Geological Survey of Denmark and Greenland Bulletin 7, 2004, p 9-12


9

Although it was for many years believed that coals could not
act as source rocks for commercial oil accumulations, it is
today generally accepted that coals can indeed generate and
expel commercial quantities of oil. While hydrocarbon gen-
eration from coals is less well understood than for marine and
lacustrine source rocks, liquid hydrocarbon generation from
coals and coaly source rocks is now known from many parts
of the world, especially in the Australasian region (Mac-
Gregor 1994; Todd et al. 1997). Most of the known large oil
accumulations derived from coaly source rocks have been
generated from Cenozoic coals, such as in the Gippsland
Basin (Australia), the Taranaki Basin (New Zealand), and the
Kutei Basin (Indonesia). Permian and Jurassic coal-sourced
oils are known from, respectively, the Cooper Basin (Au-
stralia) and the Danish North Sea, but in general only minor
quantities of oil appear to be related to coals of Permian and
Jurassic age. In contrast, Carboniferous coals are only associa-
ted with gas, as demonstrated for example by the large gas
deposits in the southern North Sea and The Netherlands.

Overall, the oil generation capacity of coals seems to in-
crease from the Carboniferous to the Cenozoic. This suggests
a relationship to the evolution of more complex higher land
plants through time, such that the highly diversified Ceno-
zoic plant communities in particular have the potential to
produce oil-prone coals. In addition to this overall vegeta-
tional factor, the depositional conditions of the precursor
mires influenced the generation potential. 

The various aspects of oil generation from coals have been
the focus of research at the Geological Survey of Denmark
and Greenland (GEUS) for several years, and recently a
worldwide database consisting of more than 500 coals has
been the subject of a detailed study that aims to describe the
oil window and the generation potential of coals as a function
of coal composition and age.

Depositional conditions

Hydrocarbons are derived from the aliphatic chains in the
organic matrix. The dominant organic matter in conven-
tional marine source rocks (type II kerogen), and also lacus-
trine source rocks (type I kerogen), is formed from algae. This
type of organic matter is geochemically quite uniform and
contains an abundance of long-chain n-alkanes, a prerequi-

site for oil formation. Coals are composed of transformed
higher land plant material (mainly vitrinite or type III kero-
gen) and are compositionally much more heterogeneous and
complex. Compared to algae-derived organic matter, the
organic matter is richer in oxygen and contains fewer long-
chain n-alkanes. Therefore coals inherently have lower oil
generation potential. However, paralic coals that have been
influenced by seawater during deposition may be enriched in
hydrogen (higher H/C ratios; Figs 1, 2; Petersen & Rosen-
berg 1998; Sykes 2001), and incorporation of the hydrogen
into aliphatic chains may increase the generation capacity.

Hydrogen enrichment is related to the activity of sulphate
-reducing bacteria, and is commonly associated with in-
creased contents of sulphur (Fig. 1). In the Søgne Basin
(North Sea), for example, a clear facies-related change in gene-
ration potential is recorded for Middle Jurassic coal source
rocks. The coals were formed on marine-influenced coastal

Geological Survey of Denmark and Greenland Bulletin 7, 9–12 (2005)                              © GEUS, 2005

Oil generation from coal source rocks: the influence of
depositional conditions and stratigraphic age

Henrik I. Petersen

C
e
n
o
zo

ic
Ju

ra
ss

ic
P
e
rm

ia
n

C
ar

b
o
n
if
e
ro

u
s

> 1% sulphur (d.a.f.)

0.5–1% sulphur (d.a.f.)

< 0.5% sulphur (d.a.f.)

0 0.1
0

0.4

0.2

0.8

0.6

1.4
Type I

Type II

Type III

1.2

1

H
/C

 (
at

o
m

ic
 r

at
io

)

O/C (atomic ratio)

0.2 0.3

Fig. 1. The H/C ratio of coals from the major coal-forming geological

periods displayed on the so-called ‘van Krevelen diagram’. Note that

coals with a low sulphur content have a tendency to plot towards the

lower part of the ‘Type III’-band and coals with a higher sulphur con-

tent towards the upper limit of the band. This feature is not related to

coal age; d.a.f., dry ash-free.



plains, and the thickest, most landward parts of the coals gene-
rated gas and condensate (Harald Field and Trym discovery),
whereas the coals that formed close to the palaeo-coastline
generated oil (Lulita Field; e.g. Petersen et al. 2000; Petersen
& Brekke 2001). The influence of depositional conditions on
the generation potential is independent of coal age (Fig. 2;
Petersen in press). The depositional conditions of peat-form-
ing mires may thus help to predict the source rock quality of
the coals.

