TY - JOUR
T1 - Methane-carbon budget of a ferruginous meromictic lake and implications for marine methane dynamics on early Earth
AU - Akam, Sajjad A.
AU - Chuang, Pei Chuan
AU - Katsev, Sergei
AU - Wittkop, Chad
AU - Chamberlain, Michelle
AU - Dale, Andrew W.
AU - Wallmann, Klaus
AU - Heathcote, Adam J.
AU - Swanner, Elizabeth D.
N1 - Publisher Copyright:
© 2024 The Authors. Gold Open Access: This paper is published under the terms of the CC-BY license
PY - 2024
Y1 - 2024
N2 - The greenhouse gas methane (CH4) contributed to a warm climate that maintained liquid water and sustained Earth’s habitability in the Precambrian despite the faint young sun. The viability of methanogenesis (ME) in ferruginous environments, however, is debated, as iron reduction can potentially outcompete ME as a pathway of organic carbon remineralization (OCR). Here, we document that ME is a dominant OCR process in Brownie Lake, Minnesota (midwestern United States), which is a ferruginous (iron-rich, sulfate-poor) and meromictic (stratified with permanent anoxic bottom waters) system. We report ME accounting for ≥90% and?>9% ± 7% of the anaerobic OCR in the water column and sediments, respectively, and an overall particulate organic carbon loading to CH4 conversion efficiency of ≥18% ± 7% in the anoxic zone of Brownie Lake. Our results, along with previous reports from ferruginous systems, suggest that even under low primary productivity in Precambrian oceans, the efficient conversion of organic carbon would have enabled marine CH4 to play a major role in early Earth’s biogeochemical evolution.
AB - The greenhouse gas methane (CH4) contributed to a warm climate that maintained liquid water and sustained Earth’s habitability in the Precambrian despite the faint young sun. The viability of methanogenesis (ME) in ferruginous environments, however, is debated, as iron reduction can potentially outcompete ME as a pathway of organic carbon remineralization (OCR). Here, we document that ME is a dominant OCR process in Brownie Lake, Minnesota (midwestern United States), which is a ferruginous (iron-rich, sulfate-poor) and meromictic (stratified with permanent anoxic bottom waters) system. We report ME accounting for ≥90% and?>9% ± 7% of the anaerobic OCR in the water column and sediments, respectively, and an overall particulate organic carbon loading to CH4 conversion efficiency of ≥18% ± 7% in the anoxic zone of Brownie Lake. Our results, along with previous reports from ferruginous systems, suggest that even under low primary productivity in Precambrian oceans, the efficient conversion of organic carbon would have enabled marine CH4 to play a major role in early Earth’s biogeochemical evolution.
UR - http://www.scopus.com/inward/record.url?scp=85187105625&partnerID=8YFLogxK
U2 - 10.1130/G51713.1
DO - 10.1130/G51713.1
M3 - 期刊論文
AN - SCOPUS:85187105625
SN - 0091-7613
VL - 52
SP - 187
EP - 192
JO - Geology
JF - Geology
IS - 3
ER -