Climatic influences on active fractions of soil organic matter
Identifieur interne : 003250 ( Main/Exploration ); précédent : 003249; suivant : 003251Climatic influences on active fractions of soil organic matter
Auteurs : A. J. Franzluebbers [États-Unis] ; R. L. Haney [États-Unis] ; C. W. Honeycutt [États-Unis] ; M. A. Arshad [Canada] ; H. H. Schomberg [États-Unis] ; F. M. Hons [États-Unis]Source :
- Soil Biology and Biochemistry [ 0038-0717 ] ; 2001.
Descripteurs français
- Wicri :
- topic : Climat.
English descriptors
- KwdEn :
Abstract
Biologically active fractions of soil organic matter are important in understanding decomposition potential of organic materials, nutrient cycling dynamics, and biophysical manipulation of soil structure. We evaluated the quantitative relationships among potential C and net N mineralization, soil microbial biomass C (SMBC), and soil organic C (SOC) under four contrasting climatic conditions. Mean SOC values were 28±11mgg−1 (n=24) in a frigid–dry region (Alberta/British Columbia), 25±5mgg−1 (n=12) in a frigid–wet region (Maine), 11±4mgg−1 (n=117) in a thermic–dry region (Texas), and 12±5mgg−1 (n=131) in a thermic–wet region (Georgia). Higher mean annual temperature resulted in consistently greater basal soil respiration (1.7 vs 0.8mgCO2–Cg−1 SOC d−1 in the thermic compared with the frigid regions, P<0.001), greater net N mineralization (2.8 vs 1.3mg inorganic Ng−1 SOC 24d−1, P<0.001), and greater SMBC (53 vs 21mg SMBC g−1 SOC, P<0.001). Specific respiratory activity of SMBC was, however, consistently lower in the thermic than in the frigid regions (29 vs 34mgCO2–Cg−1 SMBC d−1, P<0.01). Higher mean annual precipitation resulted in consistently lower basal soil respiration (1.1 vs 1.3mgCO2–Cg−1 SOC d−1 in the wet compared with the dry regions, P<0.01) and lower SMBC (31 vs 43mg SMBCg−1 SOC, P<0.001), but had inconsistent effects on net N mineralization that depended upon temperature regime. Specific respiratory activity of SMBC was consistently greater in the wet than the dry regions (≈33 vs 29mgCO2–Cg−1 SMBC d−1, P<0.01). Although the thermic regions were not able to retain as high a level of SOC as the frigid regions, due likely to high annual decomposition rates, biologically active soil fractions were as high per mass of soil and even 2–3-times greater per unit of SOC in the thermic compared with the frigid regions. These results suggest that macroclimate has a large impact on the portion of soil organic matter that is potentially active, but a relatively small impact on the specific respiratory activity of SMBC.
Url:
DOI: 10.1016/S0038-0717(01)00016-5
Affiliations:
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Le document en format XML
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<front><div type="abstract" xml:lang="en">Biologically active fractions of soil organic matter are important in understanding decomposition potential of organic materials, nutrient cycling dynamics, and biophysical manipulation of soil structure. We evaluated the quantitative relationships among potential C and net N mineralization, soil microbial biomass C (SMBC), and soil organic C (SOC) under four contrasting climatic conditions. Mean SOC values were 28±11mgg−1 (n=24) in a frigid–dry region (Alberta/British Columbia), 25±5mgg−1 (n=12) in a frigid–wet region (Maine), 11±4mgg−1 (n=117) in a thermic–dry region (Texas), and 12±5mgg−1 (n=131) in a thermic–wet region (Georgia). Higher mean annual temperature resulted in consistently greater basal soil respiration (1.7 vs 0.8mgCO2–Cg−1 SOC d−1 in the thermic compared with the frigid regions, P<0.001), greater net N mineralization (2.8 vs 1.3mg inorganic Ng−1 SOC 24d−1, P<0.001), and greater SMBC (53 vs 21mg SMBC g−1 SOC, P<0.001). Specific respiratory activity of SMBC was, however, consistently lower in the thermic than in the frigid regions (29 vs 34mgCO2–Cg−1 SMBC d−1, P<0.01). Higher mean annual precipitation resulted in consistently lower basal soil respiration (1.1 vs 1.3mgCO2–Cg−1 SOC d−1 in the wet compared with the dry regions, P<0.01) and lower SMBC (31 vs 43mg SMBCg−1 SOC, P<0.001), but had inconsistent effects on net N mineralization that depended upon temperature regime. Specific respiratory activity of SMBC was consistently greater in the wet than the dry regions (≈33 vs 29mgCO2–Cg−1 SMBC d−1, P<0.01). Although the thermic regions were not able to retain as high a level of SOC as the frigid regions, due likely to high annual decomposition rates, biologically active soil fractions were as high per mass of soil and even 2–3-times greater per unit of SOC in the thermic compared with the frigid regions. These results suggest that macroclimate has a large impact on the portion of soil organic matter that is potentially active, but a relatively small impact on the specific respiratory activity of SMBC.</div>
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