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Some basic remarks on the Concept
of Facies, Facies association and
sedimentary processes
An useful method to analyse sedimentary bodies is the FACIES ANALYSIS.
This approach allows us to describe and interpret sedimentary bodies occurring in outcrop or in the Earth subsurface.
A SEDIMENTARY FACIES is the ensemble of physical features of a sedimentary accumulation, including lithology, grain size,
structures, fossil content etc. and that can be used in order to distinguish it from adjacent different deposits.
A SEDIMENTARY FACIES can be recognise through three main phases of investigation:
1) Observation of the physical features;
2) Documentation by using standards;
3) Interpretation as processes.
F A C I E S A N A L Y S I S
2
observation description interpretation
A SEDIMENTARY FACIES is the ensemble of physical features of a sedimentary accumulation, including lithology, grain size, structures, fossil
content etc. and that can be used in order to distinguish it from adjacent different deposits. Each SEDIMENTARY FACIES can be subdivided into
minor components (sub-facies) or adjacent facies can be grouped into a FACIES ASSOCIATION.
3
R2
R1
R3
FACIES ASSOCIATION
Association 1
Association 2
Association 3
FACIES
Facies A
Facies B
Facies C
sub-FACIES
Sub-Facies
A1
Sub-Facies
A2
Sub-Facies
A3
• Nonstratified (massive), planar parallel-stratified, trough
cross-stratified, planar cross-stratified and ripple cross-lamin.
sandstone facies
• Massive, cross-stratified and planar parallel-stratified gravel
facies
• Turbidite bed classes based on Bouma divisions, such as
Tabcde, Tacde, Tbcde, Tbde, Tcde, Tde, etc.
HIGH (with facies as the
record of depositional
processes)
Sedimentological study of
a basin-fill succession or
its selected part
• Braided vs. meandering river facies
• Channel-fill vs. overbank alluvial facies
• Prodelta, delta toe, delta slope, delta front and delta top facies
• Foreshore, upper shoreface, lower shoreface, offshore
tranistion and offshore facies
• Tidal sandflat, mixed flat, mudflat and channel/creek facies
• Subtidal, intertidal and supratidal facies
• Upper, middle and lower submarine fan facies; or channel-fill
vs. overbank turbidites
MODERATE (with facies as
the record of depositional
subenvironments or narrowly-
defined specific
environments)
Basin-scale
palaeogeographic study
and sequence stratigraphy
• Alluvial, aeolian, shoreline/deltaic, nearshore, offshore facies
• Barrier/lagoon and estuarine facies
• Patch reef and carbonate platform facies
• Submarine fan/apron and abyssal plain facies
LOW (with facies as the
record of broadly-defined
depositional environments)
Broad, regional-scale
palaeogeographic study
• Terrestrial vs. marine facies
• Shallow-marine vs. deep-marine facies
• Carbonate vs. siliciclastic facies
• Evaporitic vs. carbonate facies
VERY LOW (with facies as
the record of whole classes of
depositional environmets)
Very broad, inter-regional
or ’global-scale’
palaeogeographic study
EXAMPLE DEPOSIT TYPESRESOLUTION LEVELSCOPE OF STUDY
The concept of sedimentary facies
The notion of facies used by researcher depends on the scope of a particular study.
The Walther Law
The palaeoenvironments (facies assemblages) that we find stacked vertically upon one another in a stratigraphic succession ...
… did originally occur laterally to one another and were superimposed by the lateral shifting of environment zones.
The concept of lithostratigraphic logging
and the interest in vertical facies organization stem
from the Walther Law.
Systems tract in sequence-stratigraphic sense
Systems tract in palaeogeographical sense
STRATIGRAPHIC ELEMENTS SEDIMENTOLOGICAL ANALYSIS INFORMATION DERIVED
SEDIMENTARY FACIES are the basic types of
sedimentary deposits, distinguished macroscopically on
a descriptive basis as the elementary “building blocks”
of a sedimentary succession.
The sedimentary succession is logged by being divided into more-
or-less uniform “units”, or beds, on the basis of:
sediment texture (grain characteristics)
sediment structures (grain organization characteristics)
colour and biogenic features (if present)
geometry (thickness, lateral extent, shape, boundary types).
Units with similar characteristics are classified as one facies. Each
facies is separately described and interpreted.
The principal processes of sediment transport
and deposition are recognized.
Some processes may be directly diagnostic of a
particular sedimentary environment and others
may not, but as a group – or association – they
invariably are (see the next step of analysis).
FACIES ASSOCIATIONS are assemblages of spatially
and genetically related facies, distinguished as the
basic “building megablocks” of the sedimentary
succession.
