Chapter 6 -two types: clastic and chemical: a. clastic: sandstone, shale, etc b. chemical:...
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Transcript of Chapter 6 -two types: clastic and chemical: a. clastic: sandstone, shale, etc b. chemical:...
Chapter 6
-two types: clastic and chemical: a. clastic: sandstone, shale, etc b. chemical: limestone, dolomite, evaporites-distinguish by: grain size, sorting, rounding, sedimentary structures-sedimentary rocks contain fossils- telling relative age of rocks-occur in many environments: terrestrial, transitional, marine
-Fluvial (streams): braided, meandering-Deltas: 3 types: bird foot, tidal, wave dominated-Deep marine: oozes, clays, turbidites
-Paleogeography: employ all these tools to determine what environment was like when these sediments were deposited
Sedimentary Rocks—The Archives of Earth History
• How do we know whether sedimentary rocks were deposited on – continents—river floodplains or desert sand dunes?– at the water's edge?– in the sea?
• Sedimentary rocks– preserve evidence of surface depositional processes– also, many contain fossils– These things give clues to the depositional
environment• Depositional environments are specific areas
– or environments where sediment is deposited
History from Sedimentary Rocks
• Observation and data gathering– visit rock exposures (outcrops)– carefully examine
• textures• composition• fossils (if present)• thickness• relationships to other rocks
• Preliminary interpretations in the field– For example:
• red rocks may have been deposited on land• whereas greenish rocks are more typical of marine
deposits• (caution: exceptions are numerous)
Investigating Sedimentary Rocks
• More careful study of the rocks– microscopic examination– chemical analyses– fossil identification– interpretation of vertical and lateral facies relationships– compare with present-day sediments
• Make environmental interpretation• Derived from weathering of existing Igneous,
Metamorphic or Sedimentary rocks• 2 types of Sedimentary rocks: detrital and chemical
Investigating Sedimentary Rocks
• Detrital= particles eroded from existing rocks
• Very common minerals in detrital rocks:– quartz, feldspars, and clay minerals
• Only calcite is very common in limestones• Detrital rock composition tells
– about source rocks, – not transport and deposition
• Quartz sand may have been deposited– in a river system– on a beach or– in sand dunes
1. Composition of Detrital Rocks
• Chemical= precipitate from seawater; or in swamps• Composition of chemical sedimentary rocks
– is more useful in revealing environmental information
• Limestone is deposited in warm, shallow seas– although a small amount also originates in lakes
• Evaporites such as rock salt and rock gypsum – indicate arid environments
– where evaporation rates were high
• Coal originates in swamps and bogs on land
2. Composition of Chemical Sedimentary Rocks
• Detrital grain size gives some indication – of the energy conditions – during transport and deposition
• High-energy processes – such as swift-flowing streams and waves – are needed to transport gravel
• Conglomerate must have been deposited – in areas where these processes prevail
• Sand transport also requires vigorous currents• Silt and clay are transported
– by weak currents and accumulate – only under low-energy conditions – as in lakes and lagoons
Grain Size
• Sorting and rounding are two textural features – of detrital sedimentary rocks – that aid in determining depositional processes
• Sorting refers to the variation – in size of particles – making up sediment or sedimentary rocks
• It results from processes – that selectively transport and deposit – sediments of particular sizes
Sorting and Rounding
• If the size range is not very great, – the sediment or rock is well sorted
• If they have a wide range of sizes, – they are poorly sorted
• Wind has a limited ability to transport sediment – so dune sand tends to be well sorted
• Glaciers can carry any sized particles, – because of their transport power, – so glacier deposits are poorly sorted
Sorting
• Rounding is the degree to which – detrital particles have their sharp corners and edges – warn away by abrasion
• Gravel in transport is rounded very quickly – as the particles collide with one another
• Sand becomes rounded – with considerably more transport
Rounding
• A deposit – of well rounded – and well sorted
gravel
Rounding and Sorting
• Angular, poorly sorted gravel
• Sedimentary structures are – features visible at the scale of an outcrop – that formed at the time of deposition or shortly
thereafter – and are manifestations of the physical and
biological processes – that operated in depositional environments
• Structures – seen in present-day environments – or produced in experiments – help provide information – about depositional environments of rocks – with similar structures
Sedimentary Structures
• Sedimentary rocks generally have bedding or stratification
Bedding
– Individual layers less than 1 cm thick are laminations
• common in mudrocks
– Beds are thicker than 1 cm
• common in rocks with coarser grains
