Geology Basins

Question 1

4

What controls sediment supply?
and Basin Types

Answer 1

Tectonics (need to fill a hole!) and Climate

1. Rift - Stretch therefore rapid subsidence, then decrease profile
2. Passive Margin - Continued extension, creates oceanic crust (constructional and starved passive margins)
3. Strike - Slip - Flower Structures
4. Foreland - Loading causes subsidence eg. south falkland basin

Question 2

What creates the waves for seismic?

Answer 2

• Hammer and dynamite (onshore)
• Airgun (offshore)

Question 3

Seismic Receivers

Answer 3

• Hydrophones (offshore)
• Geophones (onshore)

Question 4

Seismic Recorders

Answer 4

Seismograph

Question 5

What does seismic data present?

Answer 5

The measured changes in density through changes in velocity of seismic waves

Question 6

4

What does seismic allow us to do?

Answer 6

1. Identify potential targets
2. Understand geological history of region
3. Identify potential hazards
4. Quantify potential resources

Question 7

Seismic Strat.
How would you identify Onlap/Offlap

Answer 7

Dip less than surface they terminate on

Question 8

Seismic Strat
How would you identify Down lap

Answer 8

Dip greater than surface they terminate on

Question 9

Seismic Strat
How would you identify Toplap

Answer 9

Dip greater than surface at which they terminate. Mirror of downlap

Question 10

5

Play requirements

Answer 10

• Source
• Migration pathway
• Reservoir
• Seal
• Trap

Question 11

Play Concept
Source

Answer 11

Sed. rock - sufficient organic mats
1st Carbs and proteins, then lipids and ligins
Oil and gas from aqueous - mainly gas from terrestrial
- Sed. decreases therefore increase concentration organic matter
- Anoxic environment therefore lack of circulation

Question 12

Main source rock depositional environments

Answer 12

lacustrine eg. green river formation, Utah
Delta eg. Missionary bay Mangroves
Deep Marine eg. Black sea

Question 13

What are the key types of well data?

Answer 13

Core, Mud logging, and wireline

Question 14

Play Concepts
What is Primary Migration

Answer 14

• Flow out of source
• Low permeability: fracture in source promote expulsion
• Kerogen to petroleum = increase vol. therefore promiotes micro-fracturs and increase pA

Question 15

What does Gamma ray show?

Answer 15

Quantities of K, Th, and U within rocks
Low values usually sandstone, high values usually shale
Help to understand depositional environment

Question 16

Play Concepts
What is Secondary Migration

Answer 16

• Flow from sources
• HCs more buoyant that water and decrease solubility
  therefore drives migration

Question 17

What does Neutron Data show?

Answer 17

Indicates porosity by No. hydrogen atoms
Hydrogen present in water and HCs
Count rate is low in high porosity rocks, and high in low porosity rocks
(where less H, neutrons bounce back therefore high return, where more H, neutrons scatter, therefore less return)

Question 18

Play Concepts
Reservoir requirments?

Answer 18

Porous and permeable

Question 19

Play Concepts
What can the reservoir be affected by?

Answer 19

Cementation/Compaction

How heterogenous are units? (How dif.?)

Question 20

Play Concept
Other Reservoir info?

Answer 20

Dissolution of limestone can create reservoir
Darcy units used to measure perm.
- 1 Darcy = very good res. Nichols 2009

Question 21

Play Concepts
What are the best reservoirs?

Answer 21

• Well sorted sandy desserts
• Shallow seas
• Oolittic Grainstones
• Boundstones

(Less important)
- Rivers
- Deltas
- Submarine fans

Presence of mud and cementation decreases porosity

Question 22

What does Density data show?

Answer 22

Gamma rays emitted
Collide with electrons
Scatter
Returning rays counted
High bulk density = lots of electrons = scattering = low return rate

Question 23

Play Concepts
What makes a seal effective?

Answer 23

1. Low porosity and permeability
2. Capillary pressure greater than buoyancy pressure
3. Regionally extensive
4. Ductile (bends not fracture)

Question 24

Play Concepts
What are the best seals?

Answer 24

• Fine grained sediments (shales) greater gamma
• Evaporates (can move) very low gamma

Question 25

Play concepts
Structural Traps

Answer 25

1. Anticlinal (no fractures?)
2. Salt dome (future movement?)
3. Fault trap (Clay smearing? Cataclasis?)

Question 26

Play Concept
What is a trap?

