1. 2014 RMS-AAPG Luncheon, Oct 1st, Denver, CO
A Comprehensive Deterministic Petrophysical Analysis Procedure for Reservoir Characterization: Conventional and Unconventional Reservoirs
2014 RMS-AAPG Luncheon, Oct 1st, Denver, CO
Presented by: Michael Holmes, Antony Holmes and Dominic Holmes Digital Formation, Denver, Colorado, 2014

2. Outline Introduction Procedures
Conventional and Unconventional reservoir petrophysical models
Procedures
1. Standard shaley formation petrophysical model
2. Unconventional reservoir petrophysical model
Four porosity components model
TOC calculations
Standard vs. shale only density/neutron comparisons
Free and adsorbed hydrocarbons

3. Outline Procedures Cont. Examples 3. Fracture analysis
4. Relative permeability model
5. Rock physics model and mechanical properties – brittle vs. ductile
6. Comprehensive petrophysical model
Examples
Niobrara, Colorado
Barnett Shale, Texas
Antrim Shale, Michigan
Shale Gas, Western Canada
Bakken, Montana
Tight Gas, Colorado
New Albany, Illinois

4. Conventional Reservoirs
Introduction
Conventional vs. unconventional reservoir petrophysical models
Conventional Reservoirs
Shale
Matrix
Effective Porosity
Water
Oil/Gas
The Reservoir

5. Unconventional Reservoirs
Introduction
Unconventional Reservoirs
Free Shale Porosity
PhiFS
Water
Adsorbed Hydrocarbon ?
Free
Hydro-carbons
Total Organic Carbon-TOC
Free Hydro-carbons
Bound Water
Free Water
Clay Fluids
𝐏𝐡𝐢 𝐂𝐥𝐚𝐲
Total Porosity 𝐏𝐡𝐢 𝐭
𝐏𝐡𝐢 𝐞
Four Porosity Components
𝐕 𝐒𝐇
𝐕 𝐦𝐚𝐭𝐫𝐢𝐱
Solids
Effective Porosity
Phie
Non Shale Matrix
Silt
Clay Solids
*Note: Components not to scale

6. Procedures
In the following discussions an example from the Niobrara (Colorado) is used to illustrate procedures

7. Procedures 1 – Standard Shaley Formation Analysis
Shale Matrix
Porosity
Bulk
Fluid
Volumes
Grain
Density
Raw Data
Fluids
Lithology
Pay
RWA
Perm
Core data symbols/heavy line

8. Procedure 2 – Unconventional Reservoir Petrophysical Model
Four Porosity Component Model
The goal is to calculate the four porosity components from the unconventional reservoir model
Effective Porosity Phi e
Total Organic Carbon TOC
Clay Porosity Phi Clay
Free Shale Porosity Phi FS
TOC
Phi Components
Phi e FS
Clay
TOC
Phi e
Clay FS

9. TOC Calculation TOC Passey et al Hot colors indicate increasing TOC
Note Mismatch
Comparison of core TOC (Illustrated by thick black line) with
petrophysically determined TOC
from each porosity log
TOC Passey et al
Responses in Organic – lean intervals
TOC = Total Organic Carbon

10. TOC Calculation TOC Schmoker
Note Mismatch
TOC Schmoker
Schmoker has three different correlations of RhoB with TOC:
High Appalachian correlation
Low Appalachian correlation
Williston Basin Bakken

11. Regular Density/Neutron Cross Plot
Calculations are:
Total porosity Phit
Shale volume VSH
Effective porosity Phie
Matrix volume Vma
Fluid saturation in effective porosity – oil, water, gas
Our preference is to use a density/neutron cross plot for total porosity, to minimize influences of changing matrix and fluid properties

12. Shale Only Density/Neutron Cross Plot
Subtract the non-shale components are:
Effective porosity – account for fluid content
Matrix Volume
Total Organic Carbon – as a volume fraction
Determine porosity from the shale only density/neutron cross plot
Calculate clay porosity as the product of cross plot porosity and 𝑉 𝑆𝐻
The plot can also be used to estimate clay mineral species

