Title: The%20Tools%20of%20Subsurface%20Analysis
1The Tools of Subsurface Analysis
2Well Logs
Delimit of surfaces identify sediments
penetrated
- Resistivity Logs
- Spontaneous Potential (SP) Logs
- Gamma Ray Logs
- Neutron Logs
- Density Logs
- Sonic (acoustic) Logs
3Well Logs
Delimit of surfaces identify sediments
penetrated
- Resistivity Logs
- Spontaneous Potential (SP) Logs
- Gamma Ray Logs
- Neutron Logs
- Density Logs
- Sonic (acoustic) Logs
4Well Logs
Delimit of surfaces identify sediments
penetrated
- Resistivity Logs
- Spontaneous Potential (SP) Logs
- Gamma Ray Logs
- Neutron Logs
- Density Logs
- Sonic (acoustic) Logs
5Well Logs
Delimit of surfaces identify sediments
penetrated
- Resistivity Logs
- Spontaneous Potential (SP) Logs
- Gamma Ray Logs
- Neutron Logs
- Density Logs
- Sonic (acoustic) Logs
6Well Logs
Delimit of surfaces identify sediments
penetrated
- Resistivity Logs
- Spontaneous Potential (SP) Logs
- Gamma Ray Logs
- Neutron Logs
- Density Logs
- Sonic (acoustic) Logs
7The Tools of Subsurface Analysis
Facies analysis of subsurface data depends on
tools which delimit of surfaces and provide clues
as to the sediments they contain
- Well logs
- Cores
- Seismic
- Gravity magnetics
8Well Logs Versus Seismic
- Well logs
- Great vertical resolution
- Delimit bounding surfaces
- Establish lithology of sediments penetrated
- Seismic
- Great lateral continuity and resolution
- Define gross sediment geometry
9Tools are Keys to Allostratigraphy Sequence
Stratigraphy
- Allostratigraphy
- bounding discontinuities including erosion
surfaces, marine flooding surfaces, tuffs,
tempestite, and/or turbidite boundaries etc. as
time markers - Sequence Stratigraphy higher level
allostratigraphic model which interprets
depositional origin of sedimentary strata as
products of "relative sea level change"
10The Tools of Subsurface Analysis
Facies analysis of subsurface data depends on
tools which delimit of surfaces and provide clues
as to the sediments they contain
11Well Logs
Delimit of surfaces identify sediments
penetrated
- Resistivity Logs
- Spontaneous Potential (SP) Logs
- Gamma Ray Logs
- Neutron Logs
- Density Logs
- Sonic (acoustic) Logs
12(No Transcript)
13(No Transcript)
14Resistivity Logs
The most commonly used logs
- Measures resistance of flow of electric current
- Is function of porosity pore fluid in rock
- Frequently used to identify lithology
15(No Transcript)
16Spontaneous Potential (SP) Logs
Next most common log
- Measures electrical current in well
- Result of salinity differences between formation
water and the borehole mud - Separates bed boundaries of permeable sands
impermeable shales.