• Some beds show an upward gradual decrease – in grain size, known as graded bedding
Graded Bedding
• Graded bedding is common in turbidity current deposits– which form when
sediment-water mixtures flow along the seafloor
– As they slow, – the largest
particles settle out – then smaller ones
• Cross-bedding forms when layers come to rest – at an angle to the surface – upon which they accumulate– as on the downwind side of a sand dune
• Cross-beds result from transport – by either water or wind: scale differences
• The beds are inclined or dip downward – in the direction of the prevailing current
• They indicate ancient current directions, – or paleocurrents
• They are useful for relative dating – of deformed sedimentary rocks
Cross-Bedding
• Tabular cross-bedding forms by deposition on sand waves
Cross-Bedding
• Tabular cross-bedding in the Upper
Cretaceous Two Medicine Formation
in Montana
A few cm’s
Cross-Bedding
• Trough cross-bedding formed by migrating dunes
• Trough cross-beds in the Pliocene Six
Mile Creek Formation, Montana
10’s to 100’s cm
• Small-scale alternating ridges and troughs – known as ripple marks are common – on bedding planes, especially in sandstone
• Current ripple marks – form in response to water or wind currents – flowing in one direction– and have asymmetric profiles allowing geologists – to determine paleocurrent directions
• Wave-formed ripple marks – result from the to-and-fro motion of waves– tend to be symmetrical
• Useful for relative dating of deformed sedimentary rocks
Ripple Marks
• Ripples with an asymmetrical shape
• In the close-up of one ripple, – the internal structure – shows small-scale
cross-bedding• The photo shows
current ripples – that formed in a
small stream channel – with flow from right
to left
Current Ripple Marks
• As the waves wash back and forth, – symmetrical
ripples form
• The photo shows wave-formed ripple marks – in shallow
seawater
Wave-Formed Ripples
• When clay-rich sediments dry, they shrink – and crack into polygonal patterns – bounded by fractures called mud cracks
• Mud cracks require wetting and drying to form,
Mud Cracks
– as along a lakeshore
– or a river flood plain
– or where mud is exposed at low tide along a seashore
• Mud cracks in ancient rocks – in Glacier
National Park, Montana
• Mud cracks typically fill in– with sediment – when they are
preserved– as seen here
Ancient Mud Cracks
• Biogenic sedimentary structures include– tracks– burrows– trails
• called trace fossils• Extensive burrowing by organisms
– is called bioturbation
• It may alter sediments so thoroughly – that other structures are disrupted or destroyed
Biogenic Sedimentary Structures
• U-shaped burrows
Bioturbation
• Vertical burrows
Bioturbation
• Vertical, dark-colored areas in this rock are sediment-filled burrows– Could you use burrows such as these to relatively
date layers in deformed sedimentary rocks?
• Sedimentary structures are important – in environmental analyses– but no single structure is unique to a specific
environment• Example:
– Current ripples are found• in stream channels• in tidal channels• on the sea floor
• Environmental determinations – are usually successful with– associations of a groups of sedimentary structures– taken along with other sedimentary rock properties
No Single Structure Is Unique
• The three-dimensional shape or geometry – of a sedimentary rock body – may be helpful in environmental analyses– but it must be used with caution – because the same geometry may be found – in more than one environment– can be modified by sediment compaction – during lithification – and by erosion and deformation
• Nevertheless, it is useful in conjunction – with other features
Geometry of Sedimentary Rocks
• Some of the most extensive sedimentary rocks – in the geologic record result from – marine transgressions and regressions
• The rocks commonly cover – hundreds or thousands of square kilometers – but are perhaps only – a few tens to hundreds of meters thick
• Their thickness is small compared – to their length and width
• Thus, they are said to have – blanket or sheet geometry
Blanket or Sheet Geometry
• Some sand deposits have an elongate or shoestring geometry– especially those deposited in
• stream channels • or barrier islands
Elongate or Shoestring Geometry
• Delta deposits tend to be lens shaped – when viewed in cross profile or long profile– but lobate when observed from above
• Buried reefs are irregular – but many are long and narrow – or rather circular
Other Geometries
• Fossils– are the remains or traces of prehistoric organisms– can be used in stratigraphy for relative dating and
correlation– are constituents of rocks, sometimes making up the
entire rock– and provide evidence of depositional environments
• Many limestones are composed – in part or entirely of shells or shell fragments
• Much of the sediment on the deep-seafloor – consists of microscopic shells of organisms
Fossils—The Biological Content of Sedimentary Rocks
• This variety of limestone, – known as
coquina, – is made entirely
of shell fragments
Fossils Are Constituents of Sedimentary Rocks
• Did the organisms in question live where they were buried?
