par Bradley, James J.A.;Arndt, Sandra 
;Amend, Jan J.P.;Burwicz, Ewa;Dale, Andrew W.;Egger, Matthias;LaRowe, Douglas E.
Référence Science advances, 6, 32, page (eaba0697)
Publication Publié, 2020-08
;Amend, Jan J.P.;Burwicz, Ewa;Dale, Andrew W.;Egger, Matthias;LaRowe, Douglas E.Référence Science advances, 6, 32, page (eaba0697)
Publication Publié, 2020-08
Article révisé par les pairs
| Résumé : | Microbial cells buried in subseafloor sediments comprise a substantial portion of Earth's biosphere and control global biogeochemical cycles; however, the rate at which they use energy (i.e., power) is virtually unknown. Here, we quantify organic matter degradation and calculate the power utilization of microbial cells throughout Earth's Quaternary-age subseafloor sediments. Aerobic respiration, sulfate reduction, and methanogenesis mediate 6.9, 64.5, and 28.6% of global subseafloor organic matter degradation, respectively. The total power utilization of the subseafloor sediment biosphere is 37.3 gigawatts, less than 0.1% of the power produced in the marine photic zone. Aerobic heterotrophs use the largest share of global power (54.5%) with a median power utilization of 2.23 × 10-18 watts per cell, while sulfate reducers and methanogens use 1.08 × 10-19 and 1.50 × 10-20 watts per cell, respectively. Most subseafloor cells subsist at energy fluxes lower than have previously been shown to support life, calling into question the power limit to life. |
