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uAbstract
uFigure
captions
uIntroduction
uGeology
uProcedures
uResults
uReferences
uAbstract
uFigure
captions
uIntroduction
uGeology
uProcedures
uResults
uReferences
uAbstract
uFigure
captions
uIntroduction
uGeology
uProcedures
uResults
uReferences
uAbstract
uFigure
captions
uIntroduction
uGeology
uProcedures
uResults
uReferences
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Hydrocarbons
generated and trapped beneath the surface seep or leak to the surface in
varying but detectable quantities. These phenomena occur because
processes and mechanisms such as diffusion, effusion, and buoyancy allow
hydrocarbons to escape from reservoirs and migrate to the surface where
they may be retained in the sediments and soils or diffuse into
atmosphere or water columns (Klusman, 1993; Schumacher and Abrams,
1996). Based on these assumptions, various techniques of surface
geochemical prospecting for hydrocarbons have been developed to identify
the surface or near-surface occurrences of hydrocarbons. Surface
geochemical prospecting for hydrocarbons consist of direct and indirect
methods to identify the microseepage. These methods include adsorbed
 soil gas surveys, microbial techniques, soil salts, bitumen, and trace
element techniques, helium emanometry, etc. In order to meet the
challenges of India Hydrocarbon Vision 2025 for Exploration &
Production sector, a National Facility for surface geochemical
prospecting of hydrocarbons has been nucleated at NGRI with a grant from
Oil Industry Development Board (OIDB), New Delhi (Kumar et al., 2002a).
As a part of this National Facility and under its own Research &
Development program, NGRI is carrying-out/planning to carry-out surface
geochemical surveys for hydrocarbon prospecting in the frontier onland/offshore
basins of India. Adsorbed soil gas surveys have been completed in
Vindhyan basin (Chambal Valley) and Kutch onland basin, Gujarat (Kumar
et al., 2002b, 2003), and the work in Saurashtra basin is in progress.
The results of adsorbed soil gas analyses for light gaseous hydrocarbons
in one of the frontier basin (Saurashtra basin) and the future
strategies for geochemical surveys in other frontier basins of India are
discussed.
Saurashtra
basin, Gujarat, consists of mostly Mesozoic and Cenozoic rocks (Biswas,
1983; Merh, 1995), and stratigraphically the sequence begins with
Cretaceous to be followed upward by the Deccan volcanics, Tertiary and
the Quaternary (Figure 1a) The area is largely covered and prominently
exposed by the Deccan Trap (basaltic rocks), whose thickness varies from
few hundreds to thousands of meters. Traps are underlain by thick
Mesozoic sediments (100- 4000 m), which can form potential source rocks.
Deccan Trap volcanicity during Late Cretaceous may have generated the
requisite thermal conditions and acted as a catalyst in Mesozoic
hydrocarbon-generation process. Sedimentation in marine intertonguing
environments is considered to have been favorable phenomena for
hydrocarbon generation and entrapment. The basin is bounded by three
intersecting rift trends, Delhi (NE-SW), Narmada (ENE-WSW) and Dharwar
(NNW-SSE). Integrated geophysical studies show that two of the
sub-basins of Saurashtra, namely Jamnagar and Dwarka, have significant
sediment thicknesses below the Deccan traps and can be considered for
future hydrocarbon research.
Soil
Sampling and Analytical Procedure
Soil
samples from Jamnagar and Dwarka sub basins of Gujarat have been
collected in the depth range of 1.2 – 3.5 m using manual augers. The
soil cores collected were wrapped in aluminum foils and sealed in
poly-metal packs. A total of ~290 soil samples were collected in two
phases of field work. The sample location map of the area is given in
Figure 1b. In the first and second phase the samples were collected in
intervals of 5km and 2 km intervals, respectively, along existing roads.
One
gram of soil sample is reacted in vacuum with orthophosphoric acid to
desorb the soil gases. The CO2 released was trapped in KOH
solution and the light gaseous hydrocarbons are collected by water
displacement in a graduated tube fitted with rubber septa. The volume of
desorbed gases is recorded, and 500 µl of desorbed gas sample is
injected into the Nucon 5765 Gas Chromatograph fitted with ¼"
glass-packed column (squalane), programmable temperature controller, and
flame ionization detector. The GC was calibrated by using an external
standard with known concentrations of methane, ethane, propane, i-butane
and n-butane. The quantitative estimation of light gaseous hydrocarbon
constituents in each sample was made using peak area measurement as a
basis, and the correction for moisture content was applied. The accuracy
of measurement of C1 to C4 components is < 1 ng/g.
