抗逆增效草种包衣丸化技术在生态修复中的应用进展

doi:10.13287/j.1001-9332.202508.014

摘要/Abstract

摘要： 抗逆增效草种包衣丸化技术的核心机制是通过种衣剂(通常为液体或粉末形态)为种子提供多功能保护层,增强种子对环境胁迫的适应能力,是一种重要的生态修复手段,在恶劣环境中具有较高的应用潜力。本文综述了该技术的理论基础与发展历程,探讨了种子包衣的概念、材料选择与优化(包括活性物质、非活性物质及复合型包衣材料的应用),以及丸化工艺的创新;分析了该技术在退化草地、盐碱地和矿区修复中的应用效果,并重点讨论了其在不同生态环境中的适用性。尽管该技术在生态修复中取得了良好的效果,但面临包衣材料的环保性与经济性问题,以及长期生态效应评估的挑战。未来研究可在优化包衣材料性能的基础上,推动包衣丸化标准化技术体系的构建和技术创新,提高环保性与经济性,为生态修复提供更有力的技术支持。

关键词: 生态修复, 种子包衣技术, 丸粒化, 抗逆性, 多功能复合材料

Abstract: The core mechanism of stress-resilient and growth-enhancing seed coating and pelleting technology involves applying a multifunctional protective layer to seeds with liquid or powder coating agents. This layer enhances seed resilience to environmental stressors, making the technology a promising tool for ecological restoration. We reviewed the theoretical basis and development of the technology, including seed coating principles, the selection and optimization of active and inert materials, and composite coatings, and advances in pelleting techniques. We further evaluated its effectiveness in restoring degraded grasslands, saline-alkali soils, and mining areas, highligh-ting its adaptability to diverse ecological contexts. Despite promising outcomes, challenges remain concerning the environmental sustainability, cost-effectiveness, and long-term impacts of coating materials. Future research should focus on improving material performance, establishing standardized technical frameworks, and fostering innovations that enhance environmental and economic viability. Advances in those directions would provide stronger technical support for ecological restoration.

Key words: ecological restoration, seed coating technology, pelletizing, stress resistance, multifunctional compo-site material

任海燕, 远远, 赵文多, 李安婷, 李雨昕, 宋晓辉. 抗逆增效草种包衣丸化技术在生态修复中的应用进展[J]. 应用生态学报, 2025, 36(8): 2563-2570.

REN Haiyan, YUAN Yuan, ZHAO Wenduo, LI Anting, LI Yuxin, SONG Xiaohui. Advances in the application of stress-resilient and growth-enhancing seed coating and pelleting technology for ecological restoration[J]. Chinese Journal of Applied Ecology, 2025, 36(8): 2563-2570.

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