欢迎访问《应用生态学报》官方网站,今天是 分享到:

应用生态学报 ›› 2022, Vol. 33 ›› Issue (1): 59-66.doi: 10.13287/j.1001-9332.202201.022

• • 上一篇    下一篇

水分对林地和草地土壤氮初级转化速率的影响

李平1,2, 魏玮1,2, 郎漫1,2*   

  1. 1南京信息工程大学/江苏省农业气象重点实验室, 南京 210044;
    2南京信息工程大学应用气象学院, 南京 210044
  • 收稿日期:2021-04-27 接受日期:2021-10-30 出版日期:2022-01-15 发布日期:2022-07-15
  • 通讯作者: * E-mail: mlang@nuist.edu.cn
  • 作者简介:李 平, 男, 1982年生, 副教授。主要从事土壤氮循环及其生态环境效应、土壤环境化学过程与污染控制研究。E-mail: pli@nuist.edu.cn
  • 基金资助:
    国家自然科学基金项目(41301345,41101284)

Effects of water content on gross nitrogen transformation rates in forest land and grassland soils

LI Ping1,2, WEI Wei1,2, LANG Man1,2*   

  1. 1Nanjing University of Information Science & Technology/Jiangsu Key Laboratory of Agricultural Meteorology, Nanjing 210044, China;
    2School of Applied Meteorology, Nanjing University of Information Science & Technology, Nanjing 210044, China
  • Received:2021-04-27 Accepted:2021-10-30 Online:2022-01-15 Published:2022-07-15

摘要: 水分含量是与土壤氮转化相关微生物活性的重要影响因素。本研究以黑龙江省北安市的草地和林地土壤为对象,通过室内培养试验,利用15N同位素标记技术和FLUAZ数值优化模型研究60%和100%田间持水量(WHC)条件下土壤氮初级矿化速率、初级固定速率、初级硝化速率和初级反硝化速率,以探讨土壤氮初级转化速率对水分含量变化的响应,阐明不同水分条件下土壤中氮的产生、消耗、保存机制及其生态环境效应。结果表明: 土壤水分变化不影响草地和林地土壤氮初级矿化速率和铵态氮固定速率,水分含量由60% WHC增加至100% WHC后显著增加了林地土壤的初级硝化速率,但对草地土壤的初级硝化速率没有显著影响。60% WHC条件下草地和林地土壤的初级反硝化速率可以忽略不计,水分含量增加至100% WHC后土壤初级反硝化速率显著提高,且草地土壤的初级反硝化速率显著低于林地土壤。100% WHC条件下林地土壤初级硝化速率与铵态氮固定速率比值(gn/ia)和N2O排放量均显著高于60% WHC;100% WHC条件下草地土壤的N2O排放量显著高于60% WHC,但两个水分条件下的gn/ia值无显著差异。表明短期内水分含量的增加可能会增加草地和林地土壤氮转化的负面环境效应,且对林地土壤的影响尤为显著。

关键词: 水分含量, 林地, 草地, 15N标记, 氮转化

Abstract: Soil water content is an important factor driving microbial activities related to soil nitrogen (N) transformation. In this study, 15N pair tracing technique combined with the numerical model FLUAZ was used to investigate the gross N mineralization, immobilization, nitrification, and denitrification rates in grassland and forest land soils from Beian City, Heilongjiang Province, China under laboratory condition [60% or 100% water holding capacity (WHC)]. The responses of soil gross N transformation rates to soil water content changes, and the mechanisms of N production, consumption, and conservation in soil under different water conditions and its environmental effects were elucidated. The results showed that changes of soil water content did not affect gross rates of N mineralization and NH4+ immobilization in the forest land and grassland soils. Increasing soil water content from 60% WHC to 100% WHC significantly increased soil gross nitrification rate in forest land soil, but not affect that in grassland soil. Gross denitrification rates in grassland and forest land soils were close to zero under 60% WHC, and significantly increased under 100% WHC. The rate in grassland soil was significantly lower than that in forest land soil. In forest land soil, the ratio of gross nitrification to NH4+ immobilization rates (gn/ia) and N2O emissions under 100% WHC were significantly higher than that under 60% WHC. N2O emission from grassland soil under 100% WHC was significantly higher than that under 60% WHC, but without significant difference in gn/ia between the two water conditions. Our results indicated that increasing soil water content in the short-term may increase the negative environmental effects of nitrogen cycling in grassland and forest land soils, especially in forest land soil.

Key words: water content, forest land, grassland, 15N trace, nitrogen transformation