Manure application rather than plastic-film uncovering to sustainably alleviate plastic-greenhouse soil nitrate surplus and salinity in Yangtze River Delta

IF 5.9 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-03-21 DOI:10.1016/j.agwat.2025.109437

Ying Tang, Xiao Ma, Yun Zhao, Yang Li, Xuehong Ma, Xiong Cao, Xin Zhao, Jinlong Dong

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引用次数: 0

Abstract

Despite leading global plastic-greenhouse production using soil culture, China’s low-to-medium-tech practices exacerbate soil nitrate surplus and salinity, deteriorating local environments. However, it remains uncertain how to sustain soil nitrate to achieve high production without environment penalty. This study conducted a field survey of plastic-greenhouse farms in Yangtze River Delta, and collected 107 questionnaires and 535 soil samples to comprehensively assess current status and remediation strategies of soil salinity. 40.5 %, and 68.2 % of soil samples exceeded the critical level of soil nitrate and electrical conductivity (EC) while nitrate and EC with or without Asparagus cultivation were median of 999 and 136 mg N kg−1, and 2809 and 659 µS cm−1, respectively, demonstrating severe nitrate surplus and salinity. Structural equation and random forest model demonstrated that soil salinity was related to greater inorganic nitrogen but lower manure input. Greenhouse uncovering decreased soil nitrate from 154 to 103 mg N kg−1 by 33.2 %, and soil EC from 706 to 562 µS cm−1 by 20.5 % but threatening surface water body. More manures decreased the ratio of soil nitrate-N to total N, and increased soil C/N counteracting the nitrate surplus in grape-cultivated soils. This study therefore recommends subsidizing manure applications in the cultivation of low-value crops and promoting the cultivation of high-value horticultural crops. This approach aims to prevent nutrient leaching caused by the removal of plastic film, thereby achieving the sustainable use of plastic greenhouse soils.

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尽管中国利用土壤栽培技术进行塑料大棚生产在全球处于领先地位，但中低端技术做法加剧了土壤硝酸盐过剩和盐碱化，使当地环境恶化。然而，如何维持土壤硝酸盐以实现高产而不破坏环境仍是一个未知数。本研究对长三角地区的塑料大棚农场进行了实地调查，收集了 107 份问卷和 535 份土壤样本，全面评估了土壤盐渍化的现状和修复策略。40.5%和68.2%的土壤样品的土壤硝酸盐和导电率（EC）超过临界值，而种植芦笋或未种植芦笋的土壤硝酸盐和导电率的中位数分别为999和136 mg N kg-1，2809和659 µS cm-1，表明土壤硝酸盐过剩和盐渍化严重。结构方程和随机森林模型表明，土壤盐渍化与无机氮的增加和粪肥的减少有关。揭开温室后，土壤硝酸盐从 154 mg N kg-1 降至 103 mg N kg-1，降幅为 33.2%，土壤导电率从 706 µS cm-1 降至 562 µS cm-1，降幅为 20.5%，但对地表水体造成了威胁。更多的粪肥降低了土壤硝态氮与全氮的比率，增加了土壤碳/氮，抵消了葡萄种植土壤中硝酸盐的过剩。因此，本研究建议补贴低价值作物的施肥量，促进高价值园艺作物的种植。这种方法旨在防止因去除塑料薄膜而造成的养分流失，从而实现塑料大棚土壤的可持续利用。

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来源期刊

Agricultural Water Management 农林科学-农艺学

CiteScore

12.10

自引率

14.90%

发文量

648

审稿时长

4.9 months

期刊介绍： Agricultural Water Management publishes papers of international significance relating to the science, economics, and policy of agricultural water management. In all cases, manuscripts must address implications and provide insight regarding agricultural water management.