17(No Transcript)
18Gamma Ray Logs
Another common log
- Records radioactivity of a formation
- Shales have high gamma radioactive response
- Gamma ray logs infer grain size (and so
subsequently inferred depositional energy) - Gamma ray logs are most commonly used logs for
sequence stratigraphic analysis
19(No Transcript)
20(No Transcript)
21After Harris Saller 1999
22Neutron Logs
Another common log
- Measures porosity of formation
- Uses quantity of hydrogen present
- Measures lithology when used with Density Log
23Density Logs
A common log
- Measures formations bulk density
- Used as a porosity measure
- Differentiates lithologies with Neutron Log
- Used with Sonic Logs to generate synthetic
seismic traces to match to seismic lines
24Sonic (Acoustic) Logs
Another common log
- Measures of speed of sound in formation
- Tied to porosity and lithology
- Used with Density Logs to generate Synthetic
Seismic traces to match to Seismic lines
25(No Transcript)
26(No Transcript)
27The Tools of Subsurface Analysis
Facies analysis of subsurface data depends on
tools which delimit of surfaces and provide clues
as to the sediments they contain
28Seismic
Seismic stratigraphic interpretation used to
- Define geometries of genetic reflection packages
that envelope seismic sequences and systems
tracts - Identify bounding discontinuities on basis of
reflection termination patterns and continuity
29Seismic Boundaries
Termination below discontinuity, or upper
sequence boundary
- Toplap termination
- Truncation of sediment surface
- Often channel bottom
Above a discontinuity defining lower sequence
boundary
- Onlap over surface
- Downlap surface
30Seismic Boundaries
Below Boundary - Toplap termination
31Seismic Boundaries
Below Boundary - Truncation of surface
32Seismic Boundaries
Channeled Surface Below Boundary
33Seismic Boundaries
Over Boundary - Onlap onto surface
34Seismic Boundaries
Over Boundary- Downlap onto surface
35(No Transcript)
36(No Transcript)
37(No Transcript)
38(No Transcript)
39Sequence Stratigraphy
Subdivision interpretation of sedimentary
record using a framework surfaces seen in
outcrops, well logs, 2-D and 3-D seismic.
Include
- Surfaces of erosion non-deposition (sequence
boundaries) - Flooding (trangressive surfaces TS /or maximum
flooding surfaces mfs) high stand condensed
surfaces
This framework used to predict the extent of
sedimentary facies geometry, lithologic
character, grain size, sorting reservoir quality
40Tools Define Bounding Surfaces
These surfaces subdivide sedimentary rock
provide-
- Relative time framework for sedimentary
succession - Better understanding of inter-relationship of
depositional settings their lateral correlation
Conceptual models follow that link the processes
that formed the sediments and enable the
prediction of their gross geometries
41Hierarchy of Geometries
- Sequence geometries are subdivided and defined by
- Maximum Flooding Surfaces (mfs)
- Transgressive Surfaces (TS)
- Sequence Boundaries (SB)
- Define how vertical succession or stacking
patterns of unconfined sheets are arranged - Prograde (step seaward)
- Retrograde (step landward)
- Aggrade (build vertically)
- Sheets and unconfined lobes may contain
- Non-amalgamated bodies
- Amalgamated, multi-storied bodies
- Incised topographic fill of valleys
- Unconfined but localized lobes from point
multiple up dip sources - Unconfined but localized build ups (carbonates)
42(No Transcript)
43(No Transcript)
44(No Transcript)
45(No Transcript)
46Delta Mouth Bar - Kentucky
Note Incised Surface
47Channel Gulf Coast
Note Incised Surface
48Flood Deltas Channels - Kty
49TidalChannelsKhor alBazam-UAE
50Tidal, Storm or Tsunami Channel
Note Incised Surface
51Tsunami Load Drape - Kty
Note Uniform Thickness of Layer
52Clastic Sequence Stratigraphic Hierarchies
53Channels Shelves
Channel
Shelf
Both have unique processes structures that can
be used to identify their setting
54Tools Enable Sequence Stratigraphic Analysis
This analysis involves
- Subdivision of section into sequences,
parasequences and beds. - Link conceptual models with mix of components of
the individual sequence, parasequence or beds - Use these to explain the depositional setting in
terms of their lithology, grain size, sedimentary
structures, contacts character (gradational,
abrupt) etc
55SequenceStratigraphicAnalysis
56(No Transcript)
57(No Transcript)
58Unconfined Flow - Not in a Channel
- Unique Processes
- Flow is in all directions
- No lateral boundaries, only upper and lower
boundaries - Velocity changes high to low
- Sediment responses
- Decrease in grain size Fining outward (coarse
to fine) - Erosional/sharp/gradational contacts
- Accretion Downstream, upstream and vertical
- Decrease in sedimentary structures away from
source - Geometries
- Sheets
- Thin in direction of flow
59End of the Lecture