Szczegóły publikacji

Opis bibliograficzny

Increasing diurnal and seasonal amplitude of atmospheric methane mole fraction in Central Siberia between 2010-2021 / Dieu Anh Tran, Jordi Vilà-Guerau de Arellano, Ingrid T. Luijkx, Christoph Gerbig, Michał GAŁKOWSKI, Santiago Botía, Kim Faassen, Sönke Zaehle // Atmospheric Chemistry and Physics ; ISSN  1680-7316 . — 2025 — vol. 25 iss. 22, s. 16553–16588. — Bibliogr. s. 16583–16588, Abstr. — M. Gałkowski - dod. afiliacja: Biogeochemical Signal Department, Max Planck Institute for Biogeochemistry, Jena, Germany

Autorzy (8)

  • Tran Dieu Anh
  • Vilà-Guerau de Arellano Jordi
  • Luijkx Ingrid T.
  • Gerbig Christoph
  • AGHGałkowski Michał
  • Botía Santiago
  • Faassen Kim
  • Zaehle Sönke

Dane bibliometryczne

ID BaDAP164941
Data dodania do BaDAP2026-01-07
Tekst źródłowyURL
DOI10.5194/acp-25-16553-2025
Rok publikacji2025
Typ publikacjiartykuł w czasopiśmie
Otwarty dostęptak
Creative Commons
Czasopismo/seriaAtmospheric Chemistry and Physics

Abstract

Siberia's vast wetlands, permafrost, and boreal forests are significant, but their sources of methane (CH4) are poorly quantified. Using vertical CH4 profiles and meteorological data from the ZOtino Tall Tower Observatory (ZOTTO; 60°48′ N, 89°21′ E) in Central Siberia, we analyse long-term trends in CH4 growth rates, seasonal patterns, and diurnal cycles from 2010 to 2021. Our results show a persistent long-term trend in CH4 mole fractions and an insignificant increasing seasonal cycle amplitude, (2.12 ppbyr-1, p=0.12) along with a pronounced late-summer CH4 peak. Diurnal analysis reveals a growing late summer (July-October) CH4 amplitude over the analysed decade (5.29 ppbyr-1, p=0.001), driven by rising nighttime fluxes correlated with late summer soil temperature (R2=line0.65, p<0.01), soil moisture ( R2=0.36, p=0.032) and with preceding spring snow depth ( R2=0.54, p=0.03). Notably high nighttime CH4 fluxes occurred in 2012 and 2019 mainly due to wildfires. These findings suggest that increasing late-summer CH4 emissions, primarily from wetlands to the west and southwest of ZOTTO, dominantly contribute to the overall CH4 rise. Our study underscores the importance of continuous, high-frequency greenhouse gas observations for accurately quantifying regional CH4 trends.

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