• Or where their remains or fossils transported there?
• Example:– Fossil dinosaurs usually indicate deposition – in a land environment such as a river floodplain– But if their bones are found in rocks with – clams, corals and sea lilies, – we assume a carcass was washed out to sea
Fossils in Environmental Analyses
• What kind of habitat did the organisms originally occupy?
• Studies of a fossil’s structure – and its living relatives, if any, – help environmental analysis
• For example: clams with heavy, thick shells – typically live in shallow turbulent water– whereas those with thin shells – are found in low-energy environments
• Most corals live in warm, clear, – shallow marine environments where – symbiotic bacteria can carry out photosynthesis
Environmental Analyses
• A depositional environment – is anywhere sediment accumulates– especially a particular area – where a distinctive kind of deposit originates – from physical, chemical, and biological processes
• Three broad areas of deposition include– Continental/terrestrial – Transitional– Marine– each of which has several specific environments
Depositional Environments
Depositional EnvironmentsContinental environments
Transitional environments
Marine environments
• Deposition on continents (on land) might take place in – fluvial systems – rivers and streams– deserts– areas covered by and adjacent to glaciers
• Deposits in each of these environments – possess combinations of features – that allow us to differentiate among them
Continental Environments
• Fluvial refers to river and stream activity – and to their deposits
• Fluvial deposits accumulate in either of two types of systems
• One is a braided stream system– with multiple broad, shallow channels – in which mostly sheets of gravel – and cross-bedded sand are deposited– mud is nearly absent
Fluvial
• The deposits of braided streams are mostly – gravel and cross-bedded sand with subordinate mud
Braided Stream
• The other type of system is a meandering stream– with winding channels– mostly fine-grained sediments on floodplains– cross-bedded sand bodies with shoestring
geometry– point-bar deposits consisting of a sand body – overlying an erosion surface – that developed on the convex side of a meander
loop
Fluvial Systems
• Meandering stream deposits
Meandering Stream
– are mostly fine-grained floodplain – sediments with subordinate sand bodies
• Desert environments contain an association of features found in – sand dune deposits, – alluvial fan deposits,– and playa lake deposits
• Windblown dunes are typically composed – of well-sorted, well-rounded sand – with cross-beds meters to tens of meters high– land-dwelling plants and animals make up any
fossils
Desert Environments
• A desert basin showing the association – of alluvial fan, – sand dune, – and playa lake deposits
• In the photo, – the light colored area in the
distance– is a playa lake deposit in
Utah
Associations in Desert Basin
• Alluvial fans form best along the margins of desert basins – where streams and debris flows – discharge from mountains onto a valley floor – They form a triangular (fan-shaped) deposit – of sand and gravel
• The more central part of a desert basin – might be the site of a temporary lake, a playa lake, – in which laminated mud and evaporites accumulate
Alluvial Fans and Playa Lakes
• All sediments deposited in – glacial environments are collectively called drift
• Till is poorly sorted, nonstratified drift – deposited directly by glacial ice– mostly in ridge-like deposits called moraines
• Outwash is sand and gravel deposited – by braided streams issuing from melting glaciers
• The association of these deposits along with – scratched (striated) and polished bedrock – is generally sufficient to conclude – that glaciers were involved
Glacial Environments
• Moraines and poorly sorted till
Moraines and Till
• Origin of glacial drift
• Glacial lake deposits show – alternating dark and light laminations
• Each dark-light couplet is a varve, – representing one year’s accumulation of sediment– light layers accumulate in summer– dark in winter
Glacial Varves
• Dropstones – liberated from
icebergs – may also be
present– Varves with a
dropstone
• Transitional environments include those – with both marine and continental processes
• Example:– Deposition where a river or stream (fluvial system) – enters the sea – yields a body of sediment called a delta – with deposits modified by marine processes,
especially waves and tides• Transitional environments include
– deltas– beaches– barrier islands and lagoons– tidal flats
