Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta‐analysis and theoretical models
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
[引用][C] Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta-analysis and theoretical models
BG WARING, C AVERILL… - Ecology letters (Print …, 2013 - pascal-francis.inist.fr
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling:
insights from meta-analysis and theoretical models CNRS Inist Pascal-Francis CNRS …
insights from meta-analysis and theoretical models CNRS Inist Pascal-Francis CNRS …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: Insights from meta-analysis and theoretical models
BG Waring, C Averill, CV Hawkes - Ecology letters, 2013 - experts.umn.edu
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta-analysis and theoretical models.
BG Waring, C Averill, CV Hawkes - Ecology Letters, 2013 - europepmc.org
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta-analysis and theoretical models.
BG Waring, C Averill, CV Hawkes - 2013 - cabidigitallibrary.org
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
Differences in fungal and bacterial physiology alter soil C and N cycling: insights from meta-analysis and theoretical models.
BG Waring, C Averill, CV Hawkes - Ecology Letters, 2013 - digitalcommons.usu.edu
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta‐analysis and theoretical models
BG Waring, C Averill, CV Hawkes - Ecology Letters, 2013 - cir.nii.ac.jp
抄録< jats: title> Abstract</jats: title>< jats: p> Since fungi and bacteria are the dominant
decomposers in soil, their distinct physiologies are likely to differentially influence rates of …
decomposers in soil, their distinct physiologies are likely to differentially influence rates of …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta‐analysis and theoretical models
BG Waring, C Averill, CV Hawkes - Ecology Letters, 2013 - infona.pl
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta-analysis and theoretical models
BG Waring, C Averill, CV Hawkes - Ecology Letters, 2013 - hero.epa.gov
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
Differences in fungal and bacterial physiology alter soil carbon and nitrogen cycling: insights from meta‑analysis and theoretical models
BG Waring, C Averill, CV Hawkes - Ecology Letters, 2013 - ui.adsabs.harvard.edu
Since fungi and bacteria are the dominant decomposers in soil, their distinct physiologies
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …
are likely to differentially influence rates of ecosystem carbon (C) and nitrogen (N) cycling …