Lead-Immobilization, transformation, and induced toxicity alleviation in sunflower using nanoscale Fe°/BC: Experimental insights with Mechanistic validations
M. Aslam, M. Waris, Ihsan Muhammad, Maqbool Ahmed, Z. Khan, Z. Jabeen, Mohammad Yakoob Zehri, M. Arsalan, S. Rehman, A. M. Alnasrawi, Jawaher Alkahtani, M. S. Elshikh, Muhammad Rizwan, Shoaib Raza, Jinsong Deng, Adnan Raza Altaf
{"title":"Lead-Immobilization, transformation, and induced toxicity alleviation in sunflower using nanoscale Fe°/BC: Experimental insights with Mechanistic validations","authors":"M. Aslam, M. Waris, Ihsan Muhammad, Maqbool Ahmed, Z. Khan, Z. Jabeen, Mohammad Yakoob Zehri, M. Arsalan, S. Rehman, A. M. Alnasrawi, Jawaher Alkahtani, M. S. Elshikh, Muhammad Rizwan, Shoaib Raza, Jinsong Deng, Adnan Raza Altaf","doi":"10.1080/17429145.2022.2107722","DOIUrl":null,"url":null,"abstract":"ABSTRACT Lead (Pb) is a biologically non-essential element in the soil that brutally affects plants and other living organisms in soil; hence, its removal has become a worldwide concern. In this work, a multifunctional nanoscale zerovalent-iron assisted biochar (nFe°/BC) was used to minimize the Pb bioavailability in soil with aim of alleviating the Pb-induced toxicity in sunflower. Results revealed that nFe°/BC treatment had significantly improved plant growth (58%), chlorophyll contents (66%), intracellular permeability (60%), and ratio factor (93%), while decreasing the Pb uptake (78%) in plants. The Pb-immobilization and transformation mechanisms were proposed, suggesting that the presence of organic functional groups over the nFe°/BC surface might induce the complex formation with Pb by the ions exchange process in soil solution. The XPS analysis confirmed that surface-active components (Fe+, O2−, O*, C═O) were the key factor for high Pb-immobilization within soil matrix. In addition, 87% of stable Pb species, including PbCO3, PbO, Pb (OH)2, and Pb-O-Fe were found in the soil surface. Current findings have exposed the diverse functions of nFe°/BC on plant health and established a phenomenon that nFe°/BC application could improve the plant agronomic attributes by regulating the homeostasis of antioxidants and Pb uptake.","PeriodicalId":16830,"journal":{"name":"Journal of Plant Interactions","volume":"17 1","pages":"812 - 823"},"PeriodicalIF":2.6000,"publicationDate":"2022-08-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"4","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of Plant Interactions","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.1080/17429145.2022.2107722","RegionNum":3,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"PLANT SCIENCES","Score":null,"Total":0}
引用次数: 4
Abstract
ABSTRACT Lead (Pb) is a biologically non-essential element in the soil that brutally affects plants and other living organisms in soil; hence, its removal has become a worldwide concern. In this work, a multifunctional nanoscale zerovalent-iron assisted biochar (nFe°/BC) was used to minimize the Pb bioavailability in soil with aim of alleviating the Pb-induced toxicity in sunflower. Results revealed that nFe°/BC treatment had significantly improved plant growth (58%), chlorophyll contents (66%), intracellular permeability (60%), and ratio factor (93%), while decreasing the Pb uptake (78%) in plants. The Pb-immobilization and transformation mechanisms were proposed, suggesting that the presence of organic functional groups over the nFe°/BC surface might induce the complex formation with Pb by the ions exchange process in soil solution. The XPS analysis confirmed that surface-active components (Fe+, O2−, O*, C═O) were the key factor for high Pb-immobilization within soil matrix. In addition, 87% of stable Pb species, including PbCO3, PbO, Pb (OH)2, and Pb-O-Fe were found in the soil surface. Current findings have exposed the diverse functions of nFe°/BC on plant health and established a phenomenon that nFe°/BC application could improve the plant agronomic attributes by regulating the homeostasis of antioxidants and Pb uptake.
铅(Pb)是土壤中的一种生物非必需元素,对土壤中的植物和其他生物具有严重影响;因此,它的清除已成为全世界关注的问题。在本研究中,利用纳米多功能零价铁辅助生物炭(nFe°/BC)降低土壤中铅的生物有效性,以减轻铅对向日葵的毒性。结果表明,nFe°/BC处理显著提高了植物生长(58%)、叶绿素含量(66%)、细胞内通透性(60%)和比值因子(93%),降低了植物对Pb的吸收(78%)。研究结果表明,nFe°/BC表面有机官能团的存在可能导致土壤溶液中离子交换过程中与Pb形成络合物。XPS分析证实,表面活性成分(Fe+, O2−,O*, C = O)是土壤基质内高铅固定的关键因素。此外,土壤表层有87%的Pb稳定种,包括PbCO3、PbO、Pb (OH)2和Pb- o - fe。目前的研究结果揭示了nFe°/BC对植物健康的多种作用,并确定了nFe°/BC可以通过调节抗氧化剂和铅吸收的动态平衡来改善植物农艺性状的现象。
期刊介绍:
Journal of Plant Interactions aims to represent a common platform for those scientists interested in publishing and reading research articles in the field of plant interactions and will cover most plant interactions with the surrounding environment.