The
light gaseous hydrocarbon concentrations (CH4, C2H6,
C3H8, i-C4H10 and n-C4H10)
in soil samples of Jamnagar sub basin vary from 3 to 766, 3 to 261, 9 to
173, 8 to 45 and 5 to 118, in ppb, respectively. The Dwarka sub basin
soils are characterized by C1-C4 concentrations in
the range of 9 to 145, 3 to 130, 2 to 69, 4 to 29 and 6 to 82, in ppb,
respectively. Figure 2 depicts the crossplots between C1-C2,
C1-C3, C2-C3 and C1-ΣC2+,
showing linear correlation. This indicates that the light hydrocarbon
components may have migrated from a thermogenic source, and the effect
of secondary alteration during their seepage toward the surface may be
insignificant. Pixler (1969) proposed a variation diagram using the
ratios of C1/C2 and C1/C3,
etc. to distinguish the non-productive zone from that of oil/gas
producing zone. The discrimination diagram of Pixler for samples of
Jamnagar and Dwarka sub basins in which methane, ethane, and propane
were present suggest that ~70% of these samples fall in the
oil-producing zone and the rest in the gas zone. The concentration of
ΣC2+ is plotted in Figure 3 into three groups (i.e.,
ΣC2+ >100 ppb, ΣC2+
= 50-100 ppb, and ΣC2+ <50 ppb) and
shows that the samples around Jamnagar, Kalavad, and Lalpur are
characterized by higher ΣC2+ values. This suggests that
hydrocarbon generation has taken place in the basin and the area may
prove to be warm for future hydrocarbon exploration. The present
geochemical data support the earlier geological and geophysical
findings.
The
adsorbed soil gas surveys carried out by NGRI for Directorate General of
Hydrocarbons, New Delhi in Vindhyan basin (Chambal Valley) and Kutch
onland basin have also demarcated the warm areas for hydrocarbon
research and exploration. The efforts to conduct detailed geochemical
surveys in other frontier basins of India are in progress.
Biswas,
S.K., and Deshpande, S.V., 1983, Geology and Hydrocarbon Prospects of
Kutch, Saurashtra and Narmada Basins. In: Bhandari, L. L. et al. (Ed.),
Petroliferous Basins of India, pp. 111-126.
Klusman,
R.W., 1993, Soil Gas and Related Methods for Natural Resource
Exploration. John Wiley & Sons, England, 473 pp.
Kumar,
B., Patil, D.J. and Kalpana, G., 2002a, National Facility for studies on
surface geochemical prospecting of hydrocarbons. 9th Annual India Oil
and Gas Review Symposium, 9-10 Sept. 2002, Mumbai, pp. 274-278.
Kumar,
B., Das Sharma, S., Patil, D.J., Sreenivas, B., Raju, S.V., Kalpana, G.,
and Madhavi, M., 2002b, Adsorbed Soil Gas Surveys for Hydrocarbon
Research and Exploration in western part of Vindhyan Basin, Chambal
valley.” Submitted to Directorate General of Hydrocarbons, New Delhi.
Unpubl. Tech Rep. No. NGRI- 2002-Exp-361.
Kumar,
B., Das Sharma, S., Patil, D.J., Sreenivas, B., Raju, S.V., Kalpana, G.,
Panicker, S.K., and Vishnu Vardhan, C., 2003, Adsorbed Soil Gas Surveys
for Hydrocarbon Research and Exploration in parts of Kutch onland basin,
Gujarat. Submitted to Directorate General of Hydrocarbons, New Delhi.
Unpubl. Tech Rep. No. NGRI-2002-Exp-400.
Merh,
S.S., 1995, Geology of Gujarat, Geological Society of India, Bangalore,
222 pp.
Pixler,
B.O., 1969, Formation evaluation by analysis of hydrocarbon ratios.
Journal Petroleum Technology, v. 21, pp. 665-670.
Schumacher,
D., and Abrams, M.A., 1996, Hydrocarbon Migration and its Near Surface
Expression, AAPG Memoir 66, 446 pp.
Sreenivasan,
S., and D.M. Khar, 1995, Frontier basin exploration in India-
Perspectives and challenges. Proceedings of the First International
Conference & Exhibition Petrotech 1995, pp. 1-20.
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