Methane in the Atmosphere of Western Siberia: Results of Satellite
                     Observations and Simulations

Egor Yu. Mordvin1, Anatoly A. Lagutin1,2; Nikolay V. Volkov1,2, Konstantin M. Makushev1, Anastasia S. Prilipkova1
                                      1 Altai State University, Barnaul, Russia
                     2 Institute of Computational Technologies of SB RAS, Novosibirsk, Russia




              Abstract. In this paper we study the behavior of total methane content in the atmosphere
              of Western Siberia using satellite observations and simulations. The AIRS/AQUA data
              show the increase of the total methane content at rate ~3.3±0.2 ppbv/year for 2003–2018.
              Using the global chemical transport model MOZART4, we analyzed the contributions of
              remote sources to the total methane content in the region’s atmosphere. According to
              climatic models, the average value of methane emissions from bog complexes in Western
              Siberia was established for the period 2000–2013, and projected estimates of emissions
              up to 2050 are obtained.

              Keywords: atmospheric methane, Western Siberia, AIRS/AQUA, remote sources,
              wetland complex.

1       Introduction
    Atmospheric methane is one of the most important greenhouse gases making a significant contribution to climate
change on the Earth. The Intergovernmental Panel on Climate Change 2013 reports that its contribution to radiation
forcing is about 17% [1]. Over the past 270 years, the ratio of methane mixture in the surface layer of the background
atmosphere has increased by about 257% and was about 1860 ppb at the beginning of 2018 [2]. The methane content
increased particularly rapidly in 2014–2017 [3].
    In this regard, the problem of the atmospheric methane monitoring, as well as the implementation of projected
estimates of methane emission are the most important problems.
    The aim of this work is to study the behavior of the total methane content in the atmosphere of Western Siberia
according to satellite observations, as well as to establish methane emission trends up to 2050 using the results of
climate models.

2       Methane content in the atmosphere of Western Siberia
    The total methane content [CH4] in the atmosphere of Western Siberia was estimated using the level 2 research
product of the AIRS/AQUA, as well as the regression method developed by the authors earlier [4]. To optimize the
statistical treatment, we use our “Methane content in the free troposphere of Western Siberia” database [5]. The
analysis of the results was carried out in two zones of the study region: 1 - (65–55ºN, 60–90ºE), 2 - (55–45ºN, 60–
90ºE). The northern zone contains the main natural source of methane in the region - the Great Vasyugan Mire.
    Figure 1 shows the behavior of the total methane content in these two zones obtained using the regression model
for the entire study period of 2003–2018. Dots on the figure refer to the daily mean of methane content averaged over
the zone, and the line refers to moving average for 30 days. It is seen that in the annual cycle of [CH4] in the
atmosphere of Western Siberia there are two maxima: winter (January-February) and summer (July-September) ones.
    The analysis of the total methane content anomalies obtained using the approach [6] and shown in figure 2 allows
us to establish that the increase of [CH4] in 2003–2018 has a trend of ~3.3±0.2 ppb/year.




Copyright © 2019 for this paper by its authors. Use permitted under Creative Commons License Attribution 4.0
International (CC BY 4.0).
Figure 1. Annual cycle and interannual variability of total methane content in the atmosphere of Western Siberia for
                                               zones 1 (a) and 2 (b).




    Figure 2. Anomalies of total methane content in the atmosphere of Western Siberia for zones 1 (a) and 2 (b).


3       The influence of remote sources
    The sensitivity of the total methane content in the atmosphere of Western Siberia to remote sources was estimated
using the MOZART-4 chemical transport model [7]. In the zone of the proposed source, the surface concentration of
methane was increased artificially by 10 times. The MOZART-4 model run was carried out for a simulation period of
3 months, the duration of the emission was one month. The term sensitivity in this study refers to the ratio of the
simulation results within the included remote source and without it. As the remote sources’ zones we selected the
regions in the Western Europe, the South-East Asia, the Eastern coast of North America, the Arabian Peninsula and
the North of South America. Analysis of methane content in the case of spreading out from the remote sources was
performed at atmospheric levels of 300, 500 and 700 hPa.
    Figure 3 shows the sensitivity of total methane content [CH 4] in the atmosphere of Western Siberia during the
summer months obtained from MOZART-4 results for the sources located in Europe, North America and Asia. It is
seen that in the study period the main contribution to [CH4] in the atmosphere of Western Siberia may be due to
sources located primarily in Europe and North America. The maximum sensitivity for these sources is observed on
the 15th and 25th day after the start of emission. Figure 4 shows the area of methane spread from the source in
Western Europe to Western Siberia at the level of 300 hPa.
    Analysis of similar results for other sources showed that methane emissions from Asia and the Arabian Peninsula
could have an impact on the methane content in the upper troposphere of Western Siberia. Such events could occur in
the case of the subtropical and mid-latitude air masses exchange. The sources located in the North of South America
have almost no effect on [CH4] in Western Siberia atmosphere.




  Figure 3. The sensitivity of total methane content [CH4] in the atmosphere of Western Siberia during the summer
 months obtained from MOZART-4 results for the sources located in Europe (solid line), North America (point line)
                                               and Asia (dashed line).




     Figure 4. The sensitivity of the methane content at the level of 300 hPa to the Europe source in June 2007.

