在得克萨斯州半干旱生态区放牧覆盖作物可增加土壤微生物生物量

IF 1.3 Q3 AGRONOMY
Partson Mubvumba, Paul B. DeLaune, Terry J. Gentry
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引用次数: 0

摘要

作物-牲畜综合系统(ICLS)为农业系统带来了多样性,提高了土壤生态系统服务、粮食产量和环境可持续性。半干旱生态区域的资源利用效率实践包括种植小麦(Triticum aestivum L.)以获取粮食和放牧(G)的双系统,以及最近作为小麦双系统的补充,在休耕期间用于喂养土壤和牛的覆盖作物(CC)。后者继续引起人们的兴趣,但有关相关生化循环的信息却很少。我们的目标是评估 CC 和放牧对土壤微生物群结构、多样性、增殖和养分循环的影响。在免耕(NT [NTC])和放牧 CC(NTCG [ICLS])中引入 CC,未放牧 CC(NTC)的 PLFA 总生物量(TPB)增加了 12%,放牧 CC(NTCG [ICLS])增加了 20%;NTC 的细菌总生物量(TBB)增加了 10%,NTCG 增加了 24%;NTC 的真菌总生物量(TFB)增加了 9%,NTCG 增加了 21%。与新界休耕相比,CC 使 NTC 和 NTCG 的革兰氏(-)细菌生物量分别大幅增加了 17% 和 34%;CC 使 NTC 和 NTCG 的革兰氏(+)细菌生物量分别大幅增加了 6% 和 12%;CC 使 NTC 和 NTCG 的丛枝菌根真菌分别大幅增加了 55% 和 89%。采用哈尼土壤健康方法,观察到 NO3--N、NH4+-N、水提取有机氮、全氮和水提取有机碳与 TPB、TBB 和 TFB 存在显著相关性。根据测量参数,土壤健康状况依次为 NTCG > NTC > NT > CT,其中 NT 为免耕,C 为覆盖作物,G 为放牧,CT 为常规耕作。放牧CC比单独放牧CC提高了土壤细菌生物量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Grazing cover crops increases soil microbial biomass in Texas semiarid ecoregion

Grazing cover crops increases soil microbial biomass in Texas semiarid ecoregion

Integrated crop-livestock systems (ICLS) bring diversity to agricultural systems, enhancing soil ecosystem services, food production, and environmental sustainability. Resource utilization efficiency practices under semiarid ecoregions include dual systems that grow wheat (Triticum aestivum L.) for both grain and grazing (G) and recently complementary to wheat dual systems, cover crops (CC) for feeding both the soil and cattle during the fallow period. The latter continues to generate interest and there is a paucity of information on associated biochemical cycles. The objective was to evaluate the impact of CC and grazing thereof on soil microbiota structure, diversity, proliferation, and nutrient cycling. Introducing CC to no-till (NT [NTC]) and grazing CC (NTCG [ICLS]), increased total PLFA biomass (TPB) for ungrazed CC (NTC) by 12%, and grazed CC (NTCG [ICLS]) by 20%; total bacteria biomass (TBB) by 10% for NTC and 24% for NTCG; total fungal biomass (TFB) by 9% for NTC and 21% for NTCG. The CC significantly increased Gram (−) bacteria biomass by 17% and 34% for NTC and NTCG, respectively; the CC significantly increased Gram (+) bacteria biomass by 6% and 12% for NTC and NTCG, respectively; and the CC significantly increased arbuscular mycorrhizal fungi by 55% and 89% for NTC and NTCG respectively, compared to NT fallow practice. Significant correlations were observed for NO3–N, NH4+–N, water-extractable organic nitrogen, total nitrogen, and water-extractable organic carbon with TPB, TBB, and TFB using Haney soil health methods. Based on the measured parameters, the soil health status decreased in the order NTCG > NTC > NT > CT, where NT is the no-till, C is the cover crop, G is the grazing, and CT is the conventional-till. Grazing CC enhanced soil bacterial biomass over CC in solitude.

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来源期刊
Agrosystems, Geosciences & Environment
Agrosystems, Geosciences & Environment Agricultural and Biological Sciences-Agricultural and Biological Sciences (miscellaneous)
CiteScore
2.60
自引率
0.00%
发文量
80
审稿时长
24 weeks
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