Generation potential

The evolution of the generation potential (Hydrogen Index =
HI) with increasing maturity is shown in Fig. 2. The major-
ity of the coal samples fall within a band that narrows with
increasing maturity due the gradual homogenisation of the
organic matter. The generation potential is exhausted around
a vitrinite reflectance of 2.0% Ro, but the coals may still pos-
sess a considerable potential (HI up to 190 mg HC/g TOC)
at the end of the conventional oil window at about 1.3% Ro.
A prominent feature of the HI-band is the initial increase in

HI up to a maximum HI-value (e.g. Huc et al. 1986; Sykes
2001; Petersen 2002, in press), defined by the HImax line
between 0.6% Ro and 1.0% Ro. The increase in HI is caused
by the formation of an additional generation potential due to
structural reorganisation of the coal matrix, possibly inclu-
ding incorporation of water-derived hydrogen (Lewan 1997;
Schenk & Horsfield 1998). This means that the ‘true’ genera-
tion potential of coals is equivalent to the HImax, which is
derived by translating the coals along their maturation path-
way to the maximum value (Fig. 2; Sykes & Snowdon 2002).
Coals with an HImax < 150 mg HC/g TOC are considered to
be mainly gas-prone (Fig. 2). Compared to Carboniferous,
Permian and Jurassic coals, Cenozoic coals attain the highest
HImax values (HImax = 250–370 mg HC/g TOC; Petersen in
press). However, the HImax value may not necessarily be an
expression of the ability to generate oil. The type of generated
petroleum is dependent on the chain length of the n-alkanes
in the coal structure. The HI is a measure of the hydrogen in
the coal, but this may not be present as long-chain n-alkanes,
but rather as shorter chains with a potential to form only gas
or condensate. This may particularly be the case for Carboni-
ferous coals.

Coals with approximately similar HI values should theo-
retically contain the same proportion of hydrogen and thus
have potentially the same petroleum generation capacity.
Information about the type of generated petroleum can be
obtained by investigating the chain length of the n-alkanes in
the solid coal structure by Fourier Transform Infrared spec-
trometry (FTIR) and by ruthenium tetroxide catalysed oxi-
dation. The peak at 2850 cm–1 in the FTIR spectrum is used
to estimate the relative proportion of CH2 (dry, ash-free
basis), which is taken as a measure of the proportion of oli-
phatic chains in the coal (Fig. 3). In general, Carboniferous
coals contain a lower proportion of CH2 compared to Ceno-
zoic and Jurassic coals with similar HI values. Similarly, the
proportion of aliphatic hydrogen is lower for Carboniferous
coals (Fig. 3). Cenozoic coals also have significant gas poten-
tial (estimated from the CH3 peak at 2955 cm

–1), which is in
good agreement with the coal-sourced South-East Asian oil
fields, that commonly also contain significant proportions of
gas (e.g. the Kutei Basin, Indonesia). Ruthenium tetroxide
catalysed oxidation of the coal structure essentially ‘chops’ off
the aliphatic chains in the coal matrix, which after appropri-
ate chemical treatment can be analysed by gas chromatogra-
phy - mass spectrometry (GC-MS). By adding an internal
standard the obtained chromatograms can be directly com-
pared.

In general, Carboniferous coals contain low proportions
of n-alkanes with a carbon number > C19, whereas Cenozoic
coals in particular are much richer in long-chain aliphatics.
The difference in the chemical structure between, for exam-

10

Fig. 2. Evolution in the Hydrogen Index (HI) with increasing maturity

shown by 507 coal samples (Petersen in press). Coals with an HI < 150

mg HC/g TOC are considered mainly gas-prone (shaded area). Coals

with increased sulphur contents have a tendency for higher HI values

due to hydrogen-enrichment in the coal-structure. During initial thermal

maturation the HI increases to a maximum value (HImax), which is a bet-

ter estimate of the true generation potential of a coal. The HImax can be

estimated by translating the HI value for a coal along its maturation

pathway to the HImax line (Sykes & Snowdon 2002); for example the coal

with an HI of 185 (blue star) shows a correction of HI by 50 mg HC/g

TOC (HImax = 230 mg HC/g TOC); d.a.f., dry ash-free.

0 0.5 1.51 2 2.5 3

C
e
n
o
zo

ic
Ju

ra
ss

ic
P
e
rm

ia
n

C
ar

b
o
n
if
e
ro

u
s

> 1% sulphur (d.a.f.)

0.5–1% sulphur (d.a.f.)

< 0.5% sulphur (d.a.f.)

500

400

300

200

100

185

235

0

ga
s-

p
ro

n
e

o
il
-p

ro
n
e

H
y
d
ro

ge
n
 I
n
d
e
x
 (

m
g 

H
C

/g
T
O

C
)

Vitrinite reflectance (%Ro)

~0.60%Ro

~1.0%Ro

Line of HImax

H

H



ple, Carboniferous and Cenozoic coals, can be related to the
original coal-forming vegetation, and may explain why
Carboniferous coals are principally gas- or condensate-prone,
whereas Cenozoic coals can be highly oil-prone. In contrast
to the Carboniferous woody, gymnospermous mire vegeta-
tions, the Cenozoic coals were formed from an advanced and
diverse vegetation, which may have produced a more ali-
phatic-rich vitrinitic organic matter upon deposition.

