Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance
M Bornemann, I Bussmann, L Tichy… - FEMS microbiology …, 2016 - academic.oup.com
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
[引用][C] Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake …
M Bornemann, I Bussmann, L Tichy… - FEMS Microbiology …, 2016 - cir.nii.ac.jp
Methane release from sediment seeps to the atmosphere is counteracted by highly active
Methylococcaceae in the water column of deep oligotrophic Lake Constance | CiNii Research …
Methylococcaceae in the water column of deep oligotrophic Lake Constance | CiNii Research …
Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance …
M Bornemann, I Bussmann, L Tichy… - FEMS Microbiology …, 2016 - europepmc.org
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance
M Bornemann, I Bussmann, L Tichy… - FEMS Microbiology …, 2016 - search.proquest.com
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance
M Bornemann, I Bussmann, L Tichy… - FEMS …, 2016 - pubmed.ncbi.nlm.nih.gov
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
[引用][C] Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake …
M Bornemann, I Bussmann, L Tichy… - FEMS Microbiology …, 2016 - ui.adsabs.harvard.edu
Methane release from sediment seeps to the atmosphere is counteracted by highly active
Methylococcaceae in the water column of deep oligotrophic Lake Constance - NASA/ADS Now …
Methylococcaceae in the water column of deep oligotrophic Lake Constance - NASA/ADS Now …
Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance
M Bornemann, I Bussmann, L Tichy… - FEMS Microbiology …, 2016 - hero.epa.gov
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance
M Bornemann, I Bussmann, L Tichy… - FEMS Microbiology …, 2016 - epic.awi.de
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
Methane release from sediment seeps to the atmosphere is counteracted by highly active Methylococcaceae in the water column of deep oligotrophic Lake Constance
M Bornemann, I Bussmann, L Tichy, JS Deutzmann… - 2016 - kops.uni-konstanz.de
Methane emissions from freshwater environments contribute substantially to global warming
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …
but are under strong control of aerobic methane-oxidizing bacteria. Recently discovered …