The succession of facies is reviewed to recognize their natural
stratigraphic grouping into genetically coherent assemblages:
facies associations. These are interpreted, on the basis of their
depositional processes, as the record of particular sedimentary
environments. The environments are then arranged into a spectrum
from “proximal” to “distal”, or from shallower to deeper water. On
this basis, a conceptual model of the environments as a “systems
tract” is developed. A geographical systems tract is a spatial array
of coeval sedimentary environments through which the net transfer
of sediment occurs from land to the sea. The term is used also for
the sedimentary record of such an array of environments and their
behaviour (see below). A systems tract can be “short” or “long”,
depending on the number and range of systems (environments)
involved.
The sedimentary environments, or depositional
“systems”, are identified and their spatial
organization as a geographical “systems tract” is
recognized.
sea level
geographical systems tract (ST)
This part of facies analysis requires that the
researcher has a good “facies atlas” of natural
environments in mind and understands well their
possible variation and spatial relationships.
SYSTEMS TRACT = a succession of facies
associations recording particular types of shoreline
behaviour in a geographical systems tract. The basic
types are lowstand and highstand normal-regressive
STs and forced-regressive and transgressive STs.
SEQUENCE = a succession of systems tracts recording
one complete R-T cycle of relative sea-level change,
from one maximum regression phase to the maximum
flooding phase and to another maximum regression
phase; alternatively, sequences can be distinguished
as T-R cycles, with the maximum flooding phases
(surfaces) as boundaries.
Based on the identified spectrum and stratigraphic order of facies
associations (palaeoenvironments), the principal types of systems
tracts are recognized within the sedimentary succession. The
stratigraphic organization of these tracts is then used to distinguish
“sequences”, or transgressive-regressive cycles of relative sea-level
change (combined with possible changes in sediment supply).
The term parasequence denotes the record of a relative sea-level rise
followed by a “normal” (progradational) regression and another sea-level
rise, without an intervening relative fall, in which case a transgressive
systems tract (TST), possibly negligibly thin, culminates in the maximum
flooding phase (surface) and is followed by a regressive systems tract
(RST), which in turn is terminated by a new marine transgression.
The term sequence denotes the record of a cycle of relative sea-level fall
and rise, in which case the relative fall (“forced” regression) is represented
by an erosional unconformity surface with coeval distal deposits (FRST) and
a subsequent aggradational/progradationl lowstand systems tract (LST),
jointly a form of RST, overlain by a transgressive systems tract (TST) that
culminates in the maximum flooding phase and is followed by a
progradational (normal-regressive) highstand systems tract (HST).
The stratigraphic pattern of relative sea-level
changes (combined with changes in sediment
supply) is recognized. A hierarchy of lower-order
(longer-term) and higher-order (shorter-term)
cycles of such changes can be distinguished.
parasequence
sequence
Proximal Medial Distal
T
Distal
Medial
Proxim.
R
Facies analysis scheme
SFR
FS
MFS
MFS
FS
sedimentary processes
1) SELECTIVE PROCESSES (Tractive)
Selective processes generate both a transport (TRACTIONAL TRANSPORT) but also a modelling of the
sediment, producing structures (TRACTIONAL STRUCTURES).
(Ex.: marine currents; waves; river floods).
2) MASS PROCESSES
Mass processes produce a ‘mass transport’ of large amount (masses) of sediment, both in subaerial and
subaqueous settings.
(Ex.: landslides; mudflows, etc.).
2.1) Gravitative Processes
The gravitative processes represent a type of mass process, which occur mostly under the effect of the gravity force.
(Ex.: debris flow, grain flow, mud flow; turbidity flow).
2.2) NON Gravitative Processes
The gravitative processes represent a type of mass process, whose energy exceeds that of the gravity force, in case of
excpetional events.
(Ex.: river catastrophic floods; cyclones, hurricanes, typhoons; volcanic surges).
