黑土区水稻土有机氮组分及其对可矿化氮的贡献
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国家自然科学基金项目(41571280,41101276)和国家重点基础研究发展计划(“973”)项目(2011CB100500)资助


Soil Organic Nitrogen Components and their Contributions to Mineralizable Nitrogen in Paddy Soil of the Black Soil Region
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Supported by the National Natural Science Foundation of China (Nos. 41571280 and 41101276 ) and the National Basic Research Program of China (973 Program) (No. 2011CB100500)

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    摘要:

    采用Bremner法和长期淹水密闭培养法,研究了黑土区不同有机碳水平水稻土有机氮组分及其与可矿化氮的关系。结果表明,土壤酸解氮含量大于非酸解氮。土壤酸解各组分氮含量及其占全氮比例大小的顺序相同,即均为未知态氮 > 氨基酸态氮 > 氨态氮 > 氨基糖态氮。土壤氮素矿化潜力(N 0)为38 ~ 175.3 mg kg-1,矿化速率常数(k 0)为0.022 ~ 0.041 d-1。土壤有机碳、全氮含量与氮矿化潜力(N 0)之间均呈显著正相关(p < 0.01或p < 0.05);土壤C/N、pH与氮素矿化潜力(N 0)之间均呈显著正相关(p < 0.01),而与矿化速率常数(k 0)之间则均呈显著负相关(p < 0.05或p < 0.01),因此,土壤有机碳(氮)、C/N和pH是影响土壤有机氮素矿化的重要因素。相关分析表明,在各组分有机氮中,酸解氨态氮、酸解氨基酸态氮和非酸解氮均与氮矿化势(N 0)关系密切(p < 0.01),但进一步通过多元回归分析和通径分析表明,酸解氨态氮是对可矿化氮具有直接重要贡献的组分,是土壤可矿化氮的主要来源。

    Abstract:

    The black soil region (122° ~ 132°E, 43° ~ 50°N) in Northeast China is the most important grain production region of the country. The paddy soil derived from black soil after long-term rice cultivation has become an important paddy soil resource in Northeast China. As the region is cold in weather with the soil kept frozen for a long time period each year, and the paddy soil has only a short period of time in a year remaining waterlogged, it is essential to elucidate nitrogen-mineralization capability and N supply capacity of the black soil derived paddy soil. For that end, soil investigations were carried out and soil samples collected in paddy fields in Qing’an County of Suihua, Central Heilongjiang in 2011. The soil samples were treated with the Bremner method and long-term waterlogged incubation method and analyzed for composition of soil organic nitrogen and mineralizable N in the paddy soil and relationship between the two relative to organic carbon content. Results showed that acidolyzable N and non-acidolyzable N in the soil varied in the range of 1 014 ~ 1 834 mg kg-1 and 378 ~ 851 mg kg-1, and averaged 383 mg kg-1 and 633 mg kg-1, respectively. The former accounted for 64.9% ~ 72.9% or 68.9% on average of the total N; and the latter did for 27.1% ~ 35.1% or 31.1% on average, Obviously, the former was much higher than the latter in both content and proportion to the total. Soil acidolysable N was significantly and positively related to organic carbon and total N (p<0.01) in content, with correlation coefficient being 0.985 and 0.985, respectively, and soil non-acidolyzable N (p<0.01) was too, with correlation coefficient being 0.981 and 0.977, respectively. In terms of content and the proportion of total N, components of the soil acidolyzable organic nitrogen followed an order of unknown N > amino acid N > ammonia N > amino sugar N. The content of acidolzsable ammonia N was significantly and positively related to organic carbon and total N (p < 0.01), with correlation coefficient being 0.987 and 0.973, respectively, and acidolyzable amino acid N was too, with correlation coefficient being 0.991 and 0.989, respectively, but the fraction of unknown acidolyzable N was significantly positive related to total N (p< 0.05) only, with correlation coefficient being 0.880. After 161 days of waterlogging incubation, cumulative NH4 -N in the soil reached close to the maximum, ranging between 38.7 and 176.1 mg kg-1, with an average being 99.3 mg kg-1 and cumulative mineralized nitrogen content was in an extremely significant positive relationship with soil organic carbon (r = 0.975, p< 0.01), and a significantly positive relationship with total nitrogen (r = 0.957, p< 0.05), too. Nitrogen mineralization potential (N 0) varied in the range of 38 ~175.3 mg kg-1, and the mineralization rate constant (k 0) in the range of 0.022~0.041 d-1. Nitrogen mineralization potential (N0) was ultra-significantly and positively related to the cumulative NH4 -N content , soil organic carbon and total N after 161 days of incubation, with correlation coefficient being 0.999, 0.978 and 0.962, respectively. Both soil C/N and pH were significantly and positively related to nitrogen mineralization potential (N 0) (p < 0.01), but negatively to mineralization rate constant (k 0) (p < 0.05 or p< 0.01). Obviously, soil organic carbon (N), C/N and pH are important factors that affect soil organic nitrogen mineralization. Among the components of soil organic nitrogen, acidolyzable ammonia N and acidolyzable amino N and non-acidolyzable N were significantly and positively related to N mineralization potential (N 0) (p < 0.01), with correlation coefficient being 0.999, 0.986 and 0.999,respectively, but stepwise multiple regressions of the three with N mineralization potential shows that acidolyzable ammonia N was the largest contributor of mineralizable nitrogen. Path analysis further indicates that acidolyzable ammonia N and mineralizable nitrogen has a very high path coefficient (1.142), but acidolyzable amino acid N and non-acidolyzable-N a very low direct path coefficient, being 0.024 and 0.172, respectively. The findings suggest that acidolyzable ammonia N is a component that has important direct contribution to mineralizable nitrogen and hence the major source of soil mineralizable nitrogen.

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丛耀辉,张玉玲,张玉龙,虞 娜,邹洪涛,范庆锋,王 展.黑土区水稻土有机氮组分及其对可矿化氮的贡献[J].土壤学报,2016,53(2):457-467. DOI:10.11766/trxb201508220362 CONG Yaohui, ZHANG Yuling, ZHANG Yulong, YU Na, ZOU Hongtao, FAN Qingfen, WANG Zhan. Soil Organic Nitrogen Components and their Contributions to Mineralizable Nitrogen in Paddy Soil of the Black Soil Region[J]. Acta Pedologica Sinica,2016,53(2):457-467.

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  • 收稿日期:2015-08-02
  • 最后修改日期:2015-11-16
  • 录用日期:2015-11-23
  • 在线发布日期: 2015-12-15
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