Bitarafan Zahra, Kaczmarek-Derda Wiktoria, Berge Therese With, Øyri Carl Emil, Fløistad Inger Sundheim
Division of Biotechnology and Plant Health, Norwegian Institute of Bioeconomy Research (NIBIO), Ås, Norway.
Division of Forestry and Forest Resources, Norwegian Institute of Bioeconomy Research (NIBIO), Ås, Norway.
Pest Manag Sci. 2025 Apr;81(4):2032-2039. doi: 10.1002/ps.8603. Epub 2024 Dec 12.
As regulations on pesticides become more stringent, it is likely that there will be interest in steam as an alternative approach for soil disinfestation. This study investigates the feasibility of utilizing a soil steaming device for thermal control of invasive plants.
Seeds of Echinochloa crus-galli, Impatiens glandulifera, Solidago canadensis, and rhizome fragments of Reynoutria × bohemica were examined for thermal sensitivity through two exposure methods: (1) steam treatment of propagative material in soil; (2) exposure of propagative material to warm soil just after heated by steam. Soil temperatures in the range of 60-99 °C and dwelling period of 3 min were tested. Increased soil temperature decreased seed germination/rhizome sprouting. The exposure method had a significant effect where higher temperatures were needed to reduce the seed germination/rhizome sprouting in method 2 explained by the effect of extra heat given in method 1. Using method 1, for E. crus-galli and S. canadensis, the maximum mean temperature of approximately 80 °C was enough to achieve the effective weed control level (90%). This was lower for I. glandulifera and higher for R. × bohemica. Using method 2, 90% control was achieved at 95 °C for S. canadensis; more than 115 °C for I. glandulifera; and more than 130 °C for E. crus-galli and R. × bohemica.
Our findings showed a promising mortality rate for weeds propagative materials through soil steaming. However, the species showed varying responses to heat and therefore steam regulation should be based on the differences in weeds' susceptibility to heat. © 2024 The Author(s). Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry.
随着农药法规日益严格,人们可能会对蒸汽作为土壤消毒的替代方法产生兴趣。本研究调查了利用土壤蒸汽处理装置对入侵植物进行热控制的可行性。
通过两种暴露方法研究了稗草、凤仙花、加拿大一枝黄花的种子以及 Bohemica 蓼的根茎片段的热敏感性:(1)对土壤中的繁殖材料进行蒸汽处理;(2)在土壤经蒸汽加热后立即将繁殖材料置于温暖的土壤中。测试了 60 - 99°C 的土壤温度范围和 3 分钟的处理时间。土壤温度升高会降低种子发芽率/根茎发芽率。暴露方法有显著影响,方法 2 需要更高的温度才能降低种子发芽率/根茎发芽率,这可以通过方法 1 中额外的热量效应来解释。使用方法 1,对于稗草和加拿大一枝黄花,约 80°C 的最高平均温度足以达到有效的杂草控制水平(90%)。对于凤仙花来说这个温度更低,而对于 Bohemica 蓼则更高。使用方法 2,加拿大一枝黄花在 95°C 时达到 90%的控制率;凤仙花在超过 115°C 时达到;稗草和 Bohemica 蓼在超过 130°C 时达到。
我们的研究结果表明,通过土壤蒸汽处理,杂草繁殖材料有较高的死亡率。然而,不同物种对热的反应不同,因此蒸汽调节应基于杂草对热的敏感性差异。© 2024 作者。由 John Wiley & Sons Ltd 代表化学工业协会出版的《害虫管理科学》。
