Interactive comment on “Methane oxidationpotential of the arctic wetland soils of ataiga-tundra ecotone in northeastern Siberia”by Jun Murase et al.

Abstract. Arctic wetlands are significant sources of atmospheric methane and the observed accelerated climate changes in the arctic could cause the change in methane dynamics, where methane oxidation would be the key process to control methane emission from wetlands. In this study we determined the potential methane oxidation rate of the wetland soils of a taiga-tundra transition zone in northeastern Siberia. Peat soil samples were collected in summer from depressions covered with tussocks of sedges and Sphagnum spp. and from mounds vegetated with moss and larch trees. A bottle incubation experiment demonstrated that the soil samples collected from depressions in the moss- and sedge-dominated zones exhibited active methane oxidation with no time lag. The potential methane oxidation rates at 15 °C ranged from 94 to 496 nmol h−1 g−1 dw. Methane oxidation was observed over the depths studied (0–40 cm) including the water-saturated anoxic layers. The maximum methane oxidation rate was recorded in the layer above the water-saturated layer: the surface (0–2 cm) layer in the sedge-dominated zone and in the middle (4–6 cm) layer in the moss-dominated zone. The methane oxidation rate was temperature-dependent, and the threshold temperature of methane oxidation was estimated to be −4 to −11 °C, which suggested methane oxidation at subzero temperatures. Soil samples collected from the frozen layer of Sphagnum peat also showed immediate methane consumption when incubated at 15 °C. The present results suggest that the methane oxidizing bacteria in the wetland soils keep their potential activities even under anoxic and frozen conditions and immediately utilize methane when the conditions become favorable. On the other hand, the inhibitor of methane oxidation did not affect the methane flux from the sedge and moss zones in situ, which indicated the minor role of plant-associated methane oxidation.

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Methane oxidation potential of the arctic wetland soils of a taiga-tundra ecotone in northeastern Siberia

Soil Science & Plant Nutrition ◽

10.1080/00380768.2020.1786343 ◽

2020 ◽

Vol 66 (4) ◽

pp. 645-652

Author(s):

Jun Murase ◽

Atsuko Sugimoto ◽

Ryo Shingubara ◽

Maochang Liang ◽

Tomoki Morozumi ◽

...

Keyword(s):

Methane Oxidation ◽

Oxidation Potential ◽

The Arctic ◽

Wetland Soils ◽

Northeastern Siberia

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The role of atmospheric dynamics in extreme wildfire activity in northeastern Siberia

10.5194/egusphere-egu21-2006 ◽

2021 ◽

Author(s):

Rebecca Scholten ◽

Coumou Dim ◽

Luo Fei ◽

Sander Veraverbeke

Keyword(s):

Large Scale ◽

Meridional Wind ◽

Atmospheric Dynamics ◽

The Arctic ◽

Burned Area ◽

Fast Fourier Transformation ◽

Arctic Circle ◽

Wave Dynamics ◽

Northeastern Siberia ◽

Fire Activity

In the summer of 2020, extreme fires have raged in northeastern Siberia, many of them within the Arctic Circle burning in ecotonal larch forest and tundra ecosystems. This unprecedented increase in fire activity within the Arctic Circle has been linked to record-high temperatures measured in the region, as well as to high lightning activity.In mid-latitudes, the pronounced and long-lasting heatwaves of the last decade have been linked to amplified Rossby waves connected with weak atmospheric circulation. These amplified waves tend to phase-lock in preferred positions and thereby lead to more persistent summer weather. Linkages between atmospheric teleconnections and boreal wildfires exist for some regions, yet the influence of wave dynamics on arctic-boreal wildfires is unknown. We explored relationships between wave dynamics, heatwaves, and the unprecedented fire activity in Siberia in 2020 to assess whether the recent surge in arctic-boreal fires in Siberia is driven by large-scale atmospheric dynamics.We determined wave amplitudes as phase positions by applying fast Fourier transformation on weekly averaged mid- to high-latitudinal mean meridional wind velocities at the 250 mb level from ERA5 reanalysis data. Gridded percentage area burned between 2001 and 2020 was derived from the Moderate Resolution Imaging Spectrometer (MODIS) Burned Area product (MCD64A1). We then quantified the importance of Rossby wave patterns on fire activity clustered by latitude in eastern Siberia.

