Abstract
Detection of faults and other zones of weakness in shallow permafrost to a few hundreds of meters is extremely important for ensuring the safety during the production and transportation of fuels (oil and gas). The construction of line facilities (power lines and pipelines) should be preceded by detailed surveys in order to localize major areas of potential hazard. Furthermore, reliable geophysical methods are necessary for exploration of gas hydrates. This research aims at proving that induction-based electromagnetic surveys are applicable for permafrost studies and at finding new evidence for the similarity and difference of the permafrost structure in different regions of Northern Siberia. TEM curves are collected in several regions of Northern Siberia with continuous, mostly continuous, and discontinuous permafrost. Transient electromagnetic (TEM) surveys performed in the Russian Arctic image the permafrost structure to a depth of 500 m. The data are acquired with telemetric systems that allow varying the survey design and loop configuration. Advanced processing tools are used to provide geologically essential information from late-time records, while optimized inversion algorithms are applied to obtain high-quality layered resistivity models. The resulting geoelectric models reveal evident variations in the thickness of highly resistive frozen rocks and the presence of unfrozen patches. The induction surveys, which require no galvanic contact with the earth and no grounding, are inferred to be best suitable for imaging the frozen shallow subsurface. The TEM-based resistivity patterns clearly resolve the permafrost base, as well as the contours of unfrozen zones (taliks), lenses of saline water (cryopegs), gas hydrates, and frost heaving features. The reported results can make basis for the choice of geophysical methods for permafrost studies in such harsh conditions as the Russian Arctic. Furthermore, the presented resistivity patterns can make reference for future studies of permafrost in Northern Siberia.
Highlights
About 50% of all recoverable gas resources in West Siberia reside in seven major oil–gas–condensate fields: Bovanenkovo, Urengoi, Yamburg, Zapolarny, Krusenshtern, Tambei, and Kharasavei [1]
The method is applicable to estimate the depths to permafrost in Arctic areas and to map the permafrost top, as well as to detect faults and other zones of weakness, but the penetration is insufficient to see through the permafrost
direct current (DC) surveys, which have been in use for over one hundred years, measure the electric field on the surface controlled by subsurface resistivity
Summary
The Arctic territories have been increasingly investigated lately, especially for the exploration and production of natural gas and the respective infrastructure projects. The. West Siberian basin is the world largest petroleum province that stores the most voluminous resources of oil and gas in the Novy Port, Bovanenkovo, Urengoi, Yamburg, Zapolarny, Medvezhy, Tambei, and many other fields. The recoverable oil reserves amount to 2524 Mt, as estimated in 167 fields, including. 72 oil, 13 oil and gas, and 82 oil, gas, and condensate fields. The gas reserves, likewise, estimated in 167 fields, including 84 oil, gas, and condensate, 49 gas and condensate, 12 oil and gas, and 22 gas fields, reach 24,587 billion cubic meters. About 50% of all recoverable gas resources in West Siberia reside in seven major oil–gas–condensate fields: Bovanenkovo, Urengoi, Yamburg, Zapolarny, Krusenshtern, Tambei, and Kharasavei [1]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
