Influences of TOC on Pore Structure of Shale from Montney

Formation, West-Central Alberta, Canada

Tianyu Xia

, Zhaohui Xia

, Penghui Su

,Liangchao Qu

,Wei Ding

and Yunpeng Hu

The Middle School Affiliated to Beijing Jiaotong University, Beijing 100044, China;

PetroChina Research Institute of Petroleum Exploration and Development, Beijing 100083, China.

Email: suphui317@163.com

Key words: Tight gas, TOC, pore structure, thermal evolution

Abstract: Shale gas has become one of the key points for the development of unconventional oil and gas. To better

understand the influence factors of TOC in shale from Montney formation, total organic carbon (TOC),

Rock-Eval analysis and saturation measurements were conducted to quantitatively analyze the influence

factors of TOC. The results show that the kerogen type in the study block is gas-prone. Porosity and

permeability have good correlations with TOC for high-maturity samples, demonstrating that organic pores

are well developed in studied shale. The relationship between TOC and T

max

is not obvious in low maturity

samples, whereas the relationship between TOC and T

max

show a negative correlation for the samples with

high maturity. Organic matter begins to transform into hydrocarbon before T

max

reaches a certain level. Gas

saturation increases with the rise of TOC. Bulk density decreases with the increase of TOC. In general, TOC

has a great influence on the pore structure of shale and the hydrocarbon-generating transformation of

kerogen and could well characterize the gas content and thermal evolution of the reservoir.

1 INTRODUCTION

Shale gas is one of the most important types of

unconventional oil and gas resources (Shao et al.

2017; Wei X et al. 2018; Sayed et al. 2017). Shale

gas usually refers to natural gas with low economic

value in low-permeability shale reservoir that have

no natural capacity and can be produced through

large-scale fracturing or special process technologies

(Holditch, 2006; Ji et al. 2016). Shale reservoirs are

mostly distributed in the center of the basin or deep

in the basin structure, showing a large area of

continuous distribution. Permeability, formation

pressure, water saturation and porosity are the most

important evaluation parameters for shale gas (Wang

et al. 2012; Chukwuma et al. 2018; Zou et al. 2012).

In order to form a shale gas sweet spot, the

effective source rock thickness should be greater

than a certain value. TOC is also an important

parameter for the evaluation of shale and the

selection of sweet spots. The development of shale

pores is closely related to the organic matter (Curtis

et al. 2010). Organic matter forms nanoscale pores

in the process of maturation and evolution (Slatt and

O'Brien, 2011; Loucks et al. 2012). The higher the

content of TOC, the larger the specific surface area

of the core (Wang et al. 2015), indicating that

organic carbon is an important factor in controlling

the pore development of the reservoir. The effect of

TOC on the pore structure in shale has been not

fully studied (Milliken et al. 2013; Mastalerz et al.

2013).

The major goals of this article are to understand

the physical properties, thermal evolution, fluid

composition and bulk density of the shale through

various experiments. The relationships between

TOC and pore structures were discussed to

understand the effect of TOC on pore structure. The

relationships between TOC and T

max

, gas saturation

and bulk density were established to explore the

influence factors of TOC. This study are of great

importance for deepening the understanding of TOC

in shale gas reservoirs.

Xia, T., Xia, Z., Su, P., Qu, L., Ding, W. and Hu, Y.

Inﬂuences of TOC on Pore Structure of Shale from Montney Formation, West-Central Alberta, Canada.

In Proceedings of the International Workshop on Environment and Geoscience (IWEG 2018), pages 541-546

ISBN: 978-989-758-342-1

541

Table 1: Pore structure and Geochemical parameters of studied shale samples.

