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Wednesday, 13 February 2019

A new Russian paper on methane releases from the Siberian permafrost


Dr.Mann, this is called SCIENCE, not conspiracy theory, even if it is from Putin's Russia.

Of course these are Putin's agents!

Methane in Gas Shows from Boreholes in Epigenetic Permafrost of Siberian Arctic



29 January, 2019


Gleb Kraev 1,2,*  ,



1 . Institute of Physicochemical and Biological Issues in Soil Science of the Russian Academy of Sciences, Pushchino, Moscow Oblast 142290, Russia
2 . Department of Earth Sciences, Vrije University of Amsterdam, 1081 HV Amsterdam, The Netherlands
3 . Department of Microbiology, University of Tennessee, Knoxville, TN 37996, USA
4 . West-Siberian Filial, Trofimuk Institute of Petroleum Geology and Geophysics of Siberian Branch of Russian Academy of Sciences, Tyumen 625026, Russia
5 . Geophysical Institute, University of Alaska Fairbanks, Fairbanks, AK 99775, USA
6.  Industrial University of Tyumen, Tyumen 625000, Russia
7 . Faculty of Biology, Lomonosov Moscow State University, Moscow 119991, Russia
8 . Center of Forest Ecology and Productivity of the Russian Academy of Sciences, Moscow 117234, Russia

*
Author to whom correspondence should be addressed.
Received: 15 October 2018 / Accepted: 24 January 2019 / Published: 29 January 2019

Abstract

: 
The gas shows in the permafrost zone represent a hazard for exploration, form the surface features, and are improperly estimated in the global methane budget. They contain methane of either surficial or deep-Earth origin accumulated earlier in the form of gas or gas hydrates in lithological traps in permafrost. From these traps, it rises through conduits, which have tectonic origin or are associated with permafrost degradation. We report methane fluxes from 20-m to 30-m deep boreholes, which are the artificial conduits for gas from permafrost in Siberia. The dynamics of degassing the traps was studied using static chambers, and compared to the concentration of methane in permafrost as analyzed by the headspace method and gas chromatography. More than 53 g of CH4 could be released to the atmosphere at rates exceeding 9 g of CH4 m−2 s−1from a trap in epigenetic permafrost disconnected from traditional geological sources over a period from a few hours to several days. The amount of methane released from a borehole exceeded the amount of the gas that was enclosed in large volumes of permafrost within a diameter up to 5 meters around the borehole. Such gas shows could be by mistake assumed as permanent gas seeps, which leads to the overestimation of the role of permafrost in global warming.

Keywords:

 fluxes of CH4; epigenetic cryogenesis; cryogenic transport; permeability of permafrost; methane accumulations; methane-hydrates; terrestrial seeps; pingo drilling

1. Introduction


The most recent estimation of the global methane budget includes the following listed sources of methane, in order of decreasing significance: the natural wetlands, geological sources (including oceans), freshwater sources (lakes and rivers), hydrates, and permafrost [1]. Permafrost, with its budget of 1 Tg CH4 yr−1, is the weakest source on this list today, and is considered to be more important in the near future. The thawing of permafrost provides a substrate and creates a favorable environment for the bacterial production of methane in wetlands and lakes [2]. It also provides an input of methane to the carbon cycle from the degradation of gas hydrates, the release of gas from coal beds, traditional gas reservoirs, dispersed or locally accumulated methane in permafrost, and other geological sources [3,4,5]. Geological sources globally emit about 54 (33-75) Tg CH4 yr−1 [1], which is four times less than natural wetlands. However, being mostly point sources, they are usually stronger.


The geological sources in the permafrost zone usually deliver methane to the surface through conduits, ascending from deep horizons through the permeable strata related to faults, taliks, and deposits with a low degree of saturation by ice [6]. The conduits reaching the ground surface and continuously emitting methane are usually referred to as seeps. The capacity and variability of the seeps as assessed by observations both at the local and regional scale fully rely on different land classifications for making larger-scale extrapolations [3,4,7].
Terrestrial seeps in Alaska, which are mostly associated with lakes, create the flux of methane from deep sources as large as 0.2 - 4.5 g CH4 m−2 yr−1 (3.7 g CH4 m−2yr−1 average) of lake surface, and has a strong variation between different sub-regions. About twice as much is emitted from thawing permafrost itself within lake or river-closed taliks [3]. A similar study conducted in northeastern Siberia revealed emissions of 33.7 g CH4 m−2 yr−1 of lake surface and attributed them solely to microbial decomposition in thaw lakes [8]. The latest study from the East Siberian Sea shelf reports the surface emission of 49.1 g CH4 m−2 yr−1 tracked from the sea bottom at a hotspot (area with high density of seeps) of 18,400 km2 [9]. Earlier similar seeps were associated with the decomposition of sub-permafrost gas hydrates due to permafrost degradation on the shelf [4].


