Unraveling Reservoir Architecture of Complex Low Net

Unraveling Reservoir Architecture of Complex Low Net: Gross Red-Bed Fluvial Sequence Using Palaeosoils and Chemostratigraphy* Andrea Moscariello1 Search and Discovery Article #50173 (2009) Posted April 27, 2009 *Adapted from oral presentation at AAPG International Conference and Exhibition, Cape Town, South Africa, October 26-29, 2008. 1

Dept of Geotechnology, Delft Technical University, Delft, Netherlands ([email protected])

Abstract The lack of stratigraphical markers and microfossils in continental, fluvial, low net-to-gross red-bed sequences, make conventional elog based interwell correlations particularly challenging. Effective reservoir modeling and development of such reservoirs therefore rely on application of sedimentological concepts that set the basis for a robust correlation framework. This paper presents a case study located offshore UK, where the sedimentary characteristics and reservoir architecture of a fluvial reservoir were re-evaluated by applying a multidisciplinary approach including pedofacies analysis and chemostratigraphy. This study developed an independent chronostratigraphic framework based on chemostratigraphy related primarily to a careful description and interpretation of “nonreservoir” facies. The innovative use of shear sonic to detect palaeosols in uncored sections was also used for modeling channel distribution. This approach ultimately allowed the identification of meaningful stratigraphic units characterised by changes in the sequence of vertical stacking of pedofacies types. The latter were interpreted as the result of different depositional environments, hence reservoir architecture and connectivity. The application of the pedofacies concept, the use of shear logs, associated with heavy-mineral analysis, allowed an independent validation of the chemostratigraphic correlation scheme, and provided a framework for more sophisticated reservoir modeling. In particular, the recognition of the overall style of fluvial behaviour that may influence the style of channel sand-body stacking provided a predictive model to assess reservoir lateral and vertical connectivity. Also, indication of proximity to channel belts enabled identification of stratigraphical which are likely to be laterally connected to channels not penetrated in the wellbore.

Unraveling reservoir architecture of complex low net:gross red-bed fluvial sequence using palaeosoils and chemostratigraphy. Andrea Moscariello AAPG Cape Town, October 2008

Outline ■

Introduction

■

The Barren Red Measures Group: ■

■

The case study: Schooner and Ketch Fields SNS, UK ■ ■ ■ ■ ■

■

Palaeogeography, Stratigraphy, Climate and Tectonic

Sedimentology First Lithostrat. Correlation & Conceptual geological model Field Performance Second Chemostrat. Correlation and Paleosoils Impact of new integrated approach and results

Conclusions & Learnings Slide 1

Outline ■

Introduction

■

The Barren Red Measures Group: ■

■

The case study: Schooner and Ketch Fields SNS, UK ■ ■ ■ ■ ■

■

Palaeogeography, Stratigraphy Climate and Tectonic

Sedimentology First Lithostrat. Correlation & Conceptual geological model Field Performance Second Chemostrat. Correlation and Paleosoils Impact of new integrated approach and results

Conclusions & Learnings Slide 2

Challenges of distal fluvial systems GR (API) 50

150

250

12800

■

Distal fluvial sandstone associated with red-beds/barren sedimentary successions are common HC-bearing reservoirs worldwide (e.g. Unaizah Fm, Gharif Fm, TAGI, Bunter Sst FM, Silverpit Fm, etc.)

12900

13000

13100

■

Understanding reservoir architecture and sand connectivity is key to establish effective predictive models

13200

13300

■

■

Correlation is challenging because of the difficulty to apply common chronostratigraphic methods (e.g. biostrat)

13400

13500

Even more complicate in endoreic basins where the fluvial system is located away from sea/lacustrine flooding.

13600

Slide 3

Outline ■

Introduction

■

The Barren Red Measures Group: ■

■

The case study: Schooner and Ketch Fields SNS, UK ■ ■ ■ ■ ■

■

Palaeogeography, Stratigraphy, Climate and Tectonic

Sedimentology First Lithostrat. Correlation & Conceptual geological model Field Performance Second Chemostrat Correlation and Paleosoils Impact of new integrated approach and results

Conclusions & Learnings Slide 4

Palaeogeography – Westphalian C

Mid North Sea High

IRL

Barren Red Measures Group •Upper Carboniferous continental fluvial system •Variscan foreland basin

UK

Silver Pit Basin

•Southern Margin of the foreland bulge (Mid North Sea High)

Variscan front

Slide 5

Stratigraphy, Climate and Tectonic STAGES

Age Ma

SAKMARIEN

ASSELIEN

Depositional environment

desert playa lake

Climate

Tectonic

arid wetting upwards

subsiding basin

295

305

WESTPHALIAN D

WESTPHALIAN C 311

Coal Measures Group

WESTPHALIAN

SILESIAN

308

WESTPHALIAN B

Variscan deformation

Saalian Unconf.