Samples

th Porosit

Permeabilit

Bulk densit

TOC Tmax

Production

Index

Gas Saturation

m % mD

/cc % °C %

1 2139.10 11.32 0.001770 2.62 1.07 370 0.32 0.71

2 2142.00 9.13 0.001060 2.60 1.55 317 0.62 1.54

3 2147.10 6.80 0.000066 2.55 3.25 342 0.58 1.59

4 2148.60 5.67 0.000018 2.60 4.43 351 0.73 2.02

5 2151.00 3.30 0.000012 2.53 3.89 491 0.48 2.14

6 2152.00 2.77 0.000006 2.55 3.57 489 0.42 1.35

7 2154.00 3.21 0.000009 2.56 3.52 490 0.33 1.77

8 2155.80 2.44 0.000008 2.54 3.80 496 0.32 1.48

9 2157.10 3.20 0.000008 2.53 3.03 486 0.49 2.21

10 2157.80 5.09 0.000011 2.52 3.04 319 0.64 3.40

11 2161.80 3.28 0.000027 2.51 5.87 496 0.41 1.99

12 2162.70 2.17 0.000012 2.58 3.18 516 0.61 1.11

13 2165.40 1.45 0.000006 2.64 1.70 506 0.58 0.55

14 2166.60 2.34 0.000007 2.56 5.07 502 0.47 1.03

15 2167.20 3.02 0.000012 2.43 4.35 529 0.65 1.74

16 2168.80 2.45 0.000010 2.71 0.67 370 0.84 0.52

17 2172.10 1.18 0.000001 2.76 0.50 326 0.92 0.39

18 2176.50 2.14 0.000036 2.74 0.90 427 0.66 0.52

19 2182.80 1.81 0.000003 2.75 1.00 571 0.77 0.25

20 2186.60 1.41 0.000006 2.73 1.55 311 0.89 0.26

2 SAMPLES AND METHODS

The Montney Formation is a late Triassic mainly

fine-grained unit, deposited in marine environments,

with a large-scale distribution of the reservoir

bodies. The unit is up to 280 meters thick and the

facies are shaley in the north and west areas, silty in

the center and become coarser (sandy) in western

Alberta. The brittle quartzic content is about 40%,

making it is easy to improve the physical properties

of the reservoir through fracturing.

Routine experiments were performed on 20

samples from Montney formation, west-central

Alberta, Canada. Retort saturation measurements

were performed on core samples. Porosity, grain

density and fluid saturation were calculated from a

representative portion of the crushed sample and the

whole sample was used for bulk density

determination. Rock Eval analysis is a standardized

method for describing the thermal maturities, types

and hydrocarbon generation potential of organic

matter in sedimentary rocks. Saturation

measurements with retort method were conducted

on samples. The parameters obtained in this study

are listed in Table 1.

3 RESULTS AND DISCUSSION

3.1 Effect of TOC on Pore Structure

Parameters

Figure 1: Relationship between porosity and permeability.

The permeability ranges from 0.000001 mD to

0.001770mD, with an average value of 0.000152

mD. The porosity ranges from 1.2 % to 11.7 %, with

IWEG 2018 - International Workshop on Environment and Geoscience

542

an average value of 4.3%. This shale gas reservoir

can be characterized as low porosity, low

permeability and shows strong heterogeneity. The

porosity shows a good exponential relation with the

permeability (Figure 1), with the correlation

coefficient of 0.7842.

The relationship between TOC and organic pores

has been widely studied (Curtis et al. 2012; Chen

and Xiao, 2014), and the effect of TOC on porosity

was not fully studied. The number of organic pores

generally increases with the rise of TOC, whereas

the relationship between TOC and porosity varies in

different sedimentary reservoir (Milliken et al. 2013;

Mathia et al. 2016). Lai found that the pore space is

mainly composed of intergranular pores,

intragranular pores and microfractures in shale from

Kelasu thrust belt (Lai and Wang, 2015). Organic

nanopores and microfractures formed by the

migration of fluid in kerogen are related to the

development of TOC. Figure 2 depicts the

relationship between TOC and porosity. For the

samples with low maturity, the relationship between

TOC and porosity is not obvious, whereas the

relationship between TOC and porosity have a good

positive correlation for the samples with high

maturity. The result demonstrates that the difference

exists in pore types between low-maturity and high-

maturity samples. Organic pores or microfractures

formed by the migration of fluid in kerogen

developed in high-maturity samples, whereas

organic pores are not well developed in low-

maturity samples. Permeability has the similar law

as porosity, as shown in Figure 3. In general, pore

types and their distribution determine the

relationships between TOC and pore structure

parameters.

