粪肥铜锌残留对土壤N<sub>2</sub>O排放及其关联因子的影响

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摘要为探究不同pH值农田土壤对猪粪中典型重金属(Cu, Zn)残留的响应,采用酸(pH值为5.81),中(pH值为7.18),碱(pH值为8.00)3种菜地土壤,分别设置不添加猪粪(CK),等氮添加有机猪粪(M)以及集约化养殖业产出的高Cu, Zn残留猪粪(MP)3种处理,干湿交替预培养至猪粪中易利用底物基本耗尽后追加尿素,以进一步分析MP中残留有效Cu、Zn对N₂O排放及其相关因子的影响.结果表明,不同pH值土壤N₂O排放对添加MP响应不同,MP在酸性和碱性土壤中显著抑制N₂O排放,在中性土壤中则显著促进N₂O排放(P<0.05).与有效Cu, Zn显著相关的产N₂O底物和微生物因子在不同土壤中存在一定差异.逐步回归分析表明酸性土壤N₂O排放的主要驱动因子为NH₄⁺-N转化量,有效Zn含量和18S rRNA丰度,碱性土壤N₂O排放仅受NO₃^--N生成量驱动,而中性土壤N₂O排放的主要驱动因子则为有效Cu.相对于M处理,MP中残留有效Cu与nirS丰度显著负相关(P<0.05),与AOB amoA丰度强正相关(n=3, r>0.95),其作用在酸性土壤中最强;残留有效Zn则与nosZ(P<0.05), 18S rRNA(P<0.1), AOA amoA(P<0.1)以及16S rRNA(n=3, r>0.95)丰度正相关,且其在中性土壤中促进作用最强; MP残留有效Cu, Zn对碱性土壤中N₂O排放相关微生物基因的作用整体表现为抑制效应.因此,集约化养殖业粪肥如需还田可优先考虑碱性土壤以降低其负面环境生态效应.

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关键词 ：菜地土壤, Cu, Zn, 猪粪, N₂O排放

Abstract：To explore the responses of different pH soils to Cu and Zn residues in the swine manure from intensive animal husbandry, three vegetable-planted soils with the acidic (pH 5.81), neutral (pH 7.18) and alkaline (pH 8.00) were used to treat with an addition of zero manure (CK), organic manure (M) and polluted manure (MP), respectively. All treatments were incubated for half year under the alternation of dry and wet conditions to exhaust the available carbon and nitrogen from the manure. After that, urea was added to each treatment to examine effects of residual Cu and Zn on N₂O emissions and its related factors. The results show that N₂O emissions from different pH soils had different responses to MP addition. MP significantly reduced N₂O emissions from acidic and alkaline soils, while significantly increased N₂O emissions from neutral soil (P<0.05). There were some differences in N₂O-producing substrates and microbial factors significantly related to available Cu and Zn in different soils. Further stepwise regression analysis showed that the main drivers of N₂O emissions from acidic soil were NH₄⁺-N conversion amount, available Zn content and 18S rRNA abundance. N₂O emissions from alkaline soil were decided by NO₃^--N production level only, while the main driver of N₂O emissions from neutral soil was the available Cu content. Relative to M treatment, residual available Cu in MP was significantly negatively correlated to the nirS abundance (P<0.05), while positively associated with AOB amoA abundance (n=3, r>0.95); the residual Cu had the greatest role in acidic soil compared to other soils. The residual Zn was positively correlated with nosZ(P<0.05), 18S rRNA(P<0.1), AOA amoA (P<0.1), and 16S rRNA abundance (n=3, r>0.95), and had the largest promoting effect in neutral soil. Evidently, the effective Cu and Zn residues in MP have an overall inhibitory effect on N₂O emission-related microbial genes in alkaline soil. Therefore, alkaline soil should be given priority to reduce the negative environmental and ecological effects of manure in intensive aquaculture if the manure is required to return to the field.

Key words： vegetable soil copper zinc swine manure N₂O emission

收稿日期: 2022-09-23

PACS:

X53

基金资助:国家自然科学基金资助项目(41675148);“十四五”国家重点研发专项(2022YFD1901603)

通讯作者: 蒋静艳,副教授,lilacjjy@njau.edu.cn E-mail: lilacjjy@njau.edu.cn

作者简介: 张婷(1997-),女,江苏连云港人,南京农业大学硕士研究生,主要研究方向为环境污染与全球变化.发表论文3篇.71179987@qq.com

引用本文:

张婷, 蒋晶晶, 冯廉洁, 蒋静艳. 粪肥铜锌残留对土壤N₂O排放及其关联因子的影响[J]. 中国环境科学, 2023, 43(6): 3013-3022. ZHANG Ting, JIANG Jing-jing, FENG Lian-jie, JIANG Jing-yan. Effects of Copper and Zinc residues in swine manure on soil N₂O emissions and related factors. CHINA ENVIRONMENTAL SCIENCECE, 2023, 43(6): 3013-3022.

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http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2023/V43/I6/3013

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