Barren Red Measures Group Boulton Ketch Fm Fm

STEPHANIAN

CARBONIFEROUS

Formation Rotliegend Group Silver Pit Claystone

SER IES

AUTUNIAN

SUB SYS TEM

UPPER

PERMIAN

SYSTEM

WESTPHALIAN Stratigraphic Subdivisions A of the British Carboniferous.

low gradient fluvial plain dominated by low sinuosity braided rivers

coastal delta plain dominated by low sinuosity meandering rivers

warm and humid; drying upwards

subsiding southern flank of the Mid North Sea High early Variscan deformation

warm and humid

Foreland of Variscan thrust zone

315

(Moscariello, 2003)

Slide 6

Outline ■

Introduction

■

The Barren Red Measures Group: ■

■

The case study: Schooner and Ketch Fields SNS, UK ■ ■ ■ ■ ■

■

Palaeogeography, Stratigraphy Climate and Tectonic

Sedimentology First Lithostrat. Correlation & Conceptual geological model Field Performance Second Chemostrat. Correlation and Paleosoils Impact of new integrated approach and results

Conclusions Slide 7

Study area Location

Mid North Sea High

IRL

UK Silver Pit Basin

Variscan front

Distance from Mid North Sea High: ca. 120 km

Slide 8

GR (API) 50

150

250

12800

12900

GR (API)

13000 0

50

100

12800

13100 12900

13200

Well A

Depth (ft, MDAH)

12450

12500

50

100

150

13300

13400

Depth (ft, MDAH)

GR (API) 0

Depth (ft, MDAH)

13000

12550

13100

13200

12600

13500

12650

13300

13600

Well A

Well G 13400

13700

13800

Well B 13900

Slide 9

The Ketch Formation ■ Correlation Methods for a Subsurface Formation ■ ■ ■ ■ ■ ■ ■

Seismic: very deep and below salt Biostratigraphy: barren Magneto-stratigraphy: too short time of deposition Tuff layers (tephra): no volcanic activity Vertebrate taphonomy: no too many around Coals: absent Litho-stratigraphy: vertical packages based on wireline logs and extrapolated laterally (distinct N:G intervals)

■ Sequence stratigraphy ? ■ Palaeosoils ? ■ Chemo-stratigraphy ? Slide 10

Reservoir Sedimentology - Facies Based on sedimentological core analysis and wireline log. Facies

Composite channels Single channels Proximal crevasse splay Fine-grained lacustrine and overbank deposits Sols

Grain-size

Gravel 10-15% Coarse to medium sand 35-40% Fine sand 20-30% Silt 30-40% Clay 5 -10%

N:G

30 %

Slide 11

Reservoir facies 1 - Fluvial channel Stacked/amalgamated channel fills with fining upward trend. Planar and trough cross bedding

Vertically aggraded and laterally coalesced low sinuosity braided channel complex

Pebble conglomerate/lag Cross bedded sets typically developed at the base of sand body

Low sinuosity braided channel bar complex deposited during high stage flood conditions

Pebble conglomerate dominated by Qz clasts. Abrupt changes to finer grained Sandstone

Slide 12

Non-Reservoir facies 2 - Flood Plain Bedded very fine grained sandstone with interbedded silt-claystone Fining upward trend Ripple-cross and planar lamination

Proximal overbank deposits. Sheetfloods, crevasse splays with interbedded floodplain deposits

Massive very fine sandstone Interfluvial/flood plain with soft sedimentary deposits relatively well deformation drained

Haematitic reddish/brown silt/claystone with rootlet/plant remains and pedogenic fabric

Palaesois

Pedogenic/mottled/churned clay/peds rich/siltstone with calcretes Slide 13

Conceptual Geological model Depositional environment of the Barren Red Measures - Upper Carboniferous SNS

Low sinuosity, sandy, braided river belts

Inland source area

Large interfluves with well layered mud, siltstone and ephemeral lacustrine deposits.