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Accurate measurements of atmospheric carbon dioxide and methane mole fractions at the Siberian coastal site Ambarchik

10.5194/amt-2018-325 ◽

2018 ◽

Cited By ~ 1

Author(s):

Friedemann Reum ◽

Mathias Göckede ◽

Jost V. Lavric ◽

Olaf Kolle ◽

Sergey Zimov ◽

...

Keyword(s):

Arctic Ocean ◽

Atmospheric Carbon Dioxide ◽

Monitoring Network ◽

The Arctic ◽

Data Quality Control ◽

In Situ Data ◽

Northeastern Siberia ◽

East Siberian Sea ◽

The Arctic Ocean ◽

Atmospheric Carbon

Abstract. Sparse data coverage in the Arctic hampers our understanding of its carbon cycle dynamics and our predictions of the fate of its vast carbon reservoirs in a changing climate. In this paper, we present accurate measurements of atmospheric CO2 and CH4 dry air mole fractions at the new atmospheric carbon observation station Ambarchik, which closes a large gap in the atmospheric trace gas monitoring network in northeastern Siberia. The site, operational since August 2014, is located near the delta of the Kolyma River at the coast of the Arctic Ocean. Data quality control of CO2 and CH4 measurements includes frequent calibrations traced to WMO scales, employment of a novel water vapor correction, an algorithm to detect influence of local polluters, and meteorological measurements that enable data selection. The available CO2 and CH4 record was characterized in comparison with in situ data from Barrow, Alaska. A footprint analysis reveals that the station is sensitive to signals from the East Siberian Sea, as well as northeast Siberian tundra and taiga regions. This makes data from Ambarchik highly valuable for inverse modeling studies aimed at constraining carbon budgets within the pan-Arctic domain, as well as for regional studies focusing on Siberia and the adjacent shelf areas of the Arctic Ocean.

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Stable Water Isotope Assessment of Tundra Wetland Hydrology as a Potential Source of Arctic Riverine Dissolved Organic Carbon in the Indigirka River Lowland, Northeastern Siberia

Frontiers in Earth Science ◽

10.3389/feart.2021.699365 ◽

2021 ◽

Vol 9 ◽

Author(s):

Shinya Takano ◽

Youhei Yamashita ◽

Shunsuke Tei ◽

Maochang Liang ◽

Ryo Shingubara ◽

...

Keyword(s):

Organic Carbon ◽

Dissolved Organic Carbon ◽

Late Summer ◽

Wetland Hydrology ◽

Temporal Variations ◽

The Arctic ◽

Stable Water Isotopes ◽

River Level ◽

Northeastern Siberia ◽

Doc Concentration

Arctic tundra wetlands may be an important source of dissolved organic carbon (DOC) in Arctic rivers and the Arctic Ocean under global warming. We investigated stable water isotopes and DOC concentration in wetlands, tributaries, and the mainstream at the lower reaches of the Indigirka River in northeastern Siberia during the summers of 2010–2014 to assess the complex hydrology and role of wetlands as sources of riverine DOC. The wetlands had higher values of δ18O and DOC concentration than the tributaries and mainstream of the Indigirka River. A relationship between the two parameters was observed in the wetlands, tributaries, and mainstream, suggesting the wetlands can be a source of DOC for the mainstream through the tributaries. The combined temporal variations in riverine δ18O and DOC concentration indicate the mainstream water flowed into the tributaries during relatively high river-level periods in summer, whereas high DOC water in the downstream wetlands could be discharged to the mainstream through the tributaries during the low river-level periods. A minor fraction (7–13%) of riverine and wetland DOC was degraded during 40 days of dark incubation. Overall, the downstream wetlands potentially provide relatively less biodegradable DOC to the Arctic river and costal ecosystem during the low river-level periods—from late summer to autumn.