Transitional Environments
Transitional Environments
Transitional environments
• Marine deltas rarely conform precisely – to this simple threefold division because – they are strongly influenced – by one or more modifying processes
• When fluvial processes prevail – a stream/river-dominated delta results
• Strong wave action – produces a wave dominated delta
• Tidal influences – result in tide-dominated deltas
Marine Deltas
• Stream/river-dominated deltas – have long
distributary channels
– extending far seaward
– Mississippi River delta
Stream/River-Dominated Deltas
• Wave-dominated deltas – such as the Nile
Delta of Egypt– also have
distributary channels
– but their seaward margin
– is modified by wave action
Wave-Dominated Deltas
• Tide-Dominated Deltas, – such as the Ganges-Brahmaputra delta
Tide-Dominated Deltas
– of Ban-gladesh
– have tidal sand bodies
– along the direction of tidal flow
• On broad continental margins – with abundant sand, long barrier islands lie offshore – separated from the mainland by a lagoon
• Barrier islands are common along the Gulf – and Atlantic Coasts of the United States
• Many ancient deposits formed in this environment
• Subenvironments of a barrier island complex: – beach sand grading offshore into finer deposits– dune sands contain shell fragments
• not found in desert dunes– fine-grained lagoon deposits – with marine fossils and bioturbation
Barrier Islands
• Subenvironments of a barrier island complex
Barrier Island Complex
• Tidal flats are present – where part of the shoreline is periodically covered – by seawater at high tide and then exposed at low tide
• Many tidal flats build or prograde seaward – and yield a sequence of rocks grading upward – from sand to mud
• One of their most distinctive features – is sets of cross-beds that dip in opposite directions
Tidal Flats
• Marine environments include:– continental shelf– continental slope– continental rise– deep-seafloor
• Much of the detritus eroded from continents – is eventually deposited in marine environments
• but sediments derived from chemical – and organic activity are found here as well, such as
• limestone• evaporites• both deposited in shallow marine environments
Marine Environments
Marine Environments
Marine environments
Sea Floor Topography
Sea Level
Mid Ocean ridge
Continental Margin
Continental Shelf
Continental Slope
Oceanic trench Abyssal Plain
Continental Margin
Continental ShelfContinental Slope
Continental Rise
• Shelf, slope and rise environments• The main avenues of sediment transport
– across the shelf are submarine canyons
Detrital Marine Environments
Turbidity currents carry sediment to the submarine fans
Sand with graded bedding and mud settled from seawater
• Beyond the continental rise, the seafloor is– nearly completely covered by fine-grained deposits
• no sand and gravel
– or no sediment at all • near mid-ocean ridges
• The main sources of sediment are:– windblown dust from continents or oceanic islands– volcanic ash– shells of microorganisms dwelling in surface
waters of the ocean
Deep Sea
• Types of sediment are:– pelagic clay,
• which covers most of the deeper parts
• of the seafloor
– calcareous (CaCO3) and siliceous (SiO2) oozes
• made up of microscopic shells
Deep Sea
• Carbonate rocks are – limestone, which is composed of calcite– dolostone, which is composed of dolomite
• most dolostone is altered limestone• Limestone is similar to detrital rock in some
ways– Many limestones are made up of
• gravel-sized grains • sand-sized grains• microcrystalline carbonate mud called micrite
– but the grains are all calcite – and are formed in the environment of deposition, – not transported there
Carbonate Environments
• Some limestone form in lakes, – but most limestone by is deposited – in warm shallow seas– on carbonate shelves and– on carbonate platforms rising from oceanic depths
• Deposition occurs where – little detrital sediment, especially mud, is present
• Carbonate barriers form in high-energy areas and may be – reefs – banks of skeletal particles – accumulations of spherical carbonate grains known
as oolites • which make up the grains in oolitic limestone
Limestone Environments
• Evaporites consist of – rock salt– rock gypsum
• They are found in environments such as– playa lakes– saline lakes– but most of the extensive deposits formed in the
ocean
• Evaporites are not nearly as common – as sandstone, mudrocks and limestone, – but can be abundant locally
Evaporite Environments
• Large evaporite deposits– lie beneath the Mediterranean Seafloor