Slide 14

Model 1: Litho-stratigraphic correlation across the Schooner Field (flattened at Ketch Formation base ) SA01/03S1 True Vertical Depth Sub Sea none MD KB none FEET facies

TVD SS 0 CGR_01R 140 none MD KB 0 FLOWUP 100 FEET CGR_01R none FEET facies No fil Plus Minus

SA04/08 True Vertical Depth Sub Sea

44/26-3 True Vertical Depth Sub Sea

TVD SS 0 GR_00J 140 none 0 FLOWUP 100 MD KB none FEET FEET GR_00J facies No fil Plus Minus

TVD SS 0 GR_00J 140 45 CNL_00J -15 none MD KB FEET FDC_00J none FEET GR_00J facies No fil No fil Plus Minus Plus Minus

1 3 5 0 0

1 3 2 5 6 1 3 3 8 8

1 3 2 9 6 .9

1 4 0 0 0

1 4 2 5 4

1 4 0 9 6

1 2 5 0 0 1 2 6 8 5 .3

1 4 0 0 0

1 5 0 0 0 1 5 0 0 6 .5 1 5 0 0 0

1 3 0 7 5 1 3 0 0 0

1 3 7 3 0

1 3 6 3 8 .8

1 4 6 8 6 .4 1 4 7 7 5

1 3 0 7 5 1 3 0 0 0 1 3 1 3 1 .5

1 4 5 0 0

1 3 9 4 3 .3

1 3 2 6 6 .1

1 4 4 2 3

1 2 6 8 7 .2

1 3 5 0 0

1 4 5 0 0

1 2 5 0 0

1 3 5 0 0

1 3 5 0 0

1 2 7 8 9 .6

1 3 5 0 0 1 3 6 9 5 .3

1 3 3 3 1

1 2 9 2 3 .8 1 3 0 7 5 .1 1 3 0 0 0

1 2 7 9 4 .2

1 3 6 1 3 1 3 7 8 9

1 3 1 6 5

1 3 0 0 0

1 3 0 0 0

1 2 5 0 0 1 3 5 3 6 1 3 5 0 0

1 2 0 6 6 .7 1 2 0 0 0 1 2 1 2 1 .5 1 2 2 4 7 .2

1 7 5 0 0 1 8 0 0 0

1 8 8 1 0 .4 1 9 0 0 0

1 7 9 7 4 .1

COAL MEASURES

1 3 5 0 0

1 8 0 0 0

1 3 0 7 5 .1 1 3 0 0 0

1 3 1 6 8 .1

1 3 0 7 5 .1 1 3 0 0 0

1 3 0 0 0

1 3 0 7 5 1 3 0 0 0

1 7 5 0 0

1 3 0 0 0

1 8 5 0 0

1 8 4 6 0

1 2 8 4 7 .8

1 7 3 5 8

1 2 7 7 3

1 2 6 5 3 .2

1 2 5 0 0

1 2 5 0 0 1 2 6 8 0 .2

1 2 9 0 6 .2 3 1 3 2 0 5 .1

1 2 5 0 0 1 7 0 0 0

1 2 5 0 0

1 6 9 7 8 .5 9

1 2 3 7 6 .5 8

1 2 4 3 8 7 .5 9

1 1 2 2 4 4 0 0 9 9 ..8 5 4

1 1 7 7 7 7 9 9 1 0 .3 5

1 6 5 0 0

1 2 0 0 0

1 2 0 0 0

1 2 3 4 5 4 .9 3 2

1 2 5 0 0 1 2 5 0 0 1 2 7 7 6 .2 3

FWL

Coal Measures

1 3 0 7 5 .1 1 3 0 0 0

FWL

BRA

FWL

FWL

BRB

FWL

1 2 8 3 8

1 2 0 0 0 1 2 0 0 0

1 2 0 0 0

Saalian Unconformity

COAL MEASURES

BRC

1 2 4 4 9 .3

1 2 0 0 0

1 2 2 1 6

1 3 3 7 8

1 3 0 0 0

1 7 0 0 0

1 6 0 0 0

1 2 7 6 2

TVD SS 0 GRS_00J 140 LDEN_01R FEET GRS_00J CNL_01R No fil No fil Plus Minus Plus Minus

