Alternate partial root-zone irrigation coupled with biochar amendment improves water use efficiency of cotton plants by modulating hydraulic and chemical signals under salinity stress

IF 5.6 1区农林科学 Q1 AGRICULTURAL ENGINEERING

Industrial Crops and Products Pub Date : 2025-05-14 DOI:10.1016/j.indcrop.2025.121206

Jingxiang Hou , Zhijun Zhang , Kehao Liang , Yiting Chen , Zhenhua Wei , Risheng Ding , Fulai Liu

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引用次数: 0

Abstract

Alternate partial root-zone irrigation (APRI) coupled with biochar application can alleviate salt stress effects while improving crop water use efficiency (WUE). However, the ecophysiological mechanisms by which APRI coupled with biochar amendment affecting cotton plant growth and WUE under salt stress remains elusive. A split-root pot experiments were done in 2020 and 2021, and both direct (2020) and residual (2021) effects of biochar were investigated. The experimental design included three factors: biochar addition (without biochar (NBC), wheat stover biochar (WSB), and softwood biochar (WB)), and irrigation mode (adequate irrigation (AI), traditional deficit irrigation (TDI), and APRI), and salinity level (0 and 200 mM sodium chloride). The results indicated that salinity and reduced irrigation reduced gas exchange rates, stomatal size, leaf water potential and seed cotton yield, but increased leaf ABA concentration and intrinsic water use efficiency (WUE_n). In both years, biochar application attenuated the adverse effects of salinity stress and improved the physiological characteristics of cotton plants, though in 2021 biochar reduced stomatal size, stomatal density, leaf ABA concentration, maximum stomatal conductance, seed cotton yield, WUE_n, and yield-level water use efficiency (WUE_s) compared to 2020. APRI coupled with WSB resulted in the highest WUE_s in both years. Structural equation model analysis indicated that leaf water potential and ABA indirectly affected WUE_n and WUE_s by altering stomatal traits. Stomatal conductance had a negative direct effect on WUE_n, whereas stomatal density had a positive direct effect on WUE_s. Considering the direct and residual effects of biochar, the APRI coupled with WSB is a promising strategy for increasing WUE and alleviating salinity stress in cotton plants.

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部分根区交替灌溉配以生物炭改良剂通过调节盐胁迫下棉花的水力和化学信号，提高了棉花的水分利用效率

部分根区交替灌溉（APRI）配施生物炭可以缓解盐胁迫效应，提高作物水分利用效率（WUE）。然而，盐胁迫下APRI和生物炭对棉花生长和水分利用效率影响的生理生态机制尚不明确。在2020年和2021年进行了分根罐试验，研究了生物炭的直接效应（2020年）和残留效应（2021年）。试验设计包括3个因素：生物炭添加量（无生物炭（NBC）、麦秸生物炭（WSB）和软木生物炭（WB））、灌溉方式（充分灌溉（AI）、传统亏缺灌溉（TDI）和APRI）和盐度水平（0和200 mM氯化钠）。结果表明，盐度和减少灌溉降低了气体交换速率、气孔大小、叶片水势和籽棉产量，但提高了叶片ABA浓度和内在水分利用效率（WUEn）。与2020年相比，生物炭在2021年降低了棉花的气孔大小、气孔密度、叶片ABA浓度、最大气孔导度、籽棉产量、WUEn和产量水平水分利用效率（wue），但在这两年中，施用生物炭减轻了盐胁迫的不利影响，改善了棉花的生理特性。APRI和WSB在这两年中产生了最高的wue。结构方程模型分析表明，叶片水势和ABA通过改变气孔性状间接影响水分平衡和水分利用效率。气孔导度对水分利用效率的直接影响为负，气孔密度对水分利用效率的直接影响为正。考虑到生物炭的直接效应和残留效应，APRI与WSB相结合是提高棉花水分利用效率和缓解盐胁迫的一种很有前景的策略。

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来源期刊

Industrial Crops and Products 农林科学-农业工程

CiteScore

9.50

自引率

8.50%

发文量

1518

审稿时长

43 days

期刊介绍： Industrial Crops and Products is an International Journal publishing academic and industrial research on industrial (defined as non-food/non-feed) crops and products. Papers concern both crop-oriented and bio-based materials from crops-oriented research, and should be of interest to an international audience, hypothesis driven, and where comparisons are made statistics performed.