评估生物资源利用影响的模块框架(BIORIM)

IF 10.9 1区 环境科学与生态学 Q1 ENVIRONMENTAL STUDIES
Ulrich Kreidenweis , Andrés de Jesús Vargas-Soplín
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引用次数: 0

摘要

生物过程和现场条件的强烈影响、管理的巨大多样性、农产品成分的变化以及过程的循环性都对生物经济的环境影响评估提出了挑战。本文介绍了一种研究生物资源利用影响的新型可持续性评估和物质流模型(BIORIM),旨在应对这些挑战。该模型代表了重要的生物经济生产系统(如耕地、奶牛场、沼气厂),在计算产品和排放量时考虑了输入属性、生产参数(如场地条件或管理)以及不同的排放因子。因此,在分析大型生产网络时,需要按照正确的顺序执行表示转换过程的函数。该模型对质量流、碳流和氮流进行全面跟踪,因此可以评估在加工过程中损失了多少,最终在产品中损失了多少,以及回收利用了多少。建模方法以一个奶牛场为例进行说明,该奶牛场将奶牛粪便作为有机肥料用于下一年的饲料作物生产。这与包括沼气厂在内的方案进行了比较。粪便储存与沼气生产的比较表明,这种变化不仅影响直接排放。沼气生产会导致更高的碳损失,从而对腐殖质平衡产生负面影响。另一方面,粪便贮存会导致较高的氮损失,从而降低粪便的肥料价值,因此第二年需要更多的矿物肥料。再加上能源生产所节省的排放量,这就使得沼气方案的全球变暖效应降低。这项研究表明,在评估生物经济生产系统的影响时,必须考虑各种过程之间的相互作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A modular framework to assess biological resource utilization impacts (BIORIM)

The strong influence of biological processes and site conditions, the large diversity in management, compositional changes of agricultural produce, and the circularity of processes challenge the assessment of environmental impacts of the bioeconomy. This paper introduces a novel sustainability assessment and material flow model to study biological resource utilization impacts (BIORIM) which aims to address these challenges. The model represents important bioeconomic production systems (e.g. arable land, dairy farm, biogas plant) and considers input properties, production parameters such as site conditions or management, and different emission factors when calculating products and emissions. For this reason, the functions that represent the conversion processes need to be executed in the correct order when analysing larger production networks. The model keeps full track of mass, carbon and nitrogen flows, and therefore allows assessing how much is lost during processing, ending up in the produce and is recycled. The modelling approach is illustrated at the example of a dairy farm where dairy manure is used as an organic fertilizer for fodder crop production in the following year. This is compared to a scenario that includes a biogas plant. The comparison of manure storage to biogas production reveals that this change does not only affects direct emissions. Biogas production leads to higher carbon losses and thus negatively affects the humus balance. The manure storage, on the other hand, leads to higher nitrogen losses, which result in a lower fertilization value of the manure, and therefore a higher amount of mineral fertilizer is required in the following year. Together with the emission savings from the energy production, this results in a lower global warming effect of the biogas scenario. The study shows that it is important to consider the interplay of processes when assessing impacts of bioeconomic production systems.

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来源期刊
Sustainable Production and Consumption
Sustainable Production and Consumption Environmental Science-Environmental Engineering
CiteScore
17.40
自引率
7.40%
发文量
389
审稿时长
13 days
期刊介绍: Sustainable production and consumption refers to the production and utilization of goods and services in a way that benefits society, is economically viable, and has minimal environmental impact throughout its entire lifespan. Our journal is dedicated to publishing top-notch interdisciplinary research and practical studies in this emerging field. We take a distinctive approach by examining the interplay between technology, consumption patterns, and policy to identify sustainable solutions for both production and consumption systems.
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