Structures deriving from
TRACTIONAL PROCESSES
ORGANISED ASSECT CAHOTIC or UNGORGANISED ASSET
Structures deriving from MASS
PROCESSES
THERE ARE FOUR MAIN TYPES OF MASS (GRAVITATIVE) PROCESSES:
Mud Flow
Grain Flow
Debris Flow
Turbidity Flow
Mud Flow
Mass Gravitative Process :
1) Mud Flow
Sedimentology Lecture 4. concept of sedimentary facies, association and processes
Mass Gravitative Process :
1) Mud Flow
SUBAERIAL FLOW
SUBAQUEOUS FLOW
air: traction negligible
water: traction negligible
turbiditic
plume
erosion
Grain Flow
Mass Gravitative Process :
1) Grain Flow
Mass Gravitative Process :
1) Grain Flow
Selective processes shaping a mud/mudrock unit
Semi-quantitative
scale is used
Selective processes shaping a sand/sandstone unit
Ripple cross-lamination
LARGE-SCALE PLANAR/TROUGH
CROSS-STRATIFICATION
SMALL-SCALE PLANAR/TROUGH
CROSS-STRATIFICATION
Selective processes shaping a gravel/gravelstone unit

More Related Content

Sedimentology Lecture 4. concept of sedimentary facies, association and processes

  • 1. Some basic remarks on the Concept of Facies, Facies association and sedimentary processes
  • 2. An useful method to analyse sedimentary bodies is the FACIES ANALYSIS. This approach allows us to describe and interpret sedimentary bodies occurring in outcrop or in the Earth subsurface. A SEDIMENTARY FACIES is the ensemble of physical features of a sedimentary accumulation, including lithology, grain size, structures, fossil content etc. and that can be used in order to distinguish it from adjacent different deposits. A SEDIMENTARY FACIES can be recognise through three main phases of investigation: 1) Observation of the physical features; 2) Documentation by using standards; 3) Interpretation as processes. F A C I E S A N A L Y S I S 2 observation description interpretation
  • 3. A SEDIMENTARY FACIES is the ensemble of physical features of a sedimentary accumulation, including lithology, grain size, structures, fossil content etc. and that can be used in order to distinguish it from adjacent different deposits. Each SEDIMENTARY FACIES can be subdivided into minor components (sub-facies) or adjacent facies can be grouped into a FACIES ASSOCIATION. 3 R2 R1 R3 FACIES ASSOCIATION Association 1 Association 2 Association 3 FACIES Facies A Facies B Facies C sub-FACIES Sub-Facies A1 Sub-Facies A2 Sub-Facies A3
  • 4. • Nonstratified (massive), planar parallel-stratified, trough cross-stratified, planar cross-stratified and ripple cross-lamin. sandstone facies • Massive, cross-stratified and planar parallel-stratified gravel facies • Turbidite bed classes based on Bouma divisions, such as Tabcde, Tacde, Tbcde, Tbde, Tcde, Tde, etc. HIGH (with facies as the record of depositional processes) Sedimentological study of a basin-fill succession or its selected part • Braided vs. meandering river facies • Channel-fill vs. overbank alluvial facies • Prodelta, delta toe, delta slope, delta front and delta top facies • Foreshore, upper shoreface, lower shoreface, offshore tranistion and offshore facies • Tidal sandflat, mixed flat, mudflat and channel/creek facies • Subtidal, intertidal and supratidal facies • Upper, middle and lower submarine fan facies; or channel-fill vs. overbank turbidites MODERATE (with facies as the record of depositional subenvironments or narrowly- defined specific environments) Basin-scale palaeogeographic study and sequence stratigraphy • Alluvial, aeolian, shoreline/deltaic, nearshore, offshore facies • Barrier/lagoon and estuarine facies • Patch reef and carbonate platform facies • Submarine fan/apron and abyssal plain facies LOW (with facies as the record of broadly-defined depositional environments) Broad, regional-scale palaeogeographic study • Terrestrial vs. marine facies • Shallow-marine vs. deep-marine facies • Carbonate vs. siliciclastic facies • Evaporitic vs. carbonate facies VERY LOW (with facies as the record of whole classes of depositional environmets) Very broad, inter-regional or ’global-scale’ palaeogeographic study EXAMPLE DEPOSIT TYPESRESOLUTION LEVELSCOPE OF STUDY The concept of sedimentary facies The notion of facies used by researcher depends on the scope of a particular study.
