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Scientific journal publication

Permafrost Region Greenhouse Gas Budgets Suggest a Weak CO2 Sink and CH4 and N2O Sources, But Magnitudes Differ Between Top-Down and Bottom-Up Methods

Hugelius, G.; Ramage, J.; Burke, E.; Chatterjee, A.; Smallman, T.L.; Aalto, T.; Bastos, A.; Biasi, C.; Canadell, J.G.; Chandra, N.; Chevallier, F.; Ciais, P.; Chang, J.; Feng, L.; Jones, M.W.; Kleinen, T.; Kuhn, M.; Lauerwald, R.; Liu, J.; López-Blanco, E.; Luijkx, I.T.; Marushchak, M.E.; Natali, S.M.; Niwa, Y.; Olefeldt, D.; Palmer, P.I.; Patra, P.K.; Peters, W.; Potter, S.; Poulter, B.; Rogers, B.M.; Riley, W.J.; Saunois, M.; Schuur, E.A.G.; Thompson, Rona Louise; Treat, C.; Tsuruta, A.; Turetsky, M.R.; Virkkala, A.-M.; Voigt, C.; Watts, J.; Zhu, Q.; Zheng, B.

Publication details

Journal: Global Biogeochemical Cycles, vol. 38, 2024

Arkiv: hdl.handle.net/11250/3164728
Doi: doi.org/10.1029/2023GB007969

Summary:
Large stocks of soil carbon (C) and nitrogen (N) in northern permafrost soils are vulnerable to remobilization under climate change. However, there are large uncertainties in present-day greenhouse gas (GHG) budgets. We compare bottom-up (data-driven upscaling and process-based models) and top-down (atmospheric inversion models) budgets of carbon dioxide (CO2), methane (CH4) and nitrous oxide (N2O) as well as lateral fluxes of C and N across the region over 2000–2020. Bottom-up approaches estimate higher land-to-atmosphere fluxes for all GHGs. Both bottom-up and top-down approaches show a sink of CO2 in natural ecosystems (bottom-up: −29 (−709, 455), top-down: −587 (−862, −312) Tg CO2-C yr−1) and sources of CH4 (bottom-up: 38 (22, 53), top-down: 15 (11, 18) Tg CH4-C yr−1) and N2O (bottom-up: 0.7 (0.1, 1.3), top-down: 0.09 (−0.19, 0.37) Tg N2O-N yr−1). The combined global warming potential of all three gases (GWP-100) cannot be distinguished from neutral. Over shorter timescales (GWP-20), the region is a net GHG source because CH4 dominates the total forcing. The net CO2 sink in Boreal forests and wetlands is largely offset by fires and inland water CO2 emissions as well as CH4 emissions from wetlands and inland waters, with a smaller contribution from N2O emissions. Priorities for future research include the representation of inland waters in process-based models and the compilation of process-model ensembles for CH4 and N2O. Discrepancies between bottom-up and top-down methods call for analyses of how prior flux ensembles impact inversion budgets, more and well-distributed in situ GHG measurements and improved resolution in upscaling techniques.