SE

1 3 1 6 6 .1

SA02/05 True Vertical Depth Sub Sea

TVD SS 0 GR_00J 100 none MD KB none FEET FEET GR_00J facies No fil Plus Minus

Well G

1 2 6 7 1

SA03/07 TVD SS

TVD SS 0 GRIC_00J 80 none MD KB FEET GRIC_00J none FEET facies No fil Plus Minus

Well F

Well E

1 1 9 1 5

1 1 7 8 5 .1

SA05/01 TVD SS

TVD SS 0 depthGR 140 45 CNL_00J -15 none MD KB FEET depthGR FDC_00J none FEET No fil No fil Plus Minus Plus Minus

Well D

1 3 0 7 5 .1 1 3 0 0 0

44/26-2 True Vertical Depth Sub Sea

Well C

1 2 5 0 0

44/26-4 True Vertical Depth Sub Sea TVD SS 0 GR_00J 140 45 CNL_00J -15 none MD KB FEET GR_00J FDC_00J none FEET No fil No fil Plus Minus Plus Minus SILVERPIT CLAYSTO

Well B

Well A

NW

Slide 15

Model 1: Sequence stratigraphy approach

Well G

Unit C: Finer sediments indicating increased rates of BL rise. Great floodplain storage of accommodation

Well E

Well D

Unit B: Non reservoir Well A

Unit A: Aggradation at early base level rise and valley infill caused by backstepping

1996 model:

Width range: 250-4000 m; T:W range: 1:9 - 1:500 Slide 16

Field Production Performance

Gas flow rate

Well 2

Well 4 Well 5 Well 3 Well 6

Well 1

Year 1/10

Year 2/4

Year 2/10

Year 3/4

e.g. Well 4 actual vs. planned

Year 3/10

Time

Slide 17

Model 2: Chemo-stratigraphic correlation across Schooner Field (flattened at Ketch Formation base ) SA02/05 True Vertical Depth Sub Sea

TVD SS 0 GR_00J 100 none MD KB none FEET FEET GR_00J facies No fil Plus Minus

TVD SS 0 GRS_00J 140 LDEN_01R FEET GRS_00J CNL_01R No fil No fil Plus Minus Plus Minus

Well F

Well E SA01/03S1 True Vertical Depth Sub Sea

none MD KB none FEET facies

Well G

SA04/08 True Vertical Depth Sub Sea

TVD SS 0 CGR_01R 140 none MD KB 0 FLOWUP 100 FEET CGR_01R none FEET facies No fil Plus Minus

TVD SS 0 GR_00J 140 45 CNL_00J -15 none MD KB FEET GR_00J FDC_00J none FEET facies No fil No fil Plus Minus Plus Minus 1 2 6 7 1

1 3 0 0 0

1 3 5 0 0

1 3 1 6 6 .1

MD KB FEET

12761

12670

12600

12217.3

12200

12217.3 12200

12800 12630.8

12600

12810.8

13000

12630.8 12600 12810.8 12800

13200

13675

FWL

13200

13166

13075

13342

13293

13400 13595

B 13600

13074.7 13125.7

13503.9

13074.7 13125.7

14408 14400

13800

12600

18360 18443 18400

12677.1

12782.9 12836.8 12800

13400

13489

13397.9

12981.7 13000

12981.7 13000

13725 13695.2 13894

13600

13098 13075 13228.2 13200

14237 14200

13384

13536

13200

12800

13400

12802.4 12800 12951.8 13000

14069

14000

13937

12352.7 12561.7

18195 18200

17400

17200

12600 0

12445.6 12400

18006 18000 12600

17125.1 17357.5 17331.1

12676

12481 12652.8 12633.7 12600

12568 1273312713

12553.6

16981.4 17000

12378.5 12400

12438 12400

12345.3 12400 12475.3

Unit 2 Unit 1

12640.2 12620.2 12600

13800

17788 17800

12407.8 12400

Unit 4 16800

12200

12200

12200

Top Unit 4

12165.7

16600

17600

13600

13000

12902

12993

12491.6

12491.6

13086

12620.1 12600

13000

12800

12400

13400

12400

12453.6

12844 12800

12400

13200

COAL MEASURES

13532

1 3 7 3 0

12063.8

12000

17400 12200

TVD SS 0 GR_00J 140 45 CNL_00J -15 none none FEET GR_00J FDC_00J facies No fil No fil Plus Minus Plus Minus

