This study examined the effect of carbon (C), nitrogen (N), and wetting cycle gradients within soil aggregates on microbial communities and populations. New methods of bacterial extractions and identification were developed for this study. Direct microscopic counts of bacterial populations were 35% higher in moist than air dry aggregates. Bacterial populations from contrasting management systems and soil types were native forest on silt loam soils > conventional-till on silt loam soils ≅ native grassland on loam soils > conventional-till planted to continuous alfalfa on sandy loam soils. A 17% and 32% increase in populations occurred in the interior regions of aggregates exposed to 3 and 6 W/D cycles. Populations in the exterior regions increased 23% with 3 W/D cycles and decreased 29% with 6 W/D cycles. A decrease in polar tensile strength was observed in aggregates exposed to 6 W/D cycles. This decrease in strength may be caused by decreased populations in the exterior regions, leading to fewer microbial by-products produced and lower aggregate strength. C and N concentrations and other factors appear to contribute to bacterial populations. Direct relationships exist between aggregate stability, porosity, and bacterial populations. As greater energy sources are available to soil bacterial populations, those populations increase in biovolume and density. This increase in size and population leads to greater bacterial by-products that in turn lead to increased aggregate formation and stabilization.
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机译:这项研究检查了土壤中的碳(C),氮(N)和湿循环梯度对微生物群落和种群的影响。为这项研究开发了新的细菌提取和鉴定方法。细菌种群的直接显微计数在潮湿状态下比在空气中干燥的聚集体高35%。来自不同管理系统和土壤类型的细菌种群为粉壤土土壤上的原始森林>粉壤土土壤上的常规耕种≅壤土土壤上的天然草地>砂壤土上种植成连续紫花苜蓿的常规耕种。暴露于3和6 W / D周期的骨料内部区域的种群数量分别增长了17%和32%。 3 W / D周期,外部区域的人口增加了23%,而6 W / D周期则减少了29%。在暴露于6 W / D循环的骨料中,观察到极性拉伸强度降低。强度的下降可能是由于外部区域的种群减少所致,导致产生的微生物副产物更少,聚集强度更低。碳和氮的浓度及其他因素似乎有助于细菌种群。聚集体的稳定性,孔隙率和细菌数量之间存在直接关系。随着更多的能源可用于土壤细菌种群,这些种群的生物量和密度都会增加。大小和种群的增加导致更多的细菌副产物,进而导致聚集体形成和稳定性增加。
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