  • 5. The Walther Law The palaeoenvironments (facies assemblages) that we find stacked vertically upon one another in a stratigraphic succession ... … did originally occur laterally to one another and were superimposed by the lateral shifting of environment zones. The concept of lithostratigraphic logging and the interest in vertical facies organization stem from the Walther Law. Systems tract in sequence-stratigraphic sense Systems tract in palaeogeographical sense
  • 6. STRATIGRAPHIC ELEMENTS SEDIMENTOLOGICAL ANALYSIS INFORMATION DERIVED SEDIMENTARY FACIES are the basic types of sedimentary deposits, distinguished macroscopically on a descriptive basis as the elementary “building blocks” of a sedimentary succession. The sedimentary succession is logged by being divided into more- or-less uniform “units”, or beds, on the basis of: sediment texture (grain characteristics) sediment structures (grain organization characteristics) colour and biogenic features (if present) geometry (thickness, lateral extent, shape, boundary types). Units with similar characteristics are classified as one facies. Each facies is separately described and interpreted. The principal processes of sediment transport and deposition are recognized. Some processes may be directly diagnostic of a particular sedimentary environment and others may not, but as a group – or association – they invariably are (see the next step of analysis). FACIES ASSOCIATIONS are assemblages of spatially and genetically related facies, distinguished as the basic “building megablocks” of the sedimentary succession. The succession of facies is reviewed to recognize their natural stratigraphic grouping into genetically coherent assemblages: facies associations. These are interpreted, on the basis of their depositional processes, as the record of particular sedimentary environments. The environments are then arranged into a spectrum from “proximal” to “distal”, or from shallower to deeper water. On this basis, a conceptual model of the environments as a “systems tract” is developed. A geographical systems tract is a spatial array of coeval sedimentary environments through which the net transfer of sediment occurs from land to the sea. The term is used also for the sedimentary record of such an array of environments and their behaviour (see below). A systems tract can be “short” or “long”, depending on the number and range of systems (environments) involved. The sedimentary environments, or depositional “systems”, are identified and their spatial organization as a geographical “systems tract” is recognized. sea level geographical systems tract (ST) This part of facies analysis requires that the researcher has a good “facies atlas” of natural environments in mind and understands well their possible variation and spatial relationships. SYSTEMS TRACT = a succession of facies associations recording particular types of shoreline behaviour in a geographical systems tract. The basic types are lowstand and highstand normal-regressive STs and forced-regressive and transgressive STs. SEQUENCE = a succession of systems tracts recording one complete R-T cycle of relative sea-level change, from one maximum regression phase to the maximum flooding phase and to another maximum regression phase; alternatively, sequences can be distinguished as T-R cycles, with the maximum flooding phases (surfaces) as boundaries. Based on the identified spectrum and stratigraphic order of facies associations (palaeoenvironments), the principal types of systems tracts are recognized within the sedimentary succession. The stratigraphic organization of these tracts is then used to distinguish “sequences”, or transgressive-regressive cycles of relative sea-level change (combined with possible changes in sediment supply). The term parasequence denotes the record of a relative sea-level rise followed by a “normal” (progradational) regression and another sea-level rise, without an intervening relative fall, in which case a transgressive systems tract (TST), possibly negligibly thin, culminates in the maximum flooding phase (surface) and is followed by a regressive systems tract (RST), which in turn is terminated by a new marine transgression. The term sequence denotes the record of a cycle of relative sea-level fall and rise, in which case the relative fall (“forced” regression) is represented by an erosional unconformity surface with coeval distal deposits (FRST) and a subsequent aggradational/progradationl lowstand systems tract (LST), jointly a form of RST, overlain by a transgressive systems tract (TST) that culminates in the maximum flooding phase and is followed by a progradational (normal-regressive) highstand systems tract (HST). The stratigraphic pattern of relative sea-level changes (combined with changes in sediment supply) is recognized. A hierarchy of lower-order (longer-term) and higher-order (shorter-term) cycles of such changes can be distinguished. parasequence sequence Proximal Medial Distal T Distal Medial Proxim. R Facies analysis scheme SFR FS MFS MFS FS
  • 8. 1) SELECTIVE PROCESSES (Tractive) Selective processes generate both a transport (TRACTIONAL TRANSPORT) but also a modelling of the sediment, producing structures (TRACTIONAL STRUCTURES). (Ex.: marine currents; waves; river floods). 2) MASS PROCESSES Mass processes produce a ‘mass transport’ of large amount (masses) of sediment, both in subaerial and subaqueous settings. (Ex.: landslides; mudflows, etc.). 2.1) Gravitative Processes The gravitative processes represent a type of mass process, which occur mostly under the effect of the gravity force. (Ex.: debris flow, grain flow, mud flow; turbidity flow). 2.2) NON Gravitative Processes The gravitative processes represent a type of mass process, whose energy exceeds that of the gravity force, in case of excpetional events. (Ex.: river catastrophic floods; cyclones, hurricanes, typhoons; volcanic surges).
  • 9. Structures deriving from TRACTIONAL PROCESSES ORGANISED ASSECT CAHOTIC or UNGORGANISED ASSET Structures deriving from MASS PROCESSES
  • 10. THERE ARE FOUR MAIN TYPES OF MASS (GRAVITATIVE) PROCESSES: Mud Flow Grain Flow Debris Flow Turbidity Flow
  • 12. Mass Gravitative Process : 1) Mud Flow
  • 14. Mass Gravitative Process : 1) Mud Flow SUBAERIAL FLOW SUBAQUEOUS FLOW air: traction negligible water: traction negligible turbiditic plume erosion
  • 16. Mass Gravitative Process : 1) Grain Flow
  • 17. Mass Gravitative Process : 1) Grain Flow
  • 18. Selective processes shaping a mud/mudrock unit Semi-quantitative scale is used
  • 19. Selective processes shaping a sand/sandstone unit Ripple cross-lamination LARGE-SCALE PLANAR/TROUGH CROSS-STRATIFICATION SMALL-SCALE PLANAR/TROUGH CROSS-STRATIFICATION
  • 20. Selective processes shaping a gravel/gravelstone unit