Unit 3

12200

44/26-3 True Vertical Depth Sub Sea

TVD SS 0 GR_00J 140 none 0 FLOWUP 100 TVD SS none FEET FEET GR_00J facies No fil Plus Minus 12600

1 3 5 0 0

11800

1 3 5 0 0

17200

1 3 6 3 8 .8

1 5 0 0 0

16400 12000

1 5 0 0 6 .5 1 5 0 0 0

12000

1 3 0 7 5 1 3 0 0 0

1 9 0 0 0 1 8 0 0 0

TVD SS 0 CGR_01R 140 none 0 FLOWUP 100 MD KB none FEET FEET CGR_01R facies No fil Plus Minus

12600

1 3 2 5 6

17000

1 3 3 8 8

1 3 2 9 6 .9

1 4 0 9 6 1 4 2 5 4

1 4 5 0 0 1 4 6 8 6 .4

12000

1 4 7 7 5

1 3 0 7 5 1 3 0 0 0

16200

1 3 1 3 1 .5

12000

1 3 0 0 0 1 3 1 6 8 .1

1 3 0 7 5 .1 1 3 0 0 0

Top Unit 5

Saalian Unconformity

1 3 5 0 0

FWL

SA04/08 True Vertical Depth Sub Sea

SA01/03S1 True Vertical Depth Sub Sea

none MD KB none FEET facies 13000

1 3 0 7 5 .1 1 3 0 0 0 1 3 1 6 5

1 4 0 0 0

1 2 5 0 0

1 2 6 8 5 .3 1 2 7 8 9 .6

1 3 5 0 0

1 3 5 0 0

11800

1 4 5 0 0

1 3 9 4 3 .3

1 3 2 6 6 .1

1 4 4 2 3

FWL

Well G

FWL

TVD SS 0 GRS_00J 140 LDEN_01R FEET CNL_01R GRS_00J No fil No fil Plus Minus Plus Minus

1 3 6 9 5 .3

11800

16000

1 3 3 3 1

1 3 7 8 9

1 2 9 2 3 .8

1 4 0 0 0

1 3 0 7 5 .1 1 3 0 0 0

1 2 5 0 0

11800

1 2 6 8 7 .2

1 8 4 6 0 1 8 8 1 0 .4

1 3 0 0 0

1 3 0 0 0

1 2 5 0 0 1 3 6 1 3

1 2 7 9 4 .2

1 2 2 4 7 .2

1 1 7 7 7 7 9 9 1 0 .3 5 1 8 0 0 0

TVD SS 0 GR_00J 100 none MD KB none FEET FEET GR_00J facies No fil Plus Minus

1 7 5 0 0

1 3 0 0 0

1 8 5 0 0

1 2 8 4 7 .8

1 7 3 5 8 1 7 9 7 4 .1

1 3 0 7 5 1 3 0 0 0

1 2 6 5 3 .2 1 3 0 7 5 .1 1 3 0 0 0

1 2 7 7 3

1 2 5 0 0

1 2 5 0 0 1 2 6 8 0 .2

1 2 9 0 6 .2 3

TVD SS 0 GRIC_00J 80 none MD KB none FEET FEET GRIC_00J facies No fil Plus Minus

Well F

Unit 4

1 3 2 0 5 .1

1 2 5 0 0 1 7 0 0 0

1 2 5 0 0

1 6 9 7 8 .5 9

1 2 3 7 6 .5 8

1 2 4 3 8 7 .5 9

1 2 5 0 0

1 2 3 4 5 4 .9 3 2

1 2 5 0 0

SA02/05 True Vertical Depth Sub SeaFWL

Well E

Unit 5

1 2 7 7 6 .2 3

SA03/07 TVD SS

SA05/01 TVD SS

Coal Measures

FWL

Well D

BRA

1 3 0 7 5 .1 1 3 0 0 0

TVD SS 0 depthGR 140 45 CNL_00J -15 none MD KB none FEET FEET depthGR FDC_00J No fil No fil Plus Minus Plus Minus