13. Free Shale Porosity and Free Available Porosity
Free Shale Porosity = Total Porosity – Effective Porosity – Clay Porosity
Free Available Porosity = Free Shale Porosity + Effective Porosity
Clearly free shale porosity is zero or greater. If negative values are calculated it might be a consequence of incorrect estimates of TOC, an incorrect assumption of TOC density, or an incorrect calculation of shale volume.
Free Shale Porosity
PhiFS
Slight Mismatch

14. Free vs. Adsorbed Hydrocarbons
Free hydrocarbons are located in the free available porosity element, and are calculated using standard approaches
Publications on calculating adsorbed hydrocarbon volumes are sparse. Empirical relations are:
Gas – Published Relation
Adsorbed G.I.P. (SCF) = X Area X Thickness X RhoB X (16 X TOC)
Oil – Suggested Relation
Adsorbed O.I.P. (Bbl) = S2 X X RhoB X h X Area X 7758
S2 = Hydrocarbons generated by thermal cracking

15. Procedure 2 – Unconventional Reservoir Petrophysical Model1 2 3 4 5 6 7 8 9 10 11 12 13 14
Raw Data
Clean Formation
Shale Formation 1
Gr, SP 4
Saturations 7
Porosity Comparison 10
Net Pay – Shale 13 2
Porosity 5
Bulk Volumes 8
Permeability 11
Shale Model 14
TOC Comparison 3
Resistivity 6
Lithology 9
Net Pay – Clean 12
Porosity Comparisons

16. Procedure 3 – Fracture Analysis from Standard Open-Hole Logs
The methodology involves examining rates of change of curve magnitude with depth
Criteria are established by the interpreter for “abnormally rapid” change
If the change to higher porosity is deemed to be too rapid for normal sedimentary processes, then open fractures are suggested
If the change is to lower porosity, closed (healed) fractures are suggested
Results can be compared with image logs, and there is usually quite good comparison with this petrophysical methodology
Calculations involve all available logs
Porosity
Resistivity
Calculated Matrix Curves
Caliper
Density Correction

17. Fracture Analysis Example
Note Fracture concentration in Niobrara C and Ft. Hays
Individual Log Responses
Stacked Data
Pink O = Open Fractures – ? Low stress
Blue C = Closed Fractures – ? High stress

18. Procedure 4 – Relative Permeability Model
Reservoir
𝐒 𝐰 > 𝐒 𝐰𝐢
𝐒 𝐰
Buckles Relation
Phie X S wi =Constant
Holmes Adaptation
Phie Q × S wi =Constant
Slope = Q
𝐒 𝐰𝐢
Reservoir at 𝐒 𝐰𝐢
Solve the Corey relation
S we = S w − S wi 1 − S wi
K rw = S we Water
K rh = 1− S we − S we Hydrocarbons

19. Relative Permeability Example
Oil Well
KEFF = 𝐊 𝐫 ×𝐏𝐞𝐫𝐦
Reservoir Components
Fluid Volume
Relative Permeability
Effective Permeability
𝐒 𝐖 > 𝐒 𝐖𝐢
Pay Flag
Water/Oil Ratio

20. Relative Permeability Example
Gas Well
Low water adjacent to pay
High water adjacent to pay
Reservoir Components
Fluid Volume
Relative Permeability
Effective Permeability
𝐒 𝐖 > 𝐒 𝐖𝐢
Pay Flag
Water/Gas Ratio

21. Procedure 5 – Rock Physics Model and Mechanical Properties – Brittle vs. Ductile
To calculate mechanical properties, the following measurements are required
Acoustic compressional
Acoustic shear
Density
Often acoustic shear is not available but can be estimated from other logs. The example shows pseudo curves based on the Krief geophysical model (Dipole Sonic not run in the Niobrara example).
Dipole Sonic