Answer 26

Conc. of HCs

Question 27

Play Concept
Stratigraphic traps

Answer 27

1. Pinchout
2. Unconformity
3. Reef

Question 28

What can be done with Neutron Density Data

Answer 28

-Both used together for accurate evaluation of porosity
-Where they track together = Sst
-Where they are separate = different lithologies or gas
-Where there is gas - density log values are high and neutron log values are low
-Use with Gamma rays for better understanding

Question 29

3 key types of explorations

Answer 29

-buy into existing field
-explore other parts of an identified producing region
-explore new region

Question 30

Pros and cons of buying into existing field

Answer 30

Pros:
-high success rate
-good infrastructure
Cons:
-high buy in costs
-low potential returns

Question 31

Pros and cons of exploring others parts of identified region

Answer 31

Pros:
-good understanding of existing system
-lots of potentially cheaper data
Cons:
-more difficult targets
-lower potential returns

Question 32

Pros and cons of exploring new region

Answer 32

Pros:
-potentially high returns
Cons:
-high risk
-limited existing data therefore expensive

Question 33

How can gravity help search for HCs

Answer 33

-Stage 1 of investigations
-Variations in r alters observed g
-Underlying densities change observed g
-Therefore can identify anomalies
-Can make assumptions about subsurface when comparing to observed measurements
-Oil can produce a gravity low
-Cost effective way of getting regional data
-Used IF substantial density contrasts are expected

Question 34

What has an influence on heat flow

Answer 34

-crustal thinning
-mantle upwelling
-water circulation
-sills and dykes
-salt
-the rocks themselves
-can effect oil window

Question 35

Features:
-Rootlets upper tidal flats
-Flaser/lenticular bedding
-Ripple cross lamination
-Heterolithic Strat.
-Bi-directional herringbone

Answer 35

Tidal Estuary - Coastal

Question 36

Features:
-Mouth bar deposits - well sorted
-Delta plain = fine grained sand, interbedded with silt
-Beach = wave ripples and medium sand
-Delta front = mudstone interbedded with sand and bioturbation

Answer 36

Wave dominated delta - Delta

Question 37

Features:
-Bi-directional features, herringbone
-Mud drapes during slack water

Answer 37

Tidal Dominated Coast - Coastal

Question 38

Features:
-Inner shelf grain/packstone
-Outer shelf pack/whackstone
-Slope redeposited limestone
-Shelf edge grainstone shoals
-Slump deposits
-Deep water carbonate

Answer 38

Non-rimmed Carbonate shelf - Shallow Marine Carbonate

Question 39

Features:
Boundstone at top
-Forereef slope rudstone and redeposited limestone
-Slump deposits
-Pelagic and Carbonate mudstone turbidites further out

Answer 39

Carbonate Rimmed Shelf - Shallow Marine Carbonate

Question 39

Features:
-Grain Stones shoals in top
-Ooids
-Bioclastic Material
-Mid-ramp redeposited material
-Outer-ramp mud/wackstone

Answer 39

Carbonate Ramp - Shallow Marine

Question 40

Feautures:
-Delta Plain = Fine grained sand and silt with current ripples
-Delta channels = medium sand with current ripples
-Moth bar = massive medium sand
-Delta front = bioturbation, slumping structures, fossils

Answer 40

River Dominated Delta - Delta

Question 40

Features:
-Beach = medium sand
-Estuary mouth = cross bedding, fossils and current ripples
-Central lagoon = bioturbation and limestone
-Bay head delta = cross strat and bioturbation

Answer 40

Wave dominated Estuary - Coastal

Question 41

Features:
-Shoreface = cross strat. and bedded sands
-Reworked sands before tidal currents and storms
-Offshore transition zone = hummocky cross-strat., interbedded with bioturbated mud
-Offshore = bioturbation, mudstone

Answer 41

Tidal Influenced Shelf succession - Shallow Marine

Question 42

Features:
-Cross-strat.
-Mud drapes
-Bi-directional features, herringbone

Answer 42

Tidal Dominated Delta - Delta

Question 43

Features:
-Shoreface = wave ripples and swale
-Offshore transition = thin sheets mud and sst, hummocky cross-strat
-Offshore = bioturbation

Answer 43

Storm Dominated Shelf - Shallow Marine

Question 44

Features:
-Grading up into finer grained deposit
-Matrix or clast support where cobbles and boulders embedded in fine sediment

Answer 44

Debris Flow - Deep Marine

Question 45

Features:
-Rootlets, muds and sands
-Channel fill succession of TxB sands
-Fining upwards
-Lateral accretion surfaces
-Scoured channel base
-Finer grain sizes than a Braider River

Answer 45

Meandering River - Fluvial

Question 46

Features:
-Mix of sand, gravel, and mud
-Inner fan = thick conglomerate and sst turbidites
-Thin levee deposits
-Mid fan = coarsening up succession of sandy turbidites
-Distal fan = fine grained turbidites

Answer 46

Submarine Fans - Deep Marine

Question 47

Features:
-Rootlets
-Fine sand and muds
-Trough cross bedding in channels, fining up
-Coarsest sediments lower flat laminated
-Scoured channel base

Answer 47

Braided River - Fluvial

Question 48

Features:
-Depositional couplets (alternating fine and course material)
-Antidunes upstream
-Clast imbrication
-Poorly sorted silt and clay

Answer 48

Alluvial Sheetflood deposit - Alluvial

Question 49

Features:
-Disc structures
-Laminated and cross-bedded sand
-Pebbly and water escape structures
-Reverse grading at bottom of sequence

