2 1 2 0 0 0 0 0 0 0 0 0 3 4 0 0 0
2A 0 4 0 0 2 0 0 1 0 3 0 0 3 0 0 0 0 0 0 0 1 0 2 5 0 0 0
2B 0 0 0 0 2 0 0 5 3 0 0 0 1 0 0 1 0 0 0 0 0 0 2 5 0 0 0
2C 1 0 0 0 0 0 0 2 4 0 0 0 0 0 0 0 0 0 0 0 0 0 1 4 0 0 0
2D 0 0 0 0 0 0 0 3 2 1 1 0 2 0 0 0 0 0 0 0 0 0 0 4 0 2 0
2E 1 0 0 0 0 0 0 2 4 0 0 0 1 0 0 0 0 0 0 0 0 1 0 4 0 0 0
2F 1 2 0 0 2 0 0 3 2 0 1 0 2 0 0 0 0 0 0 0 0 0 0 3 0 0 0
2G 0 0 0 0 0 0 0 4 2 2 1 0 0 1 0 0 0 0 0 0 0 0 0 3 0 0 2
2H 0 1 0 0 2 2 0 0 3 3 0 0 3 1 1 0 0 0 0 0 0 0 0 3 0 0 0
Abundance 3 12 5 1 28 11 2 43 33 27 11 1 29 3 1 1 6 1 1 2 2 1 10 52 3 2 2
%-Abundance 0.61 2.44 1.02 0.20 5.70 2.24 0.41 8.76 6.72 5.50 2.24 0.20 5.91 0.61 0.20 0.20 1.22 0.20 0.20 0.41 0.41 0.20 2.04 10.59 0.61 0.41 0.41
Prominence Value 2.18 5.59 3.11 0.73 11.99 5.91 1.45 16.61 13.53 10.73 6.95 0.73 13.24 2.18 0.73 0.73 3.32 0.73 0.73 0.93 1.45 0.73 5.18 18.97 1.66 0.93 0.93
endemic invasive indigenous alien
Pa
rag
en
ipa
w.
Ph
oe
nic
op
ho
riu
m b
.
Po
ute
ria
o.
Psy
cho
tria
p.
Ta
be
bu
ia p
.
Ve
rsch
aff
elt
ia s
.
To
tal
27 16 20 97
17 16 18 100
8 52 9 1 99
4 52 4 98
12 27 21 100
4 60 7 3 100
3 52 7 99
4 41 11 99
3 35 3 100
3 42 3 1 97
2 60 1 1 100
5 69 99
2 67 2 100
11 58 5 100
9 57 5 2 99
11 44 11 2 99
125 748 127 1 8 1 1586
16 16 15 1 4 1 191
8.38 8.38 7.85 0.52 2.09 0.52 100
5 4 5 0 0 0 35
5 4 5 0 0 0 36
3 6 4 0 1 0 34
2 6 2 0 0 0 28
4 5 5 0 0 0 35
2 6 3 0 2 0 29
2 6 3 0 0 0 32
2 6 4 0 0 0 36
2 6 2 0 0 0 31
2 6 2 1 0 0 30
2 6 1 0 0 1 22
3 7 0 0 0 0 25
2 7 2 0 0 0 24
4 6 3 0 0 0 29
4 6 3 0 2 0 30
4 6 4 0 2 0 35
48 93 48 1 7 1 491
9.78 18.94 9.78 0.20 1.43 0.20 100
18.15 27.32 17.63 0.73 3.52 0.73 200
Trail Transecting Data Seedling: Fond D'Albaretz (Jean Baptiste Nature Trail & expanded Nature Trail)
Ad
en
an
the
ra p
.
Allo
ph
ylu
s p
.
An
aca
rdiu
m o
.
Ap
hlo
ia s
.
Ca
nth
ium
b.
Ca
lop
hy
llu
m i.
Ca
sua
rin
a e
.
Ch
ryso
ba
lan
us
i.
Cin
na
mo
mu
m v
.
De
cke
nia
n.
Dio
spy
ros
s.
Dra
cae
na
r.
Ery
thro
xylu
m s
.
Eu
ph
orb
ia p
.
Ha
em
ato
xylu
m c
.
Leu
cae
na
l.
Lod
oic
ea
m.
Lud
ia m
.
Me
me
cylo
n e
.
Ne
ph
rosp
erm
a v
.
Och
na
c.
Pa
rag
en
ipa
w.
Ph
oe
nic
op
ho
riu
m b
.
Po
ute
ria
o.
Psy
cho
tria
p.
Ta
be
bu
ia p
.
