Microwaved Vermicast Physicochemical Properties and Active Microbial Groups Impact on Photosynthetic Activity, Growth and Yield of Kale

GM crops Pub Date : 2022-03-31 DOI:10.3390/crops2020007

L. Abbey, Zhi-Peng Rao, Su-Lan Lin

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Abstract

Microwave technology has wide applications, including extraction of active compounds in biomass and compost for agricultural use. A study was carried out to determine the effects of microwave power level from 0 (control) to 1000 W on the properties and active microbial groups in vermicast, and how it may impact the photosynthesis, plant growth, and yield of kale (Brassica oleracea var. sabellica) ‘Red Russian’. Heat accumulation in the vermicast increased rapidly to a peak of 86 °C at 400 W before declining to 68 °C at 1000 W. Vermicast water loss increased exponentially up to 800 W before declining. The C:N ratio of the vermicast was reduced at ≥600 W while the pH remained the same. In a 2D-principal component analysis biplot, vermicast treated at 600, 800 and 1000 W were associated with Gram-positive (G+), GGram-negative (G−), G + G− bacteria, protozoa, and fungi groups while the 0, 200, and 400 W treated vermicast were associated with eukaryotes. However, the trend for total microbial mass was 200 W = 400 W > 0 W > 600 W = 800 W = 1000 W. Kale leaf anthocyanin, chlorophylls, and carotenoids were significantly (p = 0.001) increased by the 400 W or 600 W treatment compared to the other treatments. Stomatal conductance, transpiration, and photosynthesis rates were increased by the 400 W followed by the 600 W. As a result, yield of kale grown in the 400 W microwaved vermicast was the highest. Future studies will explain the functions of specific microbial populations and elemental composition in microwaved vermicast.

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微波蚯蚓理化性质及活性菌群对羽衣甘蓝光合活性、生长和产量的影响

微波技术具有广泛的应用前景，可用于提取生物质和农业堆肥中的活性物质。研究了0 ~ 1000 W微波功率水平对“红俄罗斯”甘蓝(Brassica oleracea var. sabellica)光合作用、植株生长和产量的影响，以及微波功率水平对vermicast特性和活性微生物群的影响。蛭体的热积累迅速增加，在400 W时达到86℃的峰值，然后在1000 W时下降到68℃。蚓质体失水在达到800w后呈指数增长，随后下降。≥600 W时，蚯蚓的C:N比降低，但pH不变。在二维主成分分析双图中，600、800和1000 W处理的蠕形虫与革兰氏阳性(G+)、革兰氏阴性(G−)、G+ G−细菌、原生动物和真菌群相关，而0、200和400 W处理的蠕形虫与真核生物相关。微生物总质量的变化趋势为200 W = 400 W > 0 W > 600 W = 800 W = 1000 W。与其他处理相比，400 W和600 W处理显著提高了甘蓝叶片花青素、叶绿素和类胡萝卜素(p = 0.001)。气孔导度、蒸腾速率和光合速率在400 W后依次增加，600 W后增加。结果表明，在400w微波发酵条件下羽衣甘蓝产量最高。未来的研究将进一步解释微波蚓质体中特定微生物种群的功能和元素组成。

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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