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From Living Water to the “Water of Death”: Implicating Social Resilience in Northeastern Siberia

Worldviews Global Religions Culture and Ecology ◽

10.1163/15685357-01702003 ◽

2013 ◽

Vol 17 (2) ◽

pp. 115-124 ◽

Cited By ~ 4

Author(s):

Susan A. Crate

Keyword(s):

Global Climate ◽

Belief System ◽

The Arctic ◽

Social Resilience ◽

The North ◽

Northeastern Siberia ◽

Precipitation Regimes ◽

Cattle Breeders ◽

Local Water ◽

Solid Liquid

Rural inhabitants of the Arctic sustain their way of life via refined adaptations to the extreme climate of the North, and subsequent generations continue to adapt. Viliui Sakha, Turkic-speaking horse and cattle breeders of northeastern Siberia, Russia, have been successful through their ancestral adaptations to local water access, in both a solid and liquid state, at specific times and in specific amounts. Viliui Sakha’s activities to access and utilize water are grounded in a belief system where water is spirit-filled, gives life, and can interplay with death. In the context of contemporary global climate change, water’s solid-liquid balance is disrupted by changing seasonal patterns, altered precipitation regimes, and an overall “softening” of the extreme annual temperature range. Inhabitants are finding ways to adapt but at increasing labor and resource costs. In this paper, I analyze Viliui Sakha’s adaptations to altered water regimes on both the physical and cosmological levels to grasp how water is understood in Sakha’s belief system as the water of life, how it becomes “the water of death,” and the implications for social resilience.

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Application of New Precipitation and Reconstructed Streamflow Products to Streamflow Trend Attribution in Northern Eurasia

Journal of Climate ◽

10.1175/2007jcli1535.1 ◽

2008 ◽

Vol 21 (8) ◽

pp. 1807-1828 ◽

Cited By ~ 71

Author(s):

Jennifer C. Adam ◽

Dennis P. Lettenmaier

Keyword(s):

River Discharge ◽

Low Frequency ◽

The Arctic ◽

Northern Eurasia ◽

Permafrost Degradation ◽

Northeastern Siberia ◽

Physically Based ◽

Streamflow Trends ◽

Precipitation Trends

Abstract River runoff to the Arctic Ocean has increased over the last century, primarily during the winter and spring and primarily from the major Eurasian rivers. Some recent studies have suggested that the additional runoff is due to increased northward transport of atmospheric moisture (and associated increased precipitation), but other studies show inconsistencies in long-term runoff and precipitation trends, perhaps partly due to biases in the observational datasets. Through trend analysis of precipitation, temperature, and streamflow data, the authors investigate the extent to which Eurasian Arctic river discharge changes are attributable to precipitation and temperature changes as well as to reservoir construction and operation between the years of 1936 and 2000. Two new datasets are applied: a gridded precipitation product, in which the low-frequency variability is constrained to match that of long-term bias-corrected precipitation station data, and a reconstructed streamflow product, in which the effects of reservoirs have been minimized using a physically based reservoir model. It is found that reservoir operations have primarily affected streamflow seasonality, increasing winter discharge and decreasing summer discharge. To understand the influences of climate on streamflow changes, the authors hypothesize three cases that would cause precipitation trends to be inconsistent with streamflow trends: first, for the coldest basins in northeastern Siberia, streamflow should be sensitive to warming primarily as a result of the melting of excess ground ice, and for these basins positive streamflow trends may exceed precipitation trends in magnitude; second, evapotranspiration (ET) in the warmer regions of western Siberia and European Russia is sensitive to warming and increased precipitation, therefore observed precipitation trends may exceed streamflow trends; and third, streamflow from the central Siberian basins should respond to both effects. It is found that, in general, these hypotheses hold true. In the coldest basins, streamflow trends diverged from precipitation trends starting in the 1950s to 1960s, and this divergence accelerated thereafter. In the warmest basins, precipitation trends consistently exceeded streamflow trends, suggesting that increased precipitation contributed to increases in both ET and streamflow. In the central basins, permafrost degradation and ET effects appear to be contributing to long-term streamflow trends in varying degrees for each basin. The results herein suggest that the extent and state of the permafrost underlying a basin is a complicating factor in understanding long-term changes in Eurasian Arctic river discharge.

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