SE

Well C

BRB

1 1 2 2 4 4 0 0 9 9 ..8 5 4

44/26-2 True Vertical Depth Sub Sea

COAL MEASURES

Well B

1 3 5 3 6 1 3 5 0 0

1 2 0 6 6 .7 1 2 0 0 0

1 7 5 0 0

1 6 5 0 0

Well A

1 2 1 2 1 .5

Saalian Unconformity

1 2 8 3 8

1 2 0 0 0 1 2 0 0 0

1 2 0 0 0

1 2 0 0 0

1 2 0 0 0

NW

BRC

1 2 4 4 9 .3

1 2 0 0 0

1 3 3 7 8

1 2 2 1 6

1 7 0 0 0

1 6 0 0 0

SE

44/26-3 True Vertical Depth Sub Sea

TVD SS 0 GR_00J 140 none 0 FLOWUP 100 MD KB none FEET FEET GR_00J facies No fil Plus Minus

1 2 7 6 2

Well D

SA03/07 TVD SS

TVD SS 0 GRIC_00J 80 none MD KB FEET GRIC_00J none FEET facies No fil Plus Minus

1 1 9 1 5

1 1 7 8 5 .1

Well C

SA05/01 TVD SS

TVD SS 0 depthGR 140 45 CNL_00J -15 none MD KB FEET depthGR FDC_00J none FEET No fil No fil Plus Minus Plus Minus

1 2 5 0 0

44/26-2 True Vertical Depth Sub Sea

TVD SS 0 GR_00J 140 45 CNL_00J -15 none MD KB FEET GR_00J FDC_00J none FEET No fil No fil Plus Minus Plus Minus SILVERPIT CLAYSTO

Well B

Well A

NW 44/26-4 True Vertical Depth Sub Sea

FWL

Slide 18

Challenge ■ Reservoir performance, connected HC, doesn’t seem to

honour the 1st correlation and related geological conceptual model. ■ The new, 2nd correlation and associated reservoir

connectivity, might be right but is largely inconsistent with 1st geological model. ■ How can we ensure the new correlation is right ?

■ No alternatives: Back to the rocks and give a better look also at the non-reservoir intervals. Slide 20

P edofacies types Type 1

Primary sedimentary structures (bedding, soft sed. deformation, etc..) preserved, no (or very rare) occurrence of bioturbation and/or rootlets. Some hematite nodules occur. Interpretation: high sedimentation rate and high aggradation; channel or frequently feed alluvial plain

Type 2

Primary sedimentary structures are preserved but can be locally disturbed by bioturbation or rootlets which make up 10-20 % of the fabric. Interpretation: moderate aggradation sediments Slide 21

Pedofacies types Type 3

Rare preservation of primary sedimentary structure up to 30-50% of fabric disturbed by bioturbation and rootlets. Interpretation: low aggradation sediments

Type 4

No primary structure preserved, original fabric completely churned up, heavy bioturbaion, ferriginous features (pisolites) and siderite nodules, salt (barite ?), pedorelicts. Interpretation: mature paleosoil, (ultisol, tropical podzol, calcrete) intense redox and illuviation processes, wet/dry cycles very low or absent aggradation rate (long sub-aerial exposure). Slide 22

Pedofacies at the microscope

Pedofacies 1: Undisturbed lamination picked out by aligned mica and hematite-rich clay

Pedofacies 3: Cluster of opaque nodules showing separation from the groundmass (outlines around grains); stress cutans also present

Pedofacies 2-3: Anisotropic, parallel alignment of clay minerals, also with a parallel extinction pattern; grain coatings present (arrowed)

Pedofacies 4: Multiple-stress cutans and Opaque clay filled fine brecciation

cracking, developing through soil fabric from larger cracks

Increased evidence of clay movement, the presence of better developed soil fabrics and an intimation of the existence of a soil structure in pedofacies 4

Slide 23

Pedofacies distribution on the Upper Carboniferous alluvial plain: Ketch Formation

Pedofacies 4

Pedofacies 3

Pedofacies 2

Pedofacies 1

levee

channel

water table

distal floodplain

proximal floodplain

Pedofacies models: M. Kraus et al… Slide 24

1 3

1

4

1

Pedofacies cyclicity

3 3

13500

1

4

4 3 1

4

3

2

3

4

13550

1 13600

2 2

1 1

4

1

13650

13700

2 4

1

13750

1 13800

13850

Slide 25

Pedofacies stratigraphy 2 3

Pedofacies

GR (API) 0

2

100

200

1

2

3

4

Thickness (ft) 0

5

10

15 20

1

pedofacies 2 type 1 2 1 2

13500

stratigraphic log

13600

13700

4 3 2 1

13800

13900

Slide 26

Recognition of Pedofacies in uncored wells Shear Sonic

Pedofacies type

(microsec/ft)

Feet AH

80

120

160

13500

13500

13550

13550

13600

13600

13650

13650

13700

13700

13750

13750

13800

13800

13850

13850

1

2

3

4

Correlation between shear sonic log and pedofacies from core data. Pedofacies 1 (i.e. nonpedogenised facies) to 4 (strongly pedogenised facies) indicate high and low sedimentary aggradation, respectively.

