Nitrogen fertilization effects on aged Miscanthus × giganteus stands: Exploring biomass yield, yield components, and biomass prediction using in-season morphological traits

IF 5.9 3区工程技术 Q1 AGRONOMY

Global Change Biology Bioenergy Pub Date : 2024-04-10 DOI:10.1111/gcbb.13139

Nictor Namoi, Chunhwa Jang, Gevan D. Behnke, Jung Woo Lee, Wendy Yang, DoKyoung Lee

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Abstract

For sustainable biomass production of Miscanthus × giganteus (hereafter miscanthus), understanding the impact of stand age and nitrogen (N) fertilization on biomass yield is crucial. This study investigated the effects of varying N fertilization rates (0, 56, 112, and 168 kg N ha⁻¹) on yield components (tiller height, density, and weight) and their correlations with end-of-season biomass yield in miscanthus. We also explored end-of-season biomass yield prediction using in-season traits (canopy height, leaf area index, and leaf chlorophyll content [LCC]). The study was conducted at two sites in Illinois: a previously unfertilized 10-year-old miscanthus research stand at Urbana and a 16-year-old commercial stand at Pesotum with a history of annual 56N application. Results from 2018 to 2021 in Urbana and 2020 to 2021 in Pesotum showed increased biomass yields with N fertilization, varying by rate, year, and location. Biomass yield in Pesotum peaked at 56N, while in Urbana, it increased significantly at 112 kg N ha⁻¹. Biomass yield was strongly correlated with tiller height and weight measured at Urbana across N rates. Morphological traits measured every 2–3 weeks during the 2020 and 2021 growing seasons showed that canopy height was the strongest single predictor of miscanthus biomass yield, followed by LCC. Mid-August to September measurements of these traits were the best predictors of biomass yield. Multiple regressions involving the canopy height and LCC further improved yield predictions. We conclude that while N enhances biomass yields of aging miscanthus, the optimum rate depends on the site, environmental conditions, and management history.

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氮肥对老化木棉 × giganteus 林分的影响：利用季节形态特征探索生物量产量、产量成分和生物量预测

为了实现 Miscanthus × giganteus（以下简称 Miscanthus）的可持续生物量生产，了解立地年龄和氮肥对生物量产量的影响至关重要。本研究调查了不同氮肥施用量（0、56、112 和 168 kg N ha-1）对马齿苋产量成分（分蘖高度、密度和重量）的影响及其与季末生物量产量的相关性。我们还利用季内性状（冠层高度、叶面积指数和叶片叶绿素含量 [LCC]）对季末生物量产量进行了预测。该研究在伊利诺伊州的两个地点进行：位于厄巴纳的一个以前未施肥的 10 年生马桑草研究林地和位于佩索图姆的一个 16 年生商业林地，这两个林地有每年施用 56N 的历史。乌尔班纳 2018 年至 2021 年和佩索图姆 2020 年至 2021 年的结果表明，氮肥施用量、施用年份和施用地点不同，生物量产量也不同。Pesotum 的生物量产量在 56N 时达到峰值，而在 Urbana，生物量产量在每公顷 112 千克氮时显著增加。乌尔班纳的生物量产量与不同氮肥施用量下测得的分蘖高度和重量密切相关。2020 年和 2021 年生长季期间每 2-3 周测量一次的形态特征表明，冠层高度是预测马齿苋生物量产量的最强单一指标，其次是 LCC。8 月中旬至 9 月对这些性状的测量结果是预测生物量产量的最佳指标。涉及冠层高度和 LCC 的多重回归进一步改善了产量预测。我们得出的结论是，虽然氮能提高老化鱼腥草的生物量产量，但最佳比例取决于种植地点、环境条件和管理历史。

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来源期刊

Global Change Biology Bioenergy AGRONOMY-ENERGY & FUELS

CiteScore

10.30

自引率

7.10%

发文量

审稿时长

1.5 months

期刊介绍： GCB Bioenergy is an international journal publishing original research papers, review articles and commentaries that promote understanding of the interface between biological and environmental sciences and the production of fuels directly from plants, algae and waste. The scope of the journal extends to areas outside of biology to policy forum, socioeconomic analyses, technoeconomic analyses and systems analysis. Papers do not need a global change component for consideration for publication, it is viewed as implicit that most bioenergy will be beneficial in avoiding at least a part of the fossil fuel energy that would otherwise be used. Key areas covered by the journal: Bioenergy feedstock and bio-oil production: energy crops and algae their management,, genomics, genetic improvements, planting, harvesting, storage, transportation, integrated logistics, production modeling, composition and its modification, pests, diseases and weeds of feedstocks. Manuscripts concerning alternative energy based on biological mimicry are also encouraged (e.g. artificial photosynthesis). Biological Residues/Co-products: from agricultural production, forestry and plantations (stover, sugar, bio-plastics, etc.), algae processing industries, and municipal sources (MSW). Bioenergy and the Environment: ecosystem services, carbon mitigation, land use change, life cycle assessment, energy and greenhouse gas balances, water use, water quality, assessment of sustainability, and biodiversity issues. Bioenergy Socioeconomics: examining the economic viability or social acceptability of crops, crops systems and their processing, including genetically modified organisms [GMOs], health impacts of bioenergy systems. Bioenergy Policy: legislative developments affecting biofuels and bioenergy. Bioenergy Systems Analysis: examining biological developments in a whole systems context.