Lowland tropical forests remain a methane sink under warming and long-term hurricane disturbance recovery

Gabriele Larocca Conte; Lucia Zuvela; Rachel Cruz-Perez; Tatiana Barreto-Vélez; Nibia Becerra-Santillan; Sophia F. Campbell; Hieu P. Chu; Trung Dam; Iana F. Grullón-Penkova; Miriam Kleit; Deyaneira A. Ortiz-Iglesias; Laura C. Rubio-Lebrón; Molly A. Cavaleri; Sasha C. Reed; Debjani Sihi; Tana E. Wood; Christine S. O'Connell

doi:10.1016/j.agrformet.2026.111225

Lowland tropical forests remain a methane sink under warming and long-term hurricane disturbance recovery

Agricultural and Forest Meteorology

By: Gabriele Larocca Conte, Lucia Zuvela, Rachel Cruz-Perez, Tatiana Barreto-Vélez, Nibia Becerra-Santillan, Sophia F. Campbell, Hieu P. Chu, Trung Dam, Iana F. Grullón-Penkova, Miriam Kleit, Deyaneira A. Ortiz-Iglesias, Laura C. Rubio-Lebrón, Molly A. Cavaleri, Sasha C. Reed, Debjani Sihi, Tana E. Wood, and Christine S. O'Connell

https://doi.org/10.1016/j.agrformet.2026.111225

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Abstract

Methane (CH₄) is a potent greenhouse gas, and tropical forests account for roughly one–third of global atmospheric CH₄ uptake by soils. Projected warming and more frequent hurricanes in these ecosystems may alter soil CH₄ sink strength, as warmer and wetter soils enhance methanogenesis activity. We measured soil CH₄ and CO₂ efflux during the calendar summer months of 2023 and 2024 alongside continuous records of soil moisture, soil and air temperature, and precipitation in an in–situ warming experiment (TRACE) located in a lowland tropical forest in Puerto Rico, six to seven years after Hurricanes Irma and Maria (2017). The realized warming (∼1.95°C) enhanced soil respiration only in summer 2023 (p < 0.05), but net soil CH₄ uptake was invariant in both campaigns (p > 0.05). Instead, sampling day and between–plot variability explained soil CH₄ dynamics much more than treatment contrasts. Importantly, CH₄ uptake was consistently coupled to CO₂ efflux, suggesting tight linkages between methanotrophic and heterotrophic activities. Between treatments, CH₄ and CO₂ responses to soil temperature variation were less sensitive in warmed plots, which may suggest weak metabolic upregulation under elevated temperatures. Together, these findings indicate that lowland tropical soils remain CH₄ sink even under warming and years after hurricane disturbance, with CH₄ dynamics driven more by spatial and temporal variability than experimental warming. Long–term, high–resolution monitoring integrating soil biogeochemistry and microbial processes will be critical to determine whether the observed net CH₄ uptake signal represents a sustainable or transient response under continued warming and disturbance.

Suggested Citation

Larocca Conte, G., Zuvela, L., Cruz-Perez, R., Barreto-Vélez, T., Becerra-Santillan, N., Campbell, S.F., Chu, H.P., Dam, T., Grullón-Penkova, I.F., Kleit, M., Ortiz-Iglesias, D.A., Rubio-Lebrón, L.C., Cavaleri, M.A., Reed, S., Sihi, D., Wood, T.E., and O'Connell, C.S., 2026, Lowland tropical forests remain a methane sink under warming and long-term hurricane disturbance recovery: Agricultural and Forest Meteorology, v. 386, 111225, 19 p., https://doi.org/10.1016/j.agrformet.2026.111225.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Lowland tropical forests remain a methane sink under warming and long-term hurricane disturbance recovery
Series title	Agricultural and Forest Meteorology
DOI	10.1016/j.agrformet.2026.111225
Volume	386
Publication Date	May 23, 2026
Year Published	2026
Language	English
Publisher	Elsevier
Contributing office(s)	Southwest Biological Science Center
Description	111225, 19 p.
Country	United States
Other Geospatial	Puerto Rico, Sabana Field Research Station