Post on 24-Feb-2016
description
Tradeoffs in land and water productivity of rice with
establishment method and irrigation schedule
Sudhir Yadav and Liz Humphreys
Outline
• Establishment method of rice• Performance of DSR and AWD
field experiment Model simulation
•Conclusion•Research need
Rice agriculture is the engine of growth for rural and urban
economies…and maintaining peace
Conventional practice of growing RiceNursery raising
Puddling
Transplanting
Issues and Concerns• Labour cost and availability• Ground water depletion/deterioration • Energy requirement to pump groundwater• Productivity of rice• Soil and environmental health
*Some of these problems can be handled by changing establishment method of rice
Other practices of establishing Rice
Establishment method of rice
Transplanting
Puddled
Manual
Mechanical
Unpuddled
After dry Tillage
After Zero Tillage
Direct seeding
Wet seeding
Puddled field
Broadcasting
Line sowing
Unpuddled field
Broadcasting
Line sowing
Dry seeding
After dry tillage
After Zero tillage (+M/-
M)
Direct seeding
Mechanical transplanting, WSR & DSR• labour saving - reduced costs
- timely establishment
DSR• beneficial to non-rice crops in the rotation (e.g. wheat & maize) due to avoidance of puddling = improved soil)• opportunity to introduce conservation agriculture
in rice – upland rotations e.g. rice-wheat(zero tillage, surface residue retention = mulch)
Drivers of different establishment method
-40
-30
-20
-10
0
10
20
30
40
Prod
uctiv
ity in
dex
of D
SR
Performance of DSR in IGP
DSR is considered as a “water saving technology” but the fact is- it is just an “establishment method”
0
2
4
6
8
0 500 1000 1500 2000 2500 3000
Yield (t ha-1)
Water input (mm)
Increasing “drying period"
IRRIGATION+ RAIN
Adapted from Bouman & Tuong 2001
Rice is very sensitive to water deficit
11Ladha et al. (2000)
Irrigated rice & wheatRainfed rice, partially irrigated wheat
Punjab: “Food basket of India”
2009
0
2
4
6
8
10
PTR DSR
Yield (t/ha)
Daily 20 kPa 40 kPa 70 kPa
• Regardless of establishment method, rice very sensitive to soil drying
• With more water stress (>20 kPa), yield penalty was higher in DSR than PTR.
Water requirement of DSR vs puddled transplanted rice (PTR)Punjab, India (clay loam, deep watertable)
4 irrigation treatments - daily or soil water tension 20, 40 or 70 kPa at 15-20 cm
for potential, water-limited, and/or nitrogen-limited conditions (lowland, aerobic rice)Effects of weather, irrigation, nitrogen fertilizer, general management, variety characteristics, soil type (hydrological, native N supply)
version 2.0, 2004; and 2.13, 2009
Fully documented User-friendly interface (FSEWin) Tutorial available Standard evaluation methodology Standard data sets available www.knowledgebank.irri.org/oryza2000/
Oryza2000: a rice growth simulation model
Application of ORYZA• Calibration: from 2 year field experiment data• Evaluation: 4 irrigation regime each year• Simulation: 40 years (1970-2009) past weather
data of Ludhiana, India
Irrigation threshold• First 30 DAS: 2-d after disappearance of water• After 30 DAS: SWT based (10,20,..........70kPa)
Performance of ORYZA2000 to predict grain yield
Irrigation threshold
Gra
in y
ield
(kg
ha-1
)
Irrigation threshold
Gra
in y
ield
(kg
ha-1
)
Irrigation threshold
Gra
in y
ield
(kg
ha-1
)
Irrigation threshold
Gra
in y
ield
(kg
ha-1
)
PTR
DSR
2008
2008
2009
2009
Performance of ORYZA2000 to predict water balance components
Simulation with 40 years past weather data
Grain yield and IW input with different irrigation schedule
Irrigation threshold (kPa)
Gra
in y
ield
(kg
ha-1
)
Irrig
atio
n w
ater
(mm
)
PTR DSR
Irrigation threshold (kPa)
Eva
potra
nspi
ratio
n (m
m)
PTR DSR
Irrigation threshold (kPa)
Dra
inag
e (m
m)
Where is the water saving?
(Percolation+Seepage)
Can we count it under “water saving”
Safe AWD- PTR vs DSR
f(x) = 3.24 x − 424.3R² = 0.979335327149392
f(x) = 4.13519556091232 x − 396.092387772728R² = 0.975058114317446
PTR DSR
Day of year
Cum
ulat
ive
irrig
atio
n in
put (
mm
) Stage 1 Stage 2 Stage 3 y = 4.14x - 396.1R² = 0.97
y = 3.24x - 424.3R² = 0.98
Cracking in soil
SWT and Cracking intensity*
PTRDSR
Pro
porti
on a
rea
of c
rack
s (%
)
SW
T (k
Pa)
*measurement with WinDIAS Sofware
Water productivity: PTR vs DSR
PTRDSR
Irrigation threshold
WP
IW (g
kg-
1)
Irrigation threshold
WP
ET
(g k
g-1)
WP
I+R
(g k
g-1)
Target Technology Predicted outcome
Yield
(t ha-1)WPI
(g kg-1)
WPET
(g kg-1)
ET
mm
Maximizing yield DSR-CF 9.8 0.37 1.39 705
Maximizing WPI DSR-30 kPa 8.2 1.81 1.41 586
Maximizing WPET PTR-20 kPa 8.5 1.19 1.66 518
Minimizing ET PTR-60 kPa 7.2 1.30 1.45 497
Selection of establishment method and irrigation schedule
The biggest gains in irrigation water saving are from adoption of safe AWD (establishment method is of secondary importance)
Safe AWD • reduced runoff, percolation & seepage (no effect on
ET) (i.e. it will not make more water available for other uses where runoff & deep drainage can be used elsewhere)• reduced irrigation requirement for DSR by ~30%
compared with PTR in Punjab, India(needs to be evaluated in other situations)• requires ability to deliver water when needed (because of sensitivity of rice to soil drying)
Significance of above for irrigation system managers
• irrigation scheduling for DSR o can we reduce frequency of irrigation during some
crop stages & further reduce irrigation input without reducing yield?
o how is this affected by soil type, climate, varietal duration etc?
o develop farmer friendly techniques for AWD Field water tube (shallow water table) Tensiometer (deep water table)
• does adoption of zero tillage & mulching in a rice-upland cropping system increase total system yield, WPi & WP of depleted water?
• what are the real water savings at higher spatial scales (irrigation schemes, catchments, river basins)?
Research needs for AWD & DSR
Acknowledgement
• Gurjeet Gill, The University of Adelaide, Australia
• Liz Humphreys, International Rice Research Institute, Philippines
• Tao Li, International Rice Research Institute, Philippines
• S.S.Kukal, Punjab Agricultural University, India
Thank You !