When the studies did not rely on the ebullition as a seep indicator, the findings of terrestrial seeps or gas shows were occasional, unless the methane seep resulted in the surficial forms as large as the Yamal crater. The latter is a gas blowout surface feature in continuous permafrost as evidenced by the elevated methane concentration in the air inside the Yamal crater [10], measured after an explosion. That gas accumulation happened through either cryogenic processes [5,11,12], the destabilization of the gas-hydrate layer [13], or ascending deep gases [14].


More often, the methane emits from boreholes causing the ebullition of drilling mud, drill kicks, or even fire [12,13,15]. Reviews of drilling reports documenting the gas shows provided a view on the broad geography of the phenomenon of gas shows from the topmost permafrost horizons in many regions of the Siberian Arctic. The gas shows’ dynamics that have been studied in West Siberia provided data that they originated from methane accumulations at depths between 28–150 m. The emission of methane lasted from a few days to several months, gradually decreasing from the highest initial gas flux rate ranging from about 28 kg CH4 day−1 to 10,000 kg CH4day−1 [12]. Another study reported methane concentrations reaching 77.5% vol. of borehole for several boreholes along the coast and in the shallow shelf of the East Siberian Sea [16].


A borehole acts as a conduit or a chimney, which is similar to natural disturbances or permeable sediments delivering gas from a source or lithological trap to the surface. Previous studies showed that epigenetic permafrost always contains methane in an average concentration of 2.7 mg CH4 m−3 (up to 47.4 g CH4 m−3) of frozen sediment as opposed to syngenetic permafrost, which in most cases did not have any detectable methane [17,18]. High concentrations of methane in permafrost deposits were found in redeposited and refrozen sediments of drained thaw lake basins in Central Yakutia [19], whereas moderate concentrations were detected in loams and the segregation ice of marine deposits on the Yamal Peninsula [20]. Methane in permafrost could be produced at temperatures below zero by methanogenic archaea [21], and it could be converted to interpore gas hydrate [22]. Methane in unfrozen sediments could move for several meters due to the freezing of the sediments via the mechanism of cryogenic transport and become accumulated locally in lithological traps [5,12]. Traps tend to be composed of coarse-grained sediments and have high active porosity [13].


A gas show should not be called a seep unless it has a signature of a deep source [7]. The most common signatures are the concentration of another gas (alkanes, CO2, He, H2, etc.) and the isotopic composition. If methane has δ13C < −60‰, it could be in most cases considered biogenic [23]. However, exceptions are not rare, especially with early mature natural gas [24]. The gas shows with the value of δ13C as low as –87‰, and values from –60‰ to –65‰ were reported for 10 gas-bearing fields in West Siberia at depths below 700 m [25]. The gas from shallower permafrost studied in Russia and Canada, which was both degassed from sediments [17,20] and emitted from accumulations [5,12,26], was mostly biogenic. Methane seeps in Alaska were reported to be thermogenic and of mixed origin [3], which was strongly distinct from the surficial methane sources in closed talik. Recently discovered crater-like methane seep in the Canadian High Arctic constantly emits methane of thermogenic origin [27]. However, the isotopic effects of source depletion and/or the process of oxidation could make the biogenic methane in the specific environment look isotopically thermogenic [23]. So, the isotopic composition alone is not an ultimate indicator, and the complex understanding of environmental conditions of methane formation, migration, accumulation, and degradation are always necessary for genetic interpretations.


Our review above shows that emissions from permafrost and sub-permafrost sources are poorly quantified compared to superficial methane fluxes. This might be the reason for their improper classification, because the physical forms and temporary locations of methane find themselves in the list of natural sources [1]. The gas-hydrates or permafrost could not be listed as separate sources in the methane budget, due to representing the cases of either geological or wetland sources, depending on the genesis of methane. Improper classification reduces the quality of extrapolations and forecasts. We hypothesized that there is a link between the gas shows, gas accumulations, methane hydrates, and dispersed methane in permafrost. In this paper, we attempt to find and explain these links based on our findings of the methane shows in epigenetic permafrost. We also analyze the dynamics of methane emission over time, and discuss the possible sources of methane accumulation and its concentration in the upper 30 m of permafrost on watersheds, lake depressions, and pingos on several sites in the Siberian Arctic.