To
tal
1A 16 7 1 5 5 3 1 10 21 22 3 94
1B 20 20 12 6 1 4 2 2 3 9 18 97
1C 13 13 17 3 5 21 23 95
1D 7 4 3 8 1 14 4 22 15 78
1E 3 1 14 3 25 5 3 1 12 17 84
1F 4 9 1 13 2 4 6 1 31 22 93
1G 7 2 2 7 18 5 1 8 6 5 14 13 88
1H 1 2 1 2 4 10 3 1 8 23 1 22 15 93
2A 11 6 4 1 21 1 4 1 4 2 13 4 14 1 1 88
2B 9 1 8 51 6 2 10 3 90
2C 36 1 2 53 1 4 97
2D 34 1 9 26 1 5 2 6 1 85
2E 8 1 74 5 3 1 92
2F 21 16 27 2 1 4 4 1 4 80
2G 3 1 2 1 8 19 1 1 2 1 1 6 1 47
2H 1 3 1 39 3 8 11 7 2 75
Sum 153 13 2 3 89 4 1 80 409 42 1 13 1 1 9 3 0 16 13 97 2 51 198 168 1 6 1376
Frequency 12 6 1 2 13 4 1 11 16 7 1 7 1 1 2 1 0 3 5 15 1 14 15 15 1 3 158
%-Frequency 7.59 3.80 0.63 1.27 8.23 2.53 0.63 6.96 10.13 4.43 0.63 4.43 0.63 0.63 1.27 0.63 0.00 1.90 3.16 9.49 0.63 8.86 9.49 9.49 0.63 1.90 100
1A 4 0 0 0 3 0 1 3 3 0 0 0 0 0 0 2 0 0 0 1 0 4 5 5 0 2 33
1B 0 0 0 0 5 0 0 5 4 3 0 0 1 0 2 0 0 0 0 2 2 2 4 5 0 0 35
1C 0 0 0 0 4 0 0 0 4 5 0 0 0 0 0 0 0 0 0 2 0 3 5 5 0 0 28
1D 0 0 0 0 3 0 0 2 2 3 0 1 0 0 0 0 0 0 0 4 0 2 5 4 0 0 26
1E 2 1 0 0 4 0 0 2 5 0 0 0 0 0 3 0 0 0 0 2 0 1 4 5 0 0 29
1F 2 0 0 0 4 0 0 1 4 2 0 0 0 0 0 0 0 2 0 3 0 1 5 5 0 0 29
1G 3 2 0 2 3 0 0 0 5 3 0 1 0 0 0 0 0 3 0 3 0 3 4 4 0 0 36
1H 1 2 0 1 2 0 0 2 4 2 0 1 0 0 0 0 0 0 3 5 0 1 5 4 0 0 33
2A 4 3 0 0 2 1 0 0 5 0 1 2 0 1 0 0 0 2 2 4 0 2 4 1 1 0 35
2B 4 0 0 0 1 0 0 3 6 0 0 0 0 0 0 0 0 0 0 3 0 2 4 2 0 0 25
2C 6 0 0 0 1 0 0 2 6 1 0 0 0 0 0 0 0 0 0 2 0 0 0 0 0 0 18
2D 6 0 0 0 1 0 0 4 5 0 0 0 0 0 0 0 0 0 1 3 0 2 3 1 0 0 26
2E 3 0 0 0 0 1 0 0 7 0 0 0 0 0 0 0 0 0 0 3 0 0 2 1 0 0 17
2F 5 0 0 0 0 0 0 4 5 0 0 2 0 0 0 0 0 0 1 2 0 2 1 2 0 0 24
2G 2 1 2 0 0 1 0 3 5 0 0 1 0 0 0 0 0 0 1 2 0 1 1 3 0 1 24
2H 0 1 0 0 2 1 0 0 6 0 0 2 0 0 0 0 0 0 0 0 0 3 4 3 0 2 24
Abundance 42 10 2 3 35 4 1 31 76 19 1 10 1 1 5 2 0 7 8 41 2 29 56 50 1 5 442
%-Abundance 9.50 2.26 0.45 0.68 7.92 0.90 0.23 7.01 17.19 4.30 0.23 2.26 0.23 0.23 1.13 0.45 0.00 1.58 1.81 9.28 0.45 6.56 12.67 11.31 0.23 1.13 100
Prominence Value 17.10 6.06 1.09 1.94 16.15 3.44 0.86 13.98 27.32 8.73 0.86 6.69 0.86 0.86 2.40 1.09 0.00 3.48 4.97 18.77 1.09 15.42 22.16 20.81 0.86 3.03 200
endemic invasive indigenous alien
Trail Transecting Data: Glacis Noir Trail
ADULT
An
aca
rdiu
m o
.
Ap
hlo
ia s
.
Ca
nth
ium
b.
Ca
sua
rin
a e
.
Ch
ryso
ba
lan
us
i.
Cin
na
mo
mu
m v
.
De
cke
nia
n.
Dille
nia
f.
Ery
thro
xylu
m s
.
Lud
ia m
.
Me
me
cylo
n e
.
Ne
ph
rosp
erm
a v
.
Pa
rag
en
ipa
w.
Ph
oe
nic
op
ho
riu
m b
.
Po
ute
ria
o.
Sy
zyg
ium
j.
Sy
zyg
ium
w.