Answer 49

Lowe Sequence Turbidite Flow - Deep marine

Question 50

Features:
-Matrix supported
-Crude clast imbrication of bigger clasts
-Poorly sorted

Answer 50

Debris Flow - Alluvial

Question 51

Features:
-Muds and wave rippled sands
-Deeper laminated dark shales
-Thin turbiditic sands

Answer 51

Lacustrine Deposit - Lacustrine

Question 52

Features:
-Cross laminated sands and ripples
-Parallel laminated sands
-Massive sands and granules rapidly deposited under upper flow regime
-Scoured erosional base

Answer 52

Bouma Sequence Turbidite Flow - Deep Marine

Question 53

What is the control on marine sedimentation?

Answer 53

Base level (sea level)

Question 54

What is progradation (normal)

Answer 54

S>A
Level, seaward

Question 55

What is progradation (forced regression)

Answer 55

S>A where sea level lower
Down, seaward

Question 56

What is retrogradation

Answer 56

A>S where sea level rises
Up, Landward

Question 57

What is aggradation

Answer 57

A=S where sea level rises
Up, static

Question 58

What is Sequence Stratigraphy

Answer 58

“study of stratal stacking patterns and changes thereof in a time framework” (Catuneanu et al. 2009)

Question 59

What is a Sequence Boundary (SB)

Answer 59

-The surface in which the first signs of erosion occur due to sea level fall
-From aggradation to progradation (forced)

Question 60

Highstand System Tract (HST)

Answer 60

-Sea level rising
-Steep curve steadying out
Therefore aggradation (where steep), then progradation (where levels out)

Question 61

Falling Stage System Tract (FSST)

Answer 61

-Fluvial systems incise and transport sediment basinwards
-Downward shift in facies (foreshore lies on offshore transition with SB between)

Question 62

Lowstand System Tract (LST)

Answer 62

-Relative sea level at min
-Sea level begins to rise (limited) - therefore Accom.
-Progradational to Aggradational
-Onlapping, clinoforms that thicken updip

Question 63

Transgressive Surface (TS)

Answer 63

-A>S (where Supply is constant)
-Sedimentation migrates landward
-TS marks sea level rise

Question 64

Transgressive System Tract (TST)

Answer 64

-Sea level rise increases
-A>S (supply is constant)
-Retrogradational
-Onlap, clinoforms thicken landward

Question 65

Maximum Flooding Surface (MFS)

Answer 65

-Hiatus in deposition occurs
-Surface above which is MFS
-The most landward region of the marine realm

Question 66

Allogenic

Answer 66

Basin wide
World Wide

Question 67

Autogenic

Answer 67

within system

Question 68

Two types of Geothermal systems

Answer 68

-High temp >180C
-Low temp <100C

Question 69

Two Shallow Geothermal Energy Soruces

Answer 69

-Heat pumps - Open loop and closed loops. Open is heat exchange with groundwater. Closed is heat exchange from installed boreholes. Local Scale Heating
-Mine water systems - Old mines, storage and pathways for water, heated water extracted, boreholes used. e.g. Heerleen, Netherlands. Midland Valley, Scotland (Glasgow. Adams et al. 2009)

Question 70

Geothermal Energy facts

Answer 70

-Volcanic activity
-Water pumped to hot granites
-Requires permeability (fractures)
-Can be natural fractures or fracking

Question 71

Three components to Geothermal Energy

Answer 71

Heat, Water, Permiability

Question 72

Geothermal Potential UK

Answer 72

-26C/Km gradient
-3000m depth would be 88C
-Post carboniferous sed basins best
Eden Project - hot granite under Cornwall

Question 73

Where is hydrogen found

Answer 73

Water, HCs (most effective), organic matter

Question 74

What is hydrogen used for

Answer 74

burned as combustible fuel, or fuel cells

Question 75

Hydrogen Storage

Answer 75

-reservoir
-cap (ductile and high capillary pA)
-Trap structure
-Salt caverns can be used
-seal needs to be better quality than for HCs as higher buoyancy pA/>leak ability

Question 76

Where is CO2 critical at?

Answer 76

31C and 7.38MPa

Question 77

What is needed for CCS

Answer 77

Reservoir, Seal, Trap

Question 78

What infrastructure is in place after HCs

Answer 78

Rigs, Wells, Pipelines

Question 79

UK CCS example

Answer 79

Teeside, South Wales, Grangemouth, Acorn Project in North Sea

Question 80

Requirements for Nuclear Waste Storage

Answer 80

Space, no migration, stable groundwater, no protected areas, wont be affected by future climates

Question 81

Three types of Nuclear Storage Rock Types

Answer 81

-Salt as impermeable
-Low strength - low permeability clays and mudstone
-High strength - low permeability granites/slates

Question 82

Other nuclear storage requirements

Answer 82

Depth of 200-1000m
Thickness of 10s of metres
Several kms wide