1 . Institute of Physicochemical and Biological Issues in Soil Science of the Russian Academy of Sciences, Pushchino, Moscow Oblast 142290, Russia
2 . Department of Earth Sciences, Vrije University of Amsterdam, 1081 HV Amsterdam, The Netherlands
3 . Department of Microbiology, University of Tennessee, Knoxville, TN 37996, USA
4. West-Siberian Filial, Trofimuk Institute of Petroleum Geology and Geophysics of Siberian Branch of Russian Academy of Sciences, Tyumen 625026, Russia

5 . Geophysical Institute, University of Alaska Fairbanks, Fairbanks, AK 99775, USA

6 . Industrial University of Tyumen, Tyumen 625000, Russia

7 . Faculty of Biology, Lomonosov Moscow State University, Moscow 119991, Russia

8 . Center of Forest Ecology and Productivity of the Russian Academy of Sciences, Moscow 117234, Russia

*
Author to whom correspondence should be addressed.

Received: 15 October 2018 / Accepted: 24 January 2019 / Published: 29 January 2019

Abstract: 


The gas shows in the permafrost zone represent a hazard for exploration, form the surface features, and are improperly estimated in the global methane budget. They contain methane of either surficial or deep-Earth origin accumulated earlier in the form of gas or gas hydrates in lithological traps in permafrost. From these traps, it rises through conduits, which have tectonic origin or are associated with permafrost degradation. We report methane fluxes from 20-m to 30-m deep boreholes, which are the artificial conduits for gas from permafrost in Siberia. The dynamics of degassing the traps was studied using static chambers, and compared to the concentration of methane in permafrost as analyzed by the headspace method and gas chromatography. More than 53 g of CH4 could be released to the atmosphere at rates exceeding 9 g of CH4 m−2 s−1from a trap in epigenetic permafrost disconnected from traditional geological sources over a period from a few hours to several days. The amount of methane released from a borehole exceeded the amount of the gas that was enclosed in large volumes of permafrost within a diameter up to 5 meters around the borehole. Such gas shows could be by mistake assumed as permanent gas seeps, which leads to the overestimation of the role of permafrost in global warming.
Keywords:

 fluxes of CH4; epigenetic cryogenesis; cryogenic transport; permeability of permafrost; methane accumulations; methane-hydrates; terrestrial seeps; pingo drilling

1. Introduction


The most recent estimation of the global methane budget includes the following listed sources of methane, in order of decreasing significance: the natural wetlands, geological sources (including oceans), freshwater sources (lakes and rivers), hydrates, and permafrost [

1]. Permafrost, with its budget of 1 Tg CH4 yr−1, is the weakest source on this list today, and is considered to be more important in the near future. The thawing of permafrost provides a substrate and creates a favorable environment for the bacterial production of methane in wetlands and lakes [2]. It also provides an input of methane to the carbon cycle from the degradation of gas hydrates, the release of gas from coal beds, traditional gas reservoirs, dispersed or locally accumulated methane in permafrost, and other geological sources [3,4,5]. Geological sources globally emit about 54 (33-75) Tg CH4 yr−1 [1], which is four times less than natural wetlands. However, being mostly point sources, they are usually stronger.

The geological sources in the permafrost zone usually deliver methane to the surface through conduits, ascending from deep horizons through the permeable strata related to faults, taliks, and deposits with a low degree of saturation by ice [

6]. The conduits reaching the ground surface and continuously emitting methane are usually referred to as seeps. The capacity and variability of the seeps as assessed by observations both at the local and regional scale fully rely on different land classifications for making larger-scale extrapolations [3,4,7].

Terrestrial seeps in Alaska, which are mostly associated with lakes, create the flux of methane from deep sources as large as 0.2 - 4.5 g CH4 m−2 yr−1 (3.7 g CH4 m−2yr−1 average) of lake surface, and has a strong variation between different sub-regions. About twice as much is emitted from thawing permafrost itself within lake or river-closed taliks [

