SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4283740323> ?p ?o ?g. }

Showing items 1 to 100 of ±159 with 100 items per page.

W4283740323 endingPage "108770" @default.
W4283740323 startingPage "108770" @default.
W4283740323 abstract "Microbial carbon use efficiency (CUE), a combination of respiration and growth, plays a central role in the flow of carbon through soil. Carbon-depleted agricultural soils are promoted as a global sink for atmospheric carbon in a warming climate. There is an urgent need to understand whether increased soil respiration from warmed cropland soils reduces CUE, potentially creating positive feedback to atmospheric CO 2 concentrations. We investigated microbial CUE and turnover rates in response to experimental warming in topsoils under traditional tillage and conservation tillage management using a substrate-independent H 2 18 O labeling method. Eleven years of warming increased soil organic carbon (SOC) by 3.9% in topsoil under conservation tillage, while there was no change in traditional tilled soils. Soil microbial respiration was increased by 108% and 11.6% under traditional tillage and conservation tillage, respectively. Warming decreased microbial growth by 60.3% in traditional tilled topsoils, but increased it by 50.8% under conservation tillage. Therefore, CUE and microbial turnover rates decreased by 77% and 22.2%, respectively, in response to warming in traditional tilled topsoils and increased by 29.1% and 19.3%, respectively, under conservation tillage. Soil hydrolase (β-glucosidase, cellobiohydrolase and N -acetyl-glucosaminidase) activities were increased by warming under both management types, but oxidase (peroxidase and phenol oxidase) activities only increased in traditional tilled topsoils. Hydrolase:oxidase ratios were 4.1 times less in warmed traditional tilled soils compared to unwarmed traditional tilled soils but were 0.63 times more in warmed conservation tillage soils compared with unwarmed conservation tillage soils. Microbial CUE was positively correlated with dissolved organic carbon (DOC), DOC:SOC and hydrolase:oxidase, suggesting that substrate quality and availability were important factors driving changes in microbial physiology. The SOC increased with microbial growth, CUE and turnover rate. Our findings suggest that microorganisms in warmed topsoils under conservation tillage use a greater abundance of high-quality substrates more efficiently to build biomass, thereby reducing the positive feedback effect of increased soil respiration caused by soil warming. • Warming increased surface SOC by 3.9% under conservational tillage practice. • Warming increased microbial respiration by 108% and 12% under traditional and conservational tillage. • Warming increased microbial growth under conservational tillage, but decreased it under traditional tillage. • Warming increased hydrolase and oxidase activities under traditional tillage. • Microbial growth, CUE and turnover rate were higher under increased SOC." @default.
W4283740323 created "2022-07-02" @default.
W4283740323 creator A5022443309 @default.
W4283740323 creator A5023602095 @default.
W4283740323 creator A5041917108 @default.
W4283740323 creator A5065644535 @default.
W4283740323 creator A5076632678 @default.
W4283740323 creator A5077614139 @default.
W4283740323 creator A5078371530 @default.
W4283740323 creator A5087876899 @default.
W4283740323 date "2022-09-01" @default.
W4283740323 modified "2023-10-10" @default.
W4283740323 title "Long-term warming increased microbial carbon use efficiency and turnover rate under conservation tillage system" @default.
W4283740323 cites W1685833191 @default.
W4283740323 cites W1966466516 @default.
W4283740323 cites W1969069662 @default.
W4283740323 cites W1982209547 @default.
W4283740323 cites W1991704630 @default.
W4283740323 cites W1996387110 @default.
W4283740323 cites W1996692331 @default.
W4283740323 cites W2004320529 @default.
W4283740323 cites W2005420405 @default.
W4283740323 cites W2008549202 @default.
W4283740323 cites W2021191590 @default.
W4283740323 cites W2024643793 @default.
W4283740323 cites W2036538049 @default.
W4283740323 cites W2038770226 @default.
W4283740323 cites W2041230234 @default.
W4283740323 cites W2041641720 @default.
W4283740323 cites W2048732522 @default.
W4283740323 cites W2062977246 @default.
W4283740323 cites W2068412297 @default.
W4283740323 cites W2076090463 @default.
W4283740323 cites W2083857556 @default.
W4283740323 cites W2087474788 @default.
W4283740323 cites W2088457941 @default.
W4283740323 cites W2099990000 @default.
W4283740323 cites W2104971425 @default.
W4283740323 cites W2106986958 @default.
W4283740323 cites W2109521731 @default.
W4283740323 cites W2109937711 @default.
W4283740323 cites W2121954992 @default.
W4283740323 cites W2128002424 @default.
W4283740323 cites W2128837721 @default.
W4283740323 cites W2131406020 @default.
W4283740323 cites W2132949254 @default.
W4283740323 cites W2136596893 @default.
W4283740323 cites W2151500527 @default.
W4283740323 cites W2152405429 @default.
W4283740323 cites W2152923831 @default.
W4283740323 cites W2153339784 @default.
W4283740323 cites W2158287690 @default.
W4283740323 cites W2158535548 @default.
W4283740323 cites W2167450434 @default.
W4283740323 cites W2255365831 @default.
W4283740323 cites W2269882445 @default.
W4283740323 cites W2550788627 @default.
W4283740323 cites W2752703078 @default.
W4283740323 cites W2768220725 @default.
W4283740323 cites W2791618585 @default.
W4283740323 cites W2794098862 @default.
W4283740323 cites W2799909914 @default.
W4283740323 cites W2803483287 @default.
W4283740323 cites W2806579811 @default.
W4283740323 cites W2808506779 @default.
W4283740323 cites W2838558308 @default.
W4283740323 cites W2846603545 @default.
W4283740323 cites W2883898014 @default.
W4283740323 cites W2883907336 @default.
W4283740323 cites W2892334539 @default.
W4283740323 cites W2896080895 @default.
W4283740323 cites W2897830120 @default.
W4283740323 cites W2901529854 @default.
W4283740323 cites W2923222284 @default.
W4283740323 cites W2949913736 @default.
W4283740323 cites W2968761745 @default.
W4283740323 cites W2972308172 @default.
W4283740323 cites W2978355872 @default.
W4283740323 cites W3000834351 @default.
W4283740323 cites W3011738444 @default.
W4283740323 cites W3015951166 @default.
W4283740323 cites W3048696433 @default.
W4283740323 cites W3093740010 @default.
W4283740323 cites W3095638759 @default.
W4283740323 cites W3117177726 @default.
W4283740323 cites W3126190909 @default.
W4283740323 cites W3128189971 @default.
W4283740323 cites W3174481629 @default.
W4283740323 cites W3208386427 @default.
W4283740323 cites W3214258685 @default.
W4283740323 cites W4221041604 @default.
W4283740323 doi "https://doi.org/10.1016/j.soilbio.2022.108770" @default.
W4283740323 hasPublicationYear "2022" @default.
W4283740323 type Work @default.
W4283740323 citedByCount "7" @default.
W4283740323 countsByYear W42837403232023 @default.
W4283740323 crossrefType "journal-article" @default.
W4283740323 hasAuthorship W4283740323A5022443309 @default.