To
tal
3A 1 5 2 19 2 7 8 5 2 17 19 6 7 100
3B 2 7 2 18 15 3 3 1 4 13 22 6 1 3 100
Sum 1 2 12 4 37 17 10 11 5 1 6 30 41 12 1 3 7 200
Frequency 1 1 2 2 2 2 2 2 1 1 2 2 2 2 1 1 1 27
%-Frequency 3.70 3.70 7.41 7.41 7.41 7.41 7.41 7.41 3.70 3.70 7.41 7.41 7.41 7.41 3.70 3.70 3.70 100
3A 1 0 3 2 5 2 3 3 3 0 2 5 5 3 0 0 3 40
3B 0 2 3 2 5 4 2 2 0 1 2 4 5 3 1 2 0 38
Abundance 1 2 6 4 10 6 5 5 3 1 4 9 10 6 1 2 3 78
%-Abundance 1.28 2.56 7.69 5.13 12.82 7.69 6.41 6.41 3.85 1.28 5.13 11.54 12.82 7.69 1.28 2.56 3.85 100
Prominence Value 4.99 6.27 15.10 12.54 20.23 15.10 13.82 13.82 7.55 4.99 12.54 18.95 20.23 15.10 4.99 6.27 7.55 200
SAPLING SEEDLING
Ca
nth
ium
b.
Ch
ryso
ba
lan
us
i.
Cin
na
mo
mu
m v
.
De
cke
nia
n.
Dille
nia
f.
Dio
spy
ros
s.
Me
me
cylo
n e
.
Ne
ph
rosp
erm
a v
.
Pa
nd
an
us
m.
Pa
rag
en
ipa
w.
Ph
oe
nic
op
ho
riu
m b
.
Po
ute
ria
o.
To
tal
Ch
ryso
ba
lan
us
i.
Cin
na
mo
mu
m v
.
Ery
thro
xylu
m s
.
Lud
ia m
.
Me
me
cylo
n e
.
Ne
ph
rosp
erm
a v
.
Pa
rag
en
ipa
w.
Ph
oe
nic
op
ho
riu
m b
.
Po
ute
ria
o.
Sy
zyg
ium
j.
Sy
zyg
ium
w.
To
tal
3A 42 1 4 1 1 3 7 1 5 24 3 92 3A 30 16 5 14 3 3 2 2 75
3B 1 52 7 2 3 2 21 2 90 3B 11 62 1 2 5 2 1 2 86
Sum 1 94 8 4 1 1 5 10 1 7 45 5 182 Sum 41 78 5 1 16 8 3 2 3 2 2 161
Frequency 1 2 2 1 1 1 2 2 1 2 2 2 19 Fr. 2 2 1 1 2 2 1 1 2 1 1 16
%-Frequency 5.26 10.53 10.53 5.26 5.26 5.26 10.53 10.53 5.26 10.53 10.53 10.53 100 %-Fr. 12.50 12.50 6.25 6.25 12.50 12.50 6.25 6.25 12.50 6.25 6.25 100
3A 0 6 1 2 1 1 2 3 1 3 5 2 27 3A 5 4 3 0 4 2 2 0 2 0 2 24
3B 1 6 3 0 0 0 2 2 0 2 5 2 23 3B 4 6 0 1 2 3 0 2 1 2 0 21
Abundance 1 12 4 2 1 1 4 5 1 5 10 4 50 Ab. 9 10 3 1 6 5 2 2 3 2 2 45
%-Abundance 2.00 24.00 8.00 4.00 2.00 2.00 8.00 10.00 2.00 10.00 20.00 8.00 100 %-Ab. 20.00 22.22 6.67 2.22 13.33 11.11 4.44 4.44 6.67 4.44 4.44 100
Prominence Value 7.26 34.53 18.53 9.26 7.26 7.26 18.53 20.53 7.26 20.53 30.53 18.53 200 PV 32.50 34.72 12.92 8.47 25.83 23.61 10.69 10.69 19.17 10.69 10.69 200
endemic invasive indigenous alien
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix E -
Fire Risk Map: Geoprocessing Models
Model for Topography-based parameters:
Model for Anthropogenic-based parameters:
Model for Vegetation-based parameter:
Vegetation Survey and GIS-based Zonation of the Fond
D’Albaretz Forest, Praslin, Seychelles
- Appendix F -
List of planted species in the burned area
Aphloia seychellensis Bois merles 19
Brexia madagascariensis Bois cateau 28
Canthium bibracteatum Bois dur rouge 54
Deckenia nobilis Palmiste 2
Diospyros seychellarum Bois sagaye 8
Dodonaea viscosa Bois de reinette 55
Dracaena reflexa Bois chandelle blanc 4
Intsia bijuga Gaiac 7
Nephrosperma vanhoutteanum Latanier millepatte 105
Northea hornei Capucin 1
Ochrosia oppositifolia Bois chauve souris 66
Paragenipa wrightii Café marron grande feuille 19
Phoenicophorium borsigianum Latanier feuille 25
Pittosporum senacia wrightii Bois joli coeur 101
Psychotria sp. Bois couleuvre 3
Syzygium wrightii Bois pomme 108
Tarenna sechellensis Bois dur bleu 15
Damaged plants 7
Total 627
Plantings, 11th and 18th of October 2008