TY - JOUR
T1 - Geochemical assessment of hydrocarbon migration phenomena
T2 - Case studies from the south-western margin of the Dead Sea Basin
AU - Sokol, Ella
AU - Kozmenko, Olga
AU - Smirnov, Sergey
AU - Sokol, Ivan
AU - Novikova, Sofya
AU - Tomilenko, Anatoliy
AU - Kokh, Svetlana
AU - Ryazanova, Tatyana
AU - Reutsky, Vadim
AU - Bul'bak, Taras
AU - Vapnik, Yevgeny
AU - Deyak, Michail
N1 - Funding Information: This study has become possible due to joint efforts by many people, besides the authors, and we appreciate their aid greatly. D. Semenova, I. Kupriyanov, Dr. N. Karmanov, and M. Khlestov (IGM SB RAS, Novosibirsk) performed the analytical work; Dr. A. Nefedov (NIOCH SB RAS, Novosibirsk) helped with gas chromatography-mass spectrometry and interpretation of spectra. Trace element abundances were analyzed by Yu. Kolmogorov at the Siberian Synchrotron and Terahertz Radiation Research Center (SSTRC), Budker Institute of Nuclear Physics (Novosibirsk). Thorough and constructive reviews by Zsófia Poros and an anonymous reviewer greatly improved this paper. Thanks are extended to Editor-in-Chief of Journal of Asian Earth Sciences Professor Bor-ming Jahn. We are also thankful to T. Perepelova (IGM SB RAS, Novosibirsk) and to Miss Irene Yao (Journal of Asian Earth Sciences) for cooperation and helpful advice. The study was supported by Grant No. 12-05-90403 from the Russian Foundation for Basic Research , Russia and by Integration Project # 1-2013 SB RAS – NAS of Ukraine, Russia and Ukraine.
PY - 2014/10/15
Y1 - 2014/10/15
N2 - Calcite veins with fluid and solid bitumen inclusions have been discovered in the south-western shoulder of the Dead Sea rift within the Masada-Zohar block, where hydrocarbons exist in small commercial gas fields and non-commercial fields of heavy and light oils. The gas-liquid inclusions in calcite are dominated either by methane or CO2, and aqueous inclusions sometimes bear minor dissolved hydrocarbons. The enclosed flake-like solid bitumen matter is a residue of degraded oil, which may be interpreted as "dead carbon". About 2/3 of this matter is soot-like amorphous carbon and 1/3 consists of n-C8C18 carboxylic acids and traces of n-alkanes, light dicarboxylic acids, and higher molecular weight (>C20) branched and/or cyclic carboxylic acids. Both bitumen and the host calcites show genetic relationship with mature Maastrichtian chalky source rocks (MCSRs) evident in isotopic compositions (δ13C, δ34S, and δ18O) and in REE+Y patterns. The bitumen precursor may have been heavy sulfur-rich oil which was generated during the burial compaction of the MCSR strata within the subsided blocks of the Dead Sea graben. The δ18O and δ13C values and REE+Y signatures in calcites indicate mixing of deep buried fluids equilibrated with post-mature sediments and meteoric waters. The temperatures of fluid generation according to Mg-Li-geothermometer data range from 55°s{cyrillic} to 90°s{cyrillic} corresponding to the 2.5-4.0km depths, and largely overlap with the oil window range (60-90°s{cyrillic}) in the Dead Sea rift (Hunt, 1996; Gvirtzman and Stanislavsky, 2000; Buryakovsky et al., 2005). The bitumen-rich vein calcites originated in the course of Late Cenozoic rifting and related deformation, when tectonic stress triggers damaged small hydrocarbon reservoirs in the area, produced pathways, and caused hydrocarbon-bearing fluids to rise to the subsurface; the fluids filled open fractures and crystallized to calcite with entrapped bitumen. The reported results are in good agreement with the existing views of maturation, migration, and accumulation of hydrocarbons, as well as basin fluid transport processes in the Dead Sea area.
AB - Calcite veins with fluid and solid bitumen inclusions have been discovered in the south-western shoulder of the Dead Sea rift within the Masada-Zohar block, where hydrocarbons exist in small commercial gas fields and non-commercial fields of heavy and light oils. The gas-liquid inclusions in calcite are dominated either by methane or CO2, and aqueous inclusions sometimes bear minor dissolved hydrocarbons. The enclosed flake-like solid bitumen matter is a residue of degraded oil, which may be interpreted as "dead carbon". About 2/3 of this matter is soot-like amorphous carbon and 1/3 consists of n-C8C18 carboxylic acids and traces of n-alkanes, light dicarboxylic acids, and higher molecular weight (>C20) branched and/or cyclic carboxylic acids. Both bitumen and the host calcites show genetic relationship with mature Maastrichtian chalky source rocks (MCSRs) evident in isotopic compositions (δ13C, δ34S, and δ18O) and in REE+Y patterns. The bitumen precursor may have been heavy sulfur-rich oil which was generated during the burial compaction of the MCSR strata within the subsided blocks of the Dead Sea graben. The δ18O and δ13C values and REE+Y signatures in calcites indicate mixing of deep buried fluids equilibrated with post-mature sediments and meteoric waters. The temperatures of fluid generation according to Mg-Li-geothermometer data range from 55°s{cyrillic} to 90°s{cyrillic} corresponding to the 2.5-4.0km depths, and largely overlap with the oil window range (60-90°s{cyrillic}) in the Dead Sea rift (Hunt, 1996; Gvirtzman and Stanislavsky, 2000; Buryakovsky et al., 2005). The bitumen-rich vein calcites originated in the course of Late Cenozoic rifting and related deformation, when tectonic stress triggers damaged small hydrocarbon reservoirs in the area, produced pathways, and caused hydrocarbon-bearing fluids to rise to the subsurface; the fluids filled open fractures and crystallized to calcite with entrapped bitumen. The reported results are in good agreement with the existing views of maturation, migration, and accumulation of hydrocarbons, as well as basin fluid transport processes in the Dead Sea area.
KW - Bitumen-rich calcite veins
KW - Dead Sea Basin
KW - Fluid inclusions
KW - Hydrocarbons
KW - Petroleum migration
KW - Petroleum source rock
UR - http://www.scopus.com/inward/record.url?scp=84907314185&partnerID=8YFLogxK
U2 - https://doi.org/10.1016/j.jseaes.2014.07.023
DO - https://doi.org/10.1016/j.jseaes.2014.07.023
M3 - Article
SN - 1367-9120
VL - 93
SP - 211
EP - 228
JO - Journal of Asian Earth Sciences
JF - Journal of Asian Earth Sciences
ER -