• more than 2 km thick – in western Canada, Michigan, Ohio, New York, – and several Gulf Coast states
• How some of these deposits originated – is controversial, but geologists agree – that high evaporation rates of seawater – caused minerals to precipitate from solution
• Coastal environments in arid regions – such as the present-day Persian Gulf – meet the requirements
Evaporites
• Present-day gravel deposits – by a swiftly-flowing stream– Most transport and
deposition takes place when the stream is higher
Environmental Interpretations and Historical Geology
• Nearby gravel deposit probably less than a few thousand years old
• Conglomerate more than 1 billion years old – shows similar
features
Environmental Interpretations and Historical Geology
• We infer that it too was deposited – by a braided stream in a fluvial system– Why not deposition by glaciers or along a seashore?– Because evidence is lacking for either – glacial activity or transitional environment
• Jurassic-aged Navajo Sandstone – of the Southwestern United states – has all the features of wind-blown sand dunes:
• the sandstone is mostly well-sorted, well-rounded quartz • measuring 0.2 to 0.5 mm in diameter• tracks of land-dwelling animals, • including dinosaurs, are present• cross-beds up to 30 m high have current ripple marks • like those produced on large dunes by wind today• cross-beds dip generally southwest • indicating a northeast prevailing wind
Interpretation
– Vertical fractures
– intersect cross beds of desert dunes
– making the checker-board pattern
– 100’s m thick
Navajo Sandstone
Checkerboard Mesa, Zion National Park, Utah
• Paleogeography deals with – Earth’s geography of the past
• Using interpretations – of depositional environment – such as the ones just discussed
• we can attempt to reconstruct – what Earth’s geography was like – at these locations at various times in the past
• For example, – the Navajo Sandstone shows that a vast desert – was present in what is now the southwest – during the Jurassic Period
Paleogeography
• Detailed studies of various rocks – in several western states – allow us to determine – with some accuracy – how the area appeared – during the Late Cretaceous
• A broad coastal plain – sloped gently eastward – from a mountainous region – to the sea
Paleogeography
• Later, vast lakes, – river floodplains, alluvial fans – covered much of this area – and the sea had withdrawn
from the continent
• Interpretations the geologic record – we examine later– will be based on similar – amounts of supporting
evidence
Paleogeography
Summary• The physical and biological features
– of sedimentary rocks reveal something about – the depositional processes that form them
• Environmental analysis – of sedimentary rocks uses – mainly sedimentary structures and fossils – but also textures, rock body geometry– and even composition
• Geologists recognize – three primary depositional areas– continental, transitional, and marine– each with several specific environments
Summary
• Fluvial systems might be braided or meandering – Braided streams deposit mostly sand and
gravel, – whereas deposits of meandering streams are
mostly mud and subordinate sand bodies with shoestring geometry
• An association of alluvial fan, sand dune, – and playa lake deposits – is typical of desert depositional environments
• Glacial deposits consist mostly of till – in moraines and outwash
Summary• The simplest deltas, those in lakes,
– consist of a three-part sequence of rocks – grading from finest at the base, – upward to coarser-grained rocks
• Marine deltas dominated by – fluvial processes, waves, or tides – are much larger and more complex
• A barrier island system includes beach, – dune, and lagoon subenvironments, – each characterized a unique association – of rocks, sedimentary structures, and fossils
Summary
• Inner shelf deposits are mostly sand, – whereas those of the outer shelf are mostly mud; – both have marine fossils and bioturbation
• Much of the sediment from land – crosses the shelves and is deposited – on the continental slope and rise as submarine fans
• Either pelagic clay or oozes – derived from the shells of– microscopic floating organisms cover – most of the deep seafloor
Summary• Most limestone originates in shallow,
– warm seas where little detrital mud is present
• Carbonate rocks (just as detrital rocks) – may possess cross-beds, ripple marks, – mud cracks, and fossils – that provide information – about depositional processes
• Evaporites form in several environments, – but the most extensive ones were deposited– in marine environments