3]. A similar study conducted in northeastern Siberia revealed emissions of 33.7 g CH4 m−2 yr−1 of lake surface and attributed them solely to microbial decomposition in thaw lakes [8]. The latest study from the East Siberian Sea shelf reports the surface emission of 49.1 g CH4 m−2 yr−1 tracked from the sea bottom at a hotspot (area with high density of seeps) of 18,400 km2 [9]. Earlier similar seeps were associated with the decomposition of sub-permafrost gas hydrates due to permafrost degradation on the shelf [4].
When the studies did not rely on the ebullition as a seep indicator, the findings of terrestrial seeps or gas shows were occasional, unless the methane seep resulted in the surficial forms as large as the Yamal crater. The latter is a gas blowout surface feature in continuous permafrost as evidenced by the elevated methane concentration in the air inside the Yamal crater [10], measured after an explosion. That gas accumulation happened through either cryogenic processes [5,11,12], the destabilization of the gas-hydrate layer [13], or ascending deep gases [14].


More often, the methane emits from boreholes causing the ebullition of drilling mud, drill kicks, or even fire [

12,13,15]. Reviews of drilling reports documenting the gas shows provided a view on the broad geography of the phenomenon of gas shows from the topmost permafrost horizons in many regions of the Siberian Arctic. The gas shows’ dynamics that have been studied in West Siberia provided data that they originated from methane accumulations at depths between 28–150 m. The emission of methane lasted from a few days to several months, gradually decreasing from the highest initial gas flux rate ranging from about 28 kg CH4 day−1 to 10,000 kg CH4day−1 [12]. Another study reported methane concentrations reaching 77.5% vol. of borehole for several boreholes along the coast and in the shallow shelf of the East Siberian Sea [16].

A borehole acts as a conduit or a chimney, which is similar to natural disturbances or permeable sediments delivering gas from a source or lithological trap to the surface. Previous studies showed that epigenetic permafrost always contains methane in an average concentration of 2.7 mg CH4 m−3 (up to 47.4 g CH4 m−3) of frozen sediment as opposed to syngenetic permafrost, which in most cases did not have any detectable methane [

17,18]. High concentrations of methane in permafrost deposits were found in redeposited and refrozen sediments of drained thaw lake basins in Central Yakutia [19], whereas moderate concentrations were detected in loams and the segregation ice of marine deposits on the Yamal Peninsula [20]. Methane in permafrost could be produced at temperatures below zero by methanogenic archaea [21], and it could be converted to interpore gas hydrate [22]. Methane in unfrozen sediments could move for several meters due to the freezing of the sediments via the mechanism of cryogenic transport and become accumulated locally in lithological traps [5,12]. Traps tend to be composed of coarse-grained sediments and have high active porosity [13].
A gas show should not be called a seep unless it has a signature of a deep source [7]. The most common signatures are the concentration of another gas (alkanes, CO2, He, H2, etc.) and the isotopic composition. If methane has δ13C < −60‰, it could be in most cases considered biogenic [23]. However, exceptions are not rare, especially with early mature natural gas [24]. The gas shows with the value of δ13C as low as –87‰, and values from –60‰ to –65‰ were reported for 10 gas-bearing fields in West Siberia at depths below 700 m [25]. The gas from shallower permafrost studied in Russia and Canada, which was both degassed from sediments [17,20] and emitted from accumulations [5,12,26], was mostly biogenic. Methane seeps in Alaska were reported to be thermogenic and of mixed origin [3], which was strongly distinct from the surficial methane sources in closed talik. Recently discovered crater-like methane seep in the Canadian High Arctic constantly emits methane of thermogenic origin [27]. However, the isotopic effects of source depletion and/or the process of oxidation could make the biogenic methane in the specific environment look isotopically thermogenic [23]. So, the isotopic composition alone is not an ultimate indicator, and the complex understanding of environmental conditions of methane formation, migration, accumulation, and degradation are always necessary for genetic interpretations.

Our review above shows that emissions from permafrost and sub-permafrost sources are poorly quantified compared to superficial methane fluxes. This might be the reason for their improper classification, because the physical forms and temporary locations of methane find themselves in the list of natural sources [

1]. The gas-hydrates or permafrost could not be listed as separate sources in the methane budget, due to representing the cases of either geological or wetland sources, depending on the genesis of methane. Improper classification reduces the quality of extrapolations and forecasts. We hypothesized that there is a link between the gas shows, gas accumulations, methane hydrates, and dispersed methane in permafrost. In this paper, we attempt to find and explain these links based on our findings of the methane shows in epigenetic permafrost. We also analyze the dynamics of methane emission over time, and discuss the possible sources of methane accumulation and its concentration in the upper 30 m of permafrost on watersheds, lake depressions, and pingos on several sites in the Siberian Arctic.



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