Laser weed seed control: challenges and opportunities

Frontiers in Agronomy Pub Date : 2024-03-27 DOI:10.3389/fagro.2024.1342372

Christian Andreasen, Eleni Vlassi, Najmeh Salehan, Kenneth S. Johannsen, Signe M. Jensen

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Abstract

Farmers are greatly interested in reducing weed seeds in their fields to avoid unnecessary weed infestation. Autonomous vehicles equipped with plant recognition systems and lasers can be used to control weed plants and may therefore be used to replace or supplement herbicides and mechanical weed control. However, less is known about the ability of laser to control weed seeds. In this study, seeds of weeds (Alopecurus myosuroides, Anisantha sterilis, Avena fatua, Centaurea cyanus, Silene noctiflora) and crops (wheat (Triticum aestivum), maize (Zea mays)) were exposed to increasing dosages of laser energy. The species represented dicots and monocots with different seed sizes and morphology. We used a thulium-doped 50 W fiber laser with a wavelength of 2 µm and a diameter of 2 mm developed for weed control. The seeds were exposed to laser directly on the seed surface or after been covered with soil (2.5 and 5 mm). Small doses of energy (0.4 J mm−2 and 0.8 J mm−2) affected the germination ability of small seeds (S. noctiflora and C. cyanus) when the seeds were irradiated directly on the seed surface, and they were completely burned at the high doses (8.0 J mm−2 and 15.9 J mm−2). However, there was not a clear relationship between seed size and sensitivity to laser dose. Additionally, increasing the laser dose on the seed surface resulted in increasing infection of fungi. Seeds covered with soil were not affected by the laser treatments except C. cyanus seeds. Controlling large seeds on the ground while weed seedlings are controlled with laser robots seems realistic in the future. However, dosages higher than 50 J (~15.9 J mm−2) is necessary to control large seeds.

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激光杂草种子控制：挑战与机遇

农民对减少田间杂草种子以避免不必要的杂草侵扰非常感兴趣。配备植物识别系统和激光的自动驾驶汽车可用于控制杂草植物，因此可用于替代或补充除草剂和机械除草。然而，人们对激光控制杂草种子的能力知之甚少。在这项研究中，杂草（Alopecurus myosuroides、Anisantha sterilis、Avena fatua、Centaurea cyanus、Silene noctiflora）和农作物（小麦（Triticum aestivum）、玉米（Zea mays））的种子被暴露在剂量不断增加的激光能量下。这些物种代表了种子大小和形态各异的双子叶植物和单子叶植物。我们使用的是掺铥的 50 W 光纤激光器，波长为 2 µm，直径为 2 mm，用于控制杂草。种子直接暴露在激光照射下，或在种子表面覆盖土壤（2.5 毫米和 5 毫米）后暴露在激光照射下。直接照射种子表面时，小剂量能量（0.4 J mm-2 和 0.8 J mm-2）会影响小粒种子（S. noctiflora 和 C. cyanus）的萌发能力，而高剂量能量（8.0 J mm-2 和 15.9 J mm-2）则会完全烧毁种子。然而，种子大小与对激光剂量的敏感性之间并没有明显的关系。此外，增加种子表面的激光剂量会导致真菌感染增加。被土壤覆盖的种子不受激光处理的影响，但青花菜种子除外。在使用激光机器人控制杂草幼苗的同时控制地面上的大粒种子似乎在未来是现实的。不过，要控制大粒种子，剂量必须高于 50 J（约 15.9 J mm-2）。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Frontiers in Agronomy

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