The effective oil window 
(oil expulsion window)

The complex, heterogeneous composition of coals results in
a three-phase oil generation model (Fig. 4; Petersen in press):
(1) onset of hydrocarbon generation, (2) hydrocarbon build-
up in the coal to the expulsion threshold, and (3) oil expul-
sion in the so-called effective oil window. Figure 4 shows the
free hydrocarbons in the coals with increasing maturity. From
0.6–0.7% Ro to 0.85–1.0% Ro, the amount of oil increases
in the coals up to a maximum value, after which it decreases.
This decrease indicates the onset of efficient oil expulsion,
and the maximum BI-value thus corresponds to the start of
the effective oil window (oil expulsion window). The matu-
rity at which oil expulsion starts and the range of the effective
oil window is dependent on the initial generation potential of
the coals (Fig. 4). It should, however, be noted that the effec-
tive oil window for coals extends to higher maturities than
the conventional oil window. Coals generating < 12 mg HC/g

11

Fig. 4. Evolution in Bitumen Index (BI = S1 / TOC) with increasing matu-

rity. Initially, hydrocarbons build up in the coal to a maximum value,

which indicates the start of the effective oil window. Coals with < 12 mg

HC/g TOC (shaded area) are considered to have a limited expulsion

efficiency (gas-prone). In general, Cenozoic coals generate the highest

amounts of hydrocarbons, and they also reach the expulsion threshold

at the lowest maturities as shown by the extension of the expulsion line

down to 0.65% Ro.

(A)

Carb.

(B)

M. Jurassic
(A)

Carb.

(B)

M. Jurassic3000 2950 28502900 2800 2750 cm-1 

Carboniferous coal, Ruhr, Germany

M. Jurassic coal, Danish North Sea

CH2

CH3

Hal/H (wt.%, d.a.f.)

Hal/mg coal (d.a.f.)

2850 cm-1: symmetric CH2

2955 cm-1: asymmetric CH3

H/C = 0.76
HI = 182
0.83%Ro

H/C = 0.79
HI = 205
0.82%Ro

A B C

60

40

20

0

B
it
u
m

e
n
 I
n
d
e
x
 (

m
g 

H
C

/g
T
O

C
)

~0.65%Ro

~0.85%Ro

~1.0%Ro
~1.05%Ro

Gas-prone

0 0.5 1.51 2 2.5 3

Vitrinite reflectance (%Ro)

Start of the effective oil window
(oil expulsion window)

Unknown age
Cenozoic
Jurassic
Permian
Carboniferous

Fig. 3. A: FTIR spectra (aliphatic stretching region) of Carboniferous and Middle Jurassic coals with similar H/C ratios, HI values, and vitrinite

reflectances. The Middle Jurassic coal shows a much higher relative response at 2850 cm–1, which is an indication of a higher proportion of aliphatic

chains in the coal structure. B: Calculated relative proportions of aliphatic chains (CH2) and CH3. C: Calculated relative proportions of aliphatic hydro-

gen. The low values for the Carboniferous coal suggest a primary gas generation potential; d.a.f., dry ash-free.



12

TOC are considered to possess a limited oil expulsion effi-
ciency.

Cenozoic coals generate the largest amounts of hydrocar-
bons and they tend to reach the expulsion threshold at the
lowest maturities (from 0.65% Ro; Fig. 4). The broadest
effective oil window is thus related to Cenozoic coals, and
may extend from approximately 0.65–2.0% Ro. Jurassic,
Permian and Carboniferous coals reach the start of the effec-
tive oil window at higher maturities (0.85–0.9% Ro). The
Jurassic coals show some ability to generate and expel hydro-
carbons, whereas several of the Carboniferous and Permian
coals seem to have a limited expulsion efficiency; these coals
are principally gas-prone. As described above, the organic
matter in Carboniferous coals possesses an inherently low
ability to generate oil. Hence, the effective oil window for the
Carboniferous coals is in reality an effective gas/condensate
window.

Conclusion

Coals can act as source rocks for oil accumulations. The gene-
ration potential is related to the depositional conditions of
the coal-forming mires, with marine influence having a posi-
tive effect by increasing the hydrogen content in the vitrinitic
organic matter. In addition, an overall vegetational control
seems to be exerted on the source rock potential. Carboni-
ferous coals contain lower proportions of long-chain n-alka-
nes and aliphatic hydrogen in the coal matrix than younger
coals. Cenozoic coals generally contain high proportions of
long-chain n-alkanes and possess a high oil generation poten-
tial in addition to a high gas potential. During maturation,
coals form an additional generation potential, and hydrocar-
bon generation can be described as a three-phase process,
including a hydrocarbon build-up phase in the coals before
onset of efficient expulsion. The effective oil window starts at
higher maturities than the conventional oil window, and in
addition extends to higher maturities. Cenozoic coals display
the broadest effective oil window, whereas the effective oil
window for Carboniferous coals is, in reality, an effective
gas/condensate window. This enhanced understanding of oil
generation from coal source rocks is being directly employed
by GEUS in petroleum geological projects that are being car-
ried out, for example, in Vietnam (cf. Nielsen & Abatzis
2004).

Acknowledgement

The Carlsberg Research Foundation (ans-1293 & ans-1293/20) is thanked

for financial support.

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Author’s address

Geological Survey of Denmark and Greenland, Øster Voldgade 10, DK-1350 Copenhagen K, Denmark. E-mail: hip@geus.dk