4       Methane emissions by wetland complexes
    The modeling of methane emission by wetland complexes in Western Siberia was carried out using the approach
described in [8]. As input data we used the results of the regional climate model RegCM4 [9], the model of heat and
moisture transfer in the soil CLM4.5 [10], and the data from the database [11] containing information on the wetland
ecosystems of Western Siberia. The model was driven by the data of NCEP-DOE Atmospheric Model
Intercomparison Project reanalysis (NCEP-DOE AMIP-II (R-2)) and Hadley Global Environment Model 2 - Earth
System (HadGEM2-ES) within the Representative Concentration Pathway 4.5 (RCP 4.5) and RCP 8.5 radiative
forcing scenarios as initial and lateral boundary conditions.
    Figure 5 shows the results of methane emission simulation for the period 2000–2050. The projected values for the
period 2013–2050 were normalized taking into account the data for the contemporary period 2010–2013.
    As a result of the analysis of the obtained data it was found that the mean value of methane emission by Western
Siberia’s wetland complexes in period 2000–2013 is ~4.34 Tg/year. Methane emission rate of change is almost zero
in this period. The increase of CH4 emissions was found only in the tundra and forest tundra zones. The projected
increase of the methane emissions in 2041–2050 relative to the period 2001–2010 is 0.58 Tg/year with a trend of
0.18±0.06 Tg/10 years for the RCP 8.5 scenario. For the RCP 4.5 scenario the neutral trend of methane emissions was
established. This is due to the fact that the increase of temperature is compensated by a decrease of soil moisture
content.




Figure 5. Methane emission by wetland complexes of Western Siberia for the period 2000–2050. Bold lines are data
 for the modern period; boundary conditions are from NCEP-DOE AMIP-II (R-2) reanalysis. Thin lines - projected
    estimates normalized to the data for contemporary period; boundary conditions according to the global model
                    HadGEM2-ES in the framework of two scenarios: a) RCP 4.5; b) RCP 8.5.

5       Results and conclusions
    The behavior of the total methane content in the atmosphere of Western Siberia was studied. The main results are
as follows.
1. As a result of the analysis of the AIRS/AQUA data, the trend of total methane content in the atmosphere of
    Western Siberia for 2003–2018 ~3.3±0.2 ppb/year was established.
2. It is shown that the total methane content can be contributed to remote sources located primarily in Europe and
    North America.
3. Using the data of regional climate model it was found that in Western Siberia for the period 2000–2013 the mean
    value of methane emission by wetland complexes is ~4.34 Tg/year. The projected increase of methane emission in
    2041–2050 relative to the period 2001–2010 is 0.58 Tg/year with a trend of 0.18±0.06 Tg/10 years for the RCP
    8.5 scenario. For the RCP 4.5 scenario, the increase of emissions is negligible.

References
[1] Stoker T.F., Qin D., Plattner G.-K. et al. (eds.) IPCC 2013. Climate Change 2013: The Physical Science Basis.
    Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate
    Change. Cambridge University Press. Cambridge. United Kingdom and New York. NY. USA, 2013.
[2] WMO. The state of greenhouse gases in the atmosphere based on global observations through 2017. WMO
    greenhouse gas bulletin. No 14, 2018.
[3] Nisbet E.G., Manning M. R., Dlugokencky E.J. et al. Very strong atmospheric methane growth in the 4 years
    2014–2017: Implications for the Paris Agreement // Global Biogeochemical Cycles. 2019. Vol. 33. Pp. 318–342.
[4] Mordvin E.Yu, Lagutin A.A. Methane in the atmosphere of Western Siberia. Monograph. Russia. Barnaul:
    Azbuka, 2016. Pp. 148. ISBN 978-5-93957-893-6 (in Russian).
[5] Mordvin E.Yu, Lagutin A.A. Methane content in the free troposphere of Western Siberia / Federal Service for
    Intellectual Property (Rospatent). Certificate of state registration of the database No. 2014621683 December 5,
    2014 (in Russian).
[6] Shchelkanov N.N. A generalized method for construction of linear regression and its application to the
    development of single-parameter aerosol extinction models. // Atmospheric and Oceanic Optics. 2005. Vol. 18.
    No. 01-02. Pp. 77-81.
[7] Emmons L.K., Walters S., Hess P.G. et al. Description and evaluation of the Model for Ozone and Related
    Chemical Tracers, version 4 (MOZART-4) // Geosci. Model Dev. 2010. Vol. 3. P. 43-67.
[8] Christensen T. R., Cox P. Response of methane emission from arctic tundra to climatic change: Results from a
    model simulation // Tellus. 1995. Vol. 47B. Pp. 301-310.
[9] Giorgi F., Coppola E., Solmon F. et al. RegCM4: Model description and preliminary tests over multiple
    CORDEX domains // Clim. Res. 2012. Vol. 52. Pp. 7-29.
[10]     Lawrence D.M., Oleson K.W., Flanner M.G. et al. Parameterization improvements and functional and
   structural advances in version 4 of the Community Land Model // J. Adv. Model. Earth Sys. 2011. Vol. 3.
   M03001.
[11]    Sheng Y., Smith L.C., MacDonald G.M. et al. A high-resolution GIS-based inventory of the west Siberian
   peat carbon pool // Global Biogeochem. Cycles. 2004. Vol. 18. Pp. GB3004.