Foliar application of nano biochar solution elevates tomato productivity by counteracting the effect of salt stress insights into morphological physiological and biochemical indices.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-01-25 DOI:10.1038/s41598-025-87399-5

Javeria Shahzadi, Zaib-Un-Nisa, Naila Ali, Muhammad Iftikhar, Anis Ali Shah, M Yasin Ashraf, Chen Chao, Shifa Shaffique, Mansour K Gatasheh

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Abstract

Nano-biochar considers a versatile and valuable sorbent to enhance plant productivity by improving soil environment and emerged as a novel solution for environmental remediation and sustainable agriculture in modern era. In this study, roles of foliar applied nanobiochar colloidal solution (NBS) on salt stressed tomato plants were investigated. For this purpose, NBS was applied (0%, 1% 3% and 5%) on two groups of plants (control 0 mM and salt stress 60 mM). Tween-20 was used as a surfactant to prolong NBS effective stay on plant leaf surface. The results showed that 3% NBS application effectively improved the plant height, plant biomass, fruit count and fruit weight under non-stressed and stressed plants. In addition, 3% NBS application further increased the plant pigments such as chlorophyll by 72% and 53%, carotenoids by 64% and 40%, leaf relative water content by 4.1 fold and 1.07 fold under both conditions, respectively. NBS application stabilized the plasma membrane via reducing electrolyte leakage by 30% as well as reduced the lipid peroxidation rates by 46% and 29% under non-stressed and stressed plants, respectively. 3% NBS application also significantly enhanced the plants primary and secondary metabolites, as well as activities of antioxidant enzymes compared to control plants. Overall, NBS foliar application significantly improved all growth and yield indices, pigments, primary and secondary metabolites, leaf water content, antioxidant enzyme activities as well as reduced electrolyte leakage and lipid peroxidation rates in tomato to combat stress conditions. In future, studies on nano biochar interactions with soil microbiota, surface modifications, long-term environmental impacts, reduced methane gas emissions, and biocompatibility could provide insights into optimizing its use in sustainable agriculture.

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叶面施用纳米生物炭溶液通过抵消盐胁迫对番茄形态生理生化指标的影响而提高番茄产量。

纳米生物炭被认为是一种多功能的、有价值的吸附剂，可以通过改善土壤环境来提高植物的生产力，是现代环境修复和可持续农业的新解决方案。研究了叶面施用纳米炭胶体溶液（NBS）对盐胁迫番茄植株的影响。在对照0 mM和盐胁迫60 mM两组植株上分别施用0%、1%、3%和5%的NBS。用Tween-20作为表面活性剂延长NBS在植物叶片表面的有效停留时间。结果表明，施用3% NBS能有效提高非胁迫和胁迫植株的株高、生物量、果数和果重。此外，施用3% NBS可使叶绿素等植物色素含量分别提高72%和53%，类胡萝卜素含量分别提高64%和40%，叶片相对含水量分别提高4.1倍和1.07倍。在非胁迫和胁迫植物中，NBS通过减少30%的电解质泄漏来稳定质膜，并将脂质过氧化率分别降低46%和29%。与对照植株相比，施用3% NBS显著提高了植株的初级和次级代谢产物及抗氧化酶活性。总体而言，叶面施用NBS显著提高了番茄的所有生长和产量指标、色素、初级和次级代谢物、叶片含水量、抗氧化酶活性，并降低了电解质泄漏和脂质过氧化率，以对抗胁迫条件。未来，纳米生物炭与土壤微生物群的相互作用、表面修饰、长期环境影响、减少甲烷气体排放和生物相容性的研究可以为优化其在可持续农业中的应用提供见解。

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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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