22. Rock Physics Model and Mechanical Properties
Raw Log DT
DTS/DT
DTS
Density
Neutron

23. Young’s Modulus vs. Poisson’s Ratio
Brittle
Ductile

24. Procedure 6 – Comprehensive Petrophysical Model
A Standard Template is Used for All Examples
Clay Porosity 1.
Fluid Saturation 4.
Permeability 7.
Water/Oil Ratio – Oil Reservoirs
Water Bbl per MMCF – Gas Reservoir
10.
Porosity Types – Phie and shale porosity 2.
Bulk Volume – non shale fraction 5.
Pay Flag – Clean Formation
Yellow = Gross “Sand”
Red = Net “Sand”
Green = Pay 8.
Brittle vs. Ductile
11.
Porosity Types – Free Shale Porosity and TOC 3.
Lithology 6.
Pay Flag – Shale 9.
Fractures

25. Niobrara, Colorado – Oil
Clay Porosity
Niobrara benches are brittle
Very little shale contribution
Niobrara shales are ductile
Variable free shale porosity
Fractures in Niobrara &
Ft. Hays
Fair to good core/log Correlation

26. Bakken, Montana – Oil High free shale porosity Very high TOC
Clay Porosity
High free shale porosity
Very high TOC
Water production from lower Three Forks

27. Barnett, Texas – Shale Gas
Zone 1 – 4 Shale
Higher free shale porosity than zone 5
Shales show variable ductile/brittle responses
Good correlation core/logs

28. Antrim, Michigan – Shale Gas
Pay contribution from most of the shales
Shale shows variable brittle/ductile responses
High TOC and free shale porosity
Fractures sporadic
Good correlation core/logs

29. Western Canada – Shale Gas
Major contribution from shales
Shales are entirely brittle
High values of free shale porosity
Good correlation core/logs

30. Piceance Basin, Colorado – Tight Gas
Clay Porosity
Minor shale contribution
Fractures common
Very low TOC and free shale porosity
Sand intervals are brittle

31. Bakken, North Dakota Oil-in-place in shale: 10.2 MMBO per 640 acres
Clay Porosity
Oil-in-place in shale:
10.2 MMBO
per 640 acres
Carbonate:
9.6 MMBO
High free shale porosity and TOC in both shale intervals

32. New Albany, Illinois
Clay Porosity
Good correlation Core/Log

33. References
Michael Holmes, Antony Holmes, and Dominic Holmes “A Petrophysicial Model to Estimate Free Gas in Organic Shales”, Presented at the AAPG Annual Convention and Exhibition, Houston Texas, April, 2011.
Michael Holmes, Antony Holmes, and Dominic Holmes “A Petrophysical Model for Shale Reservoirs to Distinguish Macro Porosity, Micro Porosity, and TOC”, Presented at the 2012 AAPG ACE, Long Beach, California, April
Holmes, Michael, et al. "Pressure Effects on Porosity-Log Responses Using Rock Physics Modeling: Implications on Geophysical and Engineering Models as Reservoir Pressure Decreases." Prepared for the SPE Annual Technical Conference and Exhibition held in Dallas, Texas, USA, 9-12 October (2005).
Michael Holmes, Antony Holmes, and Dominic Holmes “Petrophysical Rock Physics Modeling: A Comparison of the Krief And Gassmann Equations, and Applications to Verifying And Estimating Compressional And Shear Velocities” presentation at the SPWLA 46th Annual Logging Symposium held in New Orleans, Louisiana, United States, June 26-29, 2005
James W. Schmoker “Use of Formation-Density Logs to Determine Organic-Carbon Content in Devonian Shales of the Western Appalachian Basin and an Additional Example Based on the Bakken Formation of the Williston Basin”, Petroleum Geology of the Black Shale Eastern North America 1989.
Q.R. Passey, S. Creaney, J.B. Kulla, F.J. Moretti, and J.D. Stroud “A Practical Model for Organic Richness from Porosity and Resistivity Logs”, AAPG 1990.