• In all cases, though, they formed – in arid regions with high evaporation rates
Summary• With information from sedimentary rocks,
– as well as other rocks, – geologists determine the past distribution – of Earth's surface features– Determine the environment of deposition of a particular package of rocks- If fossils are present, make some relative age determination based upon the fossil content
• For instance, phosphorous – from phosphorous-rich sedimentary rocks – is used in
• metallurgy
• preserved foods
• ceramics
• matches
• chemical fertilizers
• animal-feed supplements
Phosphorous
• Sand deposition – on a beach along the
Pacific coast – of the United States
• Many ancient sandstones – possess features – that indicate they were – also deposited on beaches
Beach Environment
• Sedimentary rocks may be– detrital– or chemical, including biochemical– and all preserve evidence – of the physical, chemical and biological processes – that formed them
• Some sedimentary rocks are or contain resources– phosphorous– liquid petroleum– natural gas
Sedimentary rocks
• Once sediment passes the outer margin – of the self, the shelf-slope break, – turbidity currents transport it
• So sand with graded bedding is common
• Also common is mud that settled from seawater
Slope and Rise
Simple Deltas
– topset beds– foreset beds– bottomset
beds
• The simplest deltas are those in lakes and consist of
– As the delta builds outward it progrades
– and forms a vertical sequence of rocks – that becomes coarser-grained from the bottom to top– The bottomset beds may contain marine (or lake) fossils, – whereas the topset beds contain land fossils
• Reef rock tends to be – structureless– composed of skeletons of corals, mollusks, sponges
and other organisms• Carbonate banks are made up of
– layers with horizontal beds– cross-beds– wave-formed ripple marks
• Lagoons tend to have– micrite– with marine fossils – bioturbation
Carbonate Subenvironments
• Microfossils are particularly useful – because many individuals can be recovered – from small rock samples
• In oil-drilling operations, small rock chips – called well cuttings are brought to the surface
• These cuttings rarely – contain complete fossils of large organisms, – but they might have thousands of microfossils– that aid in relative dating and environmental
analyses
Microfossils
• Trace fossils, too, may be characteristic of particular environments
• Trace fossils, of course, are not transported from their original place of origin
Trace Fossils In Place
• Tidal-flat deposits showing a prograding shoreline– Notice the distinctive cross-beds – that dip in opposite directions – How could this happen?
Tidal Flats
• The carbonate shelf is attached to a continent– Examples
occur in southern Florida and the Persian Gulf
Carbonate Shelf
• Carbonates may be deposited on a platform – rising from oceanic depths
• This example shows a cross-section – of the present-day Great Bahama Bank – in the Atlantic Ocean southeast of Florida
Carbonate Platform
– with restricted inflow of normal seawater – into the lagoon– leading to increased salinity and salt depositions
Evaporites
• Evaporites could form
• in an environment similar to this
• if the area were in an arid region,
• Braided stream deposits consist of – conglomerate– cross-bedded
sandstone– but mudstone is rare
or absent
Braided Stream Deposits
• In meandering stream deposits,– mudstone deposited in a
floodplain is common– sandstones are point bar
deposits– channel conglomerate is
minor
Meandering Stream Deposits
– and from Late Precambrian to Middle Cambrian
– the shoreline migrated inland from east and west
– during a marine transgression
Paleogeography
• The gently sloping area adjacent to a continent – is a continental shelf
• It consists of a high-energy inner part that is – periodically stirred up by waves and tidal currents
• Its sediment is mostly sand, – shaped into large cross-bedded dunes
• Bedding planes are commonly marked – by wave-formed ripple marks
• Marine fossils and bioturbation are typical
Detrital Marine Environments
• The low-energy part of the shelf – has mostly mud with marine fossils, – and interfingers with inner-shelf sand
• Much sediment derived from the continents – crosses the continental shelf – and is funneled into deeper water – through submarine canyons
• It eventually comes to rest – on the continental slope and continental rise – as a series of overlapping submarine fans
Slope and Rise
• Large-scale cross-beds – in a Permian-aged – wind-blown dune
deposit in Arizona
Dune Cross-Beds