Litcius/Paper detail

Characterizing the Atmospheric Mn Cycle and Its Impact on Terrestrial Biogeochemistry

Louis Lu, Longlei Li, Sagar Rathod, Peter Hess, Carmen Enid Martı́nez, Nicole Fernandez, Christine L. Goodale, Janice E. Thies, Michelle Y. Wong, Maria Grazia Alaimo, Paulo Artaxo, Francisco Barraza, África Barreto, David C. S. Beddows, Shankarararman Chellam, Ying Chen, P. Y. Chuang, David D. Cohen, Gaetano Dongarrà, Cassandra J. Gaston, Darío Gómez, Yasser Morera‐Gómez, Hannele Hakola, J. L. Hand, Roy M. Harrison, Philip K. Hopke, Christoph Hueglin, Yuanwen Kuang, Katriina Kyllönen, Fabrice Lambert, Willy Maenhaut, Randall V. Martin, Adina Paytan, Joseph M. Prospero, Yenny González, Sergio Rodrı́guez, Patricia Smichowski, Daniela Varrica, Brenna Walsh, Crystal Weagle, Yihua Xiao, N. M. Mahowald

2024Global Biogeochemical Cycles11 citationsDOIOpen Access PDF

Abstract

Abstract The role of manganese (Mn) in ecosystem carbon (C) biogeochemical cycling is gaining increasing attention. While soil Mn is mainly derived from bedrock, atmospheric deposition could be a major source of Mn to surface soils, with implications for soil C cycling. However, quantification of the atmospheric Mn cycle, which comprises emissions from natural (desert dust, sea salts, volcanoes, primary biogenic particles, and wildfires) and anthropogenic sources (e.g., industrialization and land‐use change due to agriculture), transport, and deposition, remains uncertain. Here, we use compiled emission data sets for each identified source to model and quantify the atmospheric Mn cycle by combining an atmospheric model and in situ atmospheric concentration measurements. We estimated global emissions of atmospheric Mn in aerosols (<10 μm in aerodynamic diameter) to be 1,400 Gg Mn year −1 . Approximately 31% of the emissions come from anthropogenic sources. Deposition of the anthropogenic Mn shortened Mn “pseudo” turnover times in 1‐m‐thick surface soils (ranging from 1,000 to over 10,000,000 years) by 1–2 orders of magnitude in industrialized regions. Such anthropogenic Mn inputs boosted the Mn‐to‐N ratio of the atmospheric deposition in non‐desert dominated regions (between 5 × 10 −5 and 0.02) across industrialized areas, but that was still lower than soil Mn‐to‐N ratio by 1–3 orders of magnitude. Correlation analysis revealed a negative relationship between Mn deposition and topsoil C density across temperate and (sub)tropical forests, consisting with atmospheric Mn deposition enhancing carbon respiration as seen in in situ biogeochemical studies.

Topics & Concepts

BiogeochemistryDeposition (geology)Biogeochemical cycleEnvironmental scienceEnvironmental chemistrySoil waterCarbon cycleAtmospheric sciencesMineral dustPrecipitationCyclingTopsoilEcosystemAerosolSoil scienceChemistryGeologyEcologyOrganic chemistryPhysicsHistorySedimentMeteorologyArchaeologyBiologyPaleontologyHeavy metals in environmentGeochemistry and Elemental AnalysisGeology and Paleoclimatology Research