What question did this study set out to answer?

This research aims to understand the factors contributing to the surge in atmospheric methane levels after 2019.

February 8, 2026

Why methane surged in the atmosphere during the early 2020s

Key Points

This research aims to understand the factors contributing to the surge in atmospheric methane levels after 2019.
Utilized multiple atmospheric inversions constrained by observational and model-based hydroxyl radical fields.
Analyzed methane atmospheric data to determine growth rates and emission sources.
Examined the role of OH radical levels and wetland emissions in methane variations.
Observed a peak methane growth rate of 16.2 ppb year −1 in 2020 before declining.
83% of variations in methane growth rates were attributed to changes in OH radical levels.
Wetland emissions increased by 8.6 ± 2.6 TgCH4 year −1 from 2019 to 2022 before decreasing by 9.9 ± 3.3 TgCH4 year −1 from 2022 to 2023.

Abstract

The atmospheric methane (CH 4 ) growth rate surged after 2019, peaking at 16.2 parts per billion per year (ppb year −1 ) in 2020 before declining to 8.6 ppb year −1 in 2023. Using multiple atmospheric inversions constrained by observation- and model-based prescribed hydroxyl radical (OH) fields and CH 4 atmospheric data, we show that a drop of OH radicals in 2020–2021, followed by recovery in 2022–2023, accounted for 83% of year-on-year variations in the CH 4 growth rate, the rest being explained by wetland and inland water emissions, which increased between 2019 and 2020–2022 +8.6 ± 2.6 teragrams of CH 4 per year (TgCH 4 year −1 ) and then decreased between 2022 and 2023 (−9.9 ± 3.3 TgCH 4 year −1 ). Most emission changes from 2019 to 2023 occurred in northern tropical wetlands in Africa and Asia, whereas South American wetlands emissions declined and Arctic emissions increased after 2019.

Why methane surged in the atmosphere during the early 2020s

Key Points

Abstract

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