Novel nanocomposite and biochar insights to boost rice growth and alleviation of Cd toxicity.

IF 3.8 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2024-10-05 DOI:10.1038/s41598-024-73635-x

Muhammad Azhar Ali, Muhammad Nafees, Sarah Owdah Alomrani, Yuanyuan Li, Qian Wang, Mohammed Ali Alshehri, Khalid A Al-Ghanim, Shafaqat Ali, Fengmin Li

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引用次数: 0

Abstract

Cadmium (Cd) is an unessential and pervasive contaminant in agricultural soil, eventually affecting the food and instigating health issues. The implication of nanocomposites in agriculture attained significant attention to drive food security. Nanocomposites possess exceptional characteristics to stun the challenges of chemical fertilizers that can enhance plant yield and better nutrient bioavailability. Similarly, biochar has the ability to immobilize Cd in soil by reducing mobility and bioavailability. Rice husk biochar is produced at high temperature pyrolysis under anoxic conditions and a stable carbon-rich material is formed. To strive against this issue, rice plants were subjected to Cd (15, 20 mg kg^- 1) stress and treated with alone/combined Ca + Mg (25 mg L^- 1) nanocomposite and rice husk biochar. In our study, growth and yield traits showed the nurturing influence of Ca + Mg nanocomposite and biochar to improve rice defence mechanism by reducing Cd stress. Growth parameters root length 28%, shoot length 34%, root fresh weight 19%, shoot fresh weight 16%, root dry weight 9%, shoot dry weight 8%, number of tillers 32%, number of grains 20%, and spike length 17% were improved with combined application of Ca + Mg and biochar, with Cd (20 mg kg^- 1), rivalled to alone biochar. Combined Ca + Mg and biochar application increased the SPAD 23%, total chlorophyll 26%, a 19%, b 18%, and carotenoids 15%, with Cd (20 mg kg^- 1), rivalled to alone biochar. MDA 15%, H₂O₂ 13%, and EL 10% were significantly regulated in shoots with combined Ca + Mg and biochar application with Cd (20 mg kg^- 1) compared to alone biochar. POD 22%, SOD 17%, APX 18%, and CAT 9% were increased in shoots with combined Ca + Mg and biochar application with Cd (20 mg kg^- 1) compared to alone biochar. Cd uptake in roots 13%, shoots 14%, and grains 21% were minimized under Cd (20 mg kg^- 1) with combined Ca + Mg and B. pumilus application, compared to alone biochar. Subsequently, combined Ca + Mg and biochar application is a sustainable solution to boost crop production under Cd stress.

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新型纳米复合材料和生物炭促进水稻生长和减轻镉毒性的见解。

镉（Cd）是农业土壤中一种不可或缺的普遍污染物，最终会影响食物并引发健康问题。纳米复合材料在农业中的应用在促进粮食安全方面获得了极大关注。纳米复合材料具有优异的特性，能够应对化肥的挑战，提高植物产量和养分的生物利用率。同样，生物炭能够固定土壤中的镉，降低其流动性和生物利用率。稻壳生物炭是在缺氧条件下通过高温热解产生的，是一种稳定的富碳材料。为了解决这一问题，我们对水稻植株施加镉（15、20 mg kg- 1）胁迫，并用单独/复合 Ca + Mg（25 mg L- 1）纳米复合材料和稻壳生物炭进行处理。我们的研究表明，纳米钙镁复合材料和生物炭对水稻的生长和产量性状具有促进作用，可通过降低镉胁迫改善水稻的防御机制。联合施用钙镁和生物炭后，根长提高了 28%，芽长提高了 34%，根鲜重提高了 19%，芽鲜重提高了 16%，根干重提高了 9%，芽干重提高了 8%，分蘖数提高了 32%，穗粒数提高了 20%，穗长提高了 17%。联合施用钙镁和生物炭可提高 SPAD 23%、总叶绿素 26%、叶绿素 a 19%、叶绿素 b 18%、类胡萝卜素 15%，其中镉（20 毫克/千克）的含量可与单独施用生物炭媲美。与单独施用生物炭相比，联合施用 Ca + Mg 和生物炭与 Cd（20 毫克/公斤-1）的嫩芽中，MDA 15%、H2O2 13%、EL 10%均有显著调节。与单独施用生物炭相比，联合施用 Ca + Mg 和含 Cd 的生物炭（20 毫克/千克-1）的嫩芽中 POD 增加了 22%，SOD 增加了 17%，APX 增加了 18%，CAT 增加了 9%。与单独施用生物炭相比，在施用 Ca + Mg 和 B. pumilus 的情况下，镉（20 毫克/公斤-1）在根中的吸收率为 13%，在芽中的吸收率为 14%，在谷物中的吸收率为 21%。因此，联合施用钙镁和生物炭是在镉胁迫下提高作物产量的可持续解决方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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