发展和应用的重要课题。许多研究证明向土壤施用添加剂可以提高植物对重金属的积累速率和水平,但其环境安全性也受到高度重视,因此开发环境友好型添加剂是今后的一个重要研究方向。
(6)降低成本—转变土地利用方式。实际上,当前植物修复技术最大的制约因素就是成本问题:不能将土地撂荒,风险防控及植物残体的处理均不能产生经济效益,这种纯投入的方式无法自发进行。转变污染土地的利用方式,在修复土壤的同时,使污染农田能够得到再利用,这或许是一条长期良性的植物修复途径。
4展望
尽管存在诸多不足,但绿色、生态这一优势使植物修复技术仍是今后治理土壤重金属污染的一个重要方法,当前,探寻该技术的改进方法已成为该领域一个新的研究课题,同时也为植物修复技术带来了新的发展契机。为了能够将植物修复手段广泛的应用与实践当中,同时保证修复工作高效、顺利地进行,在今后应加强以下几个方面的研究:(1)继续寻找和开发生物量大、能超量累积放射性重金属以及能同时累积多种放射性重金属的植物;(2) 基因工程手段与合理高效的水肥管理、轮作制度、刈割等农艺措施相结合(3)施用螯合剂虽可促进植物对重金属的吸收,但其活化作用一旦超出植物根系吸收的范围,就会增加污染风险。目前植物重金属收集技术还尚未实现,研发各种稳定技术,减少重金属向食物链转移的途径看起来更为可行。(4)深入探讨重金属的源与宿问题,正确认识不同条件下重金属的污染阈值,以转变污染土地的利用方式为主导,才能形成一整套有利润链条的良性修复模式。
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