3.2 Relation between TOC and

Maturity

Maturity of organic matter not only reflects the

conversion of organic matter into oil and gas, but

also characterizes the development of pores in the

reservoir (Chen and Xiao, 2014). The relationship

between maturity of organic matter and pore

structure is complex because thermal evolution will

not only cause changes in the porosity of organic

matter, but also cause the conversion of clay

minerals (Chen and Xiao, 2014).The relationship

between TOC and organic pores and the relationship

between the maturities of thermal evolution have

been widely discussed. However, the relationship

between the maturity of thermal evolution and TOC

was rarely studied. T

max

is an important parameter to

evaluate the maturity of organic matter. Organic

matter begins to transform into hydrocarbon before

max

reaches a certain level. The kerogen of samples

in this study is in a high-mature stage and achieves

high level conversion when T

max

is greater than

450℃ (Figure 4). Figure 4 also shows that the

kerogen type in the study block is gas-prone.

Figure 2: Relationship between TOC and porosity.

Figure 3: Relationship between TOC and permeability.

Inﬂuences of TOC on Pore Structure of Shale from Montney Formation, West-Central Alberta, Canada

543

Figure 4: The determination of kerogen type based on the

correlation between T

max

and PI.

Figure 5: Relationship between TOC and T

max.

Figure 5 shows that for the samples with low

maturity, the relationship between TOC and T

max

not obvious, whereas the relationship between TOC

and T

max

show a weak negative correlation for the

samples with high maturity. Along with the

enhancement of thermal evolution, organic matter

generates hydrocarbons and forms pores, thus the

amount of organic matter decreases, which is the

reason for the decrease of TOC with the rise of T

max

in mature stage. The hydrocarbon generation of

kerogen is related to various factors, such as mineral

composition, kerogen type and compaction (Curtis

et al. 2012). In the immature stage, organic matter is

not converted to hydrocarbon. The abundance of

organic matter is mainly related to the depositional

conditions of the reservoir in the low maturity stage,

which is the reason for the weak correlation between

TOC and T

max

. Therefore, no obvious correlation

exists between TOC and T

max

in immature stage.

3.3 Relation between TOC and Gas

Saturation

The above discussion shows that organic matter

begins to transform into hydrocarbon before T

max

reaches a certain level. In this study, the T

max

some samples is less than 400, and is in the

immature stage. Figure 6 shows that all samples

have gas saturation. The gas in immature samples

may be transported from the mature samples, which

already have more organic matter transformation.

Perhaps because the kerogen type in the study block

is gas-prone and begins to transport into gas at lower

degrees of thermal evolution, which could be

demonstrated by Figure 6. In general, for high-

maturity samples, the gas saturation increases with

the rise of TOC and the enhancement of thermal

evolution. The obvious correlation between TOC

and gas saturation was not depicted in Figure 6 for

low-maturity samples. This further confirms that the

gas in the low-maturity samples was migrated from

the nearby high-maturity samples.

Figure 6: Relationship between TOC and gas saturation.

3.4 Relation between TOC and Density

Milliken found that when the TOC is less than 5.6%,

the porosity shows an increase with increasing TOC

content, while there is a certain negative correlation

between porosity and TOC when the TOC is greater

than 5.6% (Milliken et al. 2013). The inhibitory

effect of high TOC content on organic pores may be

due to mechanical compaction or microcomponents

of non-hydrocarbon generation contained in organic

matter. The high TOC reservoirs have stronger

ductile characteristics and are more susceptible to

compaction under formation conditions. Figure 7

IWEG 2018 - International Workshop on Environment and Geoscience

544

shows that bulk density decreases with the rise of

TOC, indicating that the higher the organic matter

content, the smaller the density of the reservoir.

Higher organic matter content means greater effect

of the compaction on the reservoir, but high organic

matter generally predicts a decrease in density.

Figure 7: Relationship between TOC and bulk density.

4 CONCLUSIONS

In this paper, 20 samples in shale from Montney

formation, west-central Alberta, Canada were

subjected to various experiments to understand the

effect of TOC on pore structure and the influence

factors of TOC. The following conclusions have

been obtained.

• The reservoir in this study is characterized by

low porosity, low permeability and shows

strong heterogeneity. For high-maturity

samples, TOC has a good positive correlation

with porosity and permeability.

• The TOC is affected by thermal evolution,

organic hydrocarbon generation and mineral

composition. When T

max

is greater than a

certain level, thermal evolution will have an

impact on TOC.

• The gas in the low-maturity samples was

migrated from the nearby high-maturity

samples. The gas saturation increases with the

rise of TOC and the enhancement of thermal

evolution for high-maturity samples.

• Bulk density decreases with the rise of TOC,

indicating that the higher the organic matter

content, the smaller the density of the

reservoir.

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