Jong H. Kim, K. Chan, W. Hart-Cooper, DeAngela Ford, Kaydren Orcutt, Jeffrey D Palumbo, Christina C. Tam, William J. Orts
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引用次数: 0
Abstract
The United States is a principal producer of tree nuts (almonds, pistachios, and walnuts), resulting in the generation of excess of tree-nutshell by-products each year, with few market outlets. A nutshell is an essential, lignocellulosic layer that protects a kernel (seed) from the environment during cultivation. The objective of this study was to develop nutshell by-products as herbicide delivery systems, which would not only enable sustainable weed control in fields but also increases nutshell value and reduce the cost of waste disposal. We recently identified a natural salicylaldehyde (SA) that emits volatiles with both herbicidal and antifungal properties. In this study, walnut shell particles saturated with 0.8 to 1.6 M SA were developed as delivery vehicles for SA to soil, which allowed for the controlled release of an SA fumigant for weed control. The pre- and post-emergent herbicidal efficacy of SA was investigated using model monocot (Lolium arundinaceum (Schreb.) Darbysh; turfgrass) and dicot (Brassica rapa var. pekinensis; Chinese cabbage) plants. We compared (1) the effects of different types of solvents for dissolving SA (dimethyl sulfoxide (DMSO) and ethanol (60%, v/v)), and (2) the effect of covering soil with plastic layers (i.e., soil pasteurization) or not covering soil during SA fumigation using nutshells. Results: In the pre-emergent herbicidal testing with the soil covered, the dicot plants exhibited levels of higher susceptibility to SA in DMSO emitted from nutshells when compared to the monocot plants. The seed germination frequencies in the dicots were 15% and 1% with 0.8 and 1.6 M SA, respectively, while those in the monocots were 32% and 18%, respectively, under the same test conditions. In the post-emergent herbicidal testing with the soil covered, the growth of both the monocot and dicot plants was completely prevented after 5 to 7 days of SA fumigation, resulting in the deaths of entire plants. It was noteworthy that in the post-emergent herbicidal testing, SA dissolved in ethanol (60%, v/v) completely disrupted the growth of the monocot and dicot plants as early as 3 days after SA emission from the nutshells, even without the soil being covered. Tree-nutshell particles could serve as effective SA delivery vehicles with controlled release capabilities for SA. The SA exhibited pre- and post-emergent herbicidal activities against the monocot and dicot plants at most growth stages. SA (0.8 and 1.6 M) dissolved in ethanol (60%, v/v) might exert a synergism for higher herbicidal activity after emission from nutshells. Since tree nuts capture/store a substantial amount of carbon over their life-cycles, the new and sustainable utility of using nutshells not only reduces carbon emissions but also valorizes tree-nut by-products, thus benefitting the tree-nut industry.
美国是树坚果(杏仁、开心果和核桃)的主要生产国,因此每年都会产生过量的树坚果壳副产品,但市场销路却很少。坚果壳是一种重要的木质纤维素层,可在种植过程中保护果仁(种子)免受环境影响。本研究的目的是开发果壳副产品作为除草剂的输送系统,这不仅能实现田间除草的可持续性,还能提高果壳的价值并降低废物处理成本。我们最近发现了一种天然水杨醛(SA),它能释放出具有除草和抗真菌特性的挥发性物质。在这项研究中,我们开发了饱和 0.8 至 1.6 M 水杨醛的核桃壳颗粒,作为水杨醛在土壤中的输送载体,从而控制水杨醛熏蒸剂的释放以控制杂草。我们使用示范单子叶植物(Lolium arundinaceum (Schreb.) Darbysh;草皮草)和双子叶植物(Brassica rapa var.我们比较了(1)不同类型溶剂(二甲基亚砜(DMSO)和乙醇(60%,v/v))溶解 SA 的效果,以及(2)在使用果壳熏蒸 SA 的过程中用塑料层覆盖土壤(即土壤杀菌)或不覆盖土壤的效果。研究结果在覆盖土壤的萌发前除草试验中,与单子叶植物相比,双子叶植物对果壳释放的二甲基亚砜中的 SA 表现出更高的敏感性。在相同的试验条件下,双子叶植物的种子萌发率在 0.8 和 1.6 M SA 的作用下分别为 15%和 1%,而单子叶植物的种子萌发率分别为 32% 和 18%。在覆盖土壤的苗后除草试验中,单子叶植物和双子叶植物在 SA 熏蒸 5 至 7 天后生长完全受阻,导致整株植物死亡。值得注意的是,在芽后除草试验中,溶解在乙醇(60%,v/v)中的 SA 在果壳释放出 SA 后 3 天就完全破坏了单子叶植物和双子叶植物的生长,即使没有覆盖土壤也是如此。果壳颗粒可作为有效的 SA 运送载体,具有控制 SA 释放的能力。在大多数生长阶段,SA 对单子叶植物和双子叶植物都具有萌芽前和萌芽后除草活性。溶解在乙醇(60%,v/v)中的 SA(0.8 和 1.6 M)从果壳中释放出来后,可能会产生增效作用,从而提高除草活性。由于树坚果在其生命周期中会捕获/储存大量的碳,因此利用坚果壳这种可持续的新方法不仅能减少碳排放,还能使树坚果副产品增值,从而使树坚果产业受益。