Slide 27

Well E 12800

Depth (ft, MDAH)

12900

Well G

GR (API)

Pedofacies

Thickness (ft)

50 150 250

1 2 3 4

0 5 10 15 20

5

0

12800

12900

13000

13000

13100

13100

13200

4

13300

13400

3

GR (API) 50 100

Pedofacies

Thickness (ft)

1 2 3 4

5 4

13200

13300

3

13400

2

Reservoir anatomy based on pedofacies vertical and lateral distribution Well G Well E

?

Upper Ketch Fm

13500

13600

2

13700

13800

1

13900

chemostratigraphic units

Pedofacies/ aggradation relationship 1: high 2: moderate 3: low 4: very low

Unit 4-5

Well A

Well G

Lower Ketch Fm Unit 1-2-3 channel

palaeosol

flood plain

(Moscariello, 2003)

Example of lateral correlation and pedofacies distribution for 2 wells in the Silver Pit Basin (Barren Red Measures, Westphalian C) Slide 28

Impact on Reservoir Prediction Sequence Stratigraphy old model Fluvial architecture

Relative change in base level, wetness and available accommodation space

Unit C Unit B Unit A

Slide 29

Sequence stratigraphy

Unit C

new model Fluvial architecture

Units 4,5

Unit B Unit A Lithostratigraphy

Units 1,2,3

Foreland subsidence

old model Fluvial architecture

Relative change in base level, wetness and available accommodation space

Chemostratigraphy & Pedofacies Slide 30

Impact on Reservoir Modeling and Field Performance Prediction

New Geological Conceptual Model

Alternative Reservoir Analogue (Keighley et al, 1998)

Reliable prediction capabilities

Revised aspect ratio

Update geo-cellular model Slide 31

Outline ■

Introduction

■

The Barren Red Measures Group: ■

■

The case study: Schooner and Ketch Fields SNS, UK ■ ■ ■ ■ ■

■

Palaeogeography, Stratigraphy Climate and Tectonic

Sedimentology First Lithostrat. Correlation & Conceptual geological model Field Performance Second Chemostrat Correlation and Paleosoils Impact of new integrated approach and results

Conclusions & Learnings Slide 32

Conclusions ■ Flood plain composition and vertical evolution in low

N:G systems are intimately linked to channel sand distribution and reservoir architecture ■ Use of multiple and independent approaches (N:G

distribution, pedofacies, chemostratigraphy) allowed us to: ■define an alternative evolutionary model of the sedimentary basin

which resulted to be more consistent with the regional tectonic evolution of the basin (sequence stratigraphy approach helps but is correlation driven !!) ■better constrain the static and dynamic model by using

appropriate analogue data (i.e. reservoir performance prediction). Slide 33

Learnings 1. Limitation of using lithostratigraphic subdivision based on wireline log in isolation. 2. Shear sonic together with GR can be successfully utilised to identify pedofacies vertical patterns in uncored wells. 3. Chemostratigraphy can be efficiently used as a tool to assist definition of a reliable correlation framework, hence connectivity. 4. Importance of palaeosoils/pedofacies in characterising internal reservoir architecture in low N:G, barren fluvial reservoirs also in the subsurface. Slide 34

THANK YOU

Slide 35

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Pearce, T.J., D. McLean, D.S. Wray, D.K. Wright, C.V. Jeans, and E.W. Mearns, 2005, Stratigraphy of the Upper Carboniferous Schooner Formation, southern North Sea: chemostratigraphy, mineralogy, palynology, and Sm-Nd isotope analysis, in Carboniferous hydrocarbon geology, the southern North Sea and surrounding onshore areas: Yorkshire Geological Society Occasional Publication, v. 7, p. 165–182. Stone, G., and A. Moscariello, 1999, Integrated Modelling of the Southern North Sea carboniferous barren red measures using production data, geochemistry and pedofacies cyclocity: Offshore Europe, v. 99, 7-10 Sept 1999, Aberdeen Scotland, SPE 56898, 8 p.