化学品租赁公司(Ch.L.)与舍伍德阴谋

IF 3.6 Q2 ENVIRONMENTAL SCIENCES
G. Karakatsanis, Christos Makropoulos
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引用次数: 0

摘要

尽管循环经济(CE)通过提供广泛的替代工程解决方案取得了显著的技术进步,但其大规模商业化的障碍在于采用那些能够准确描述资源回收所产生价值的商业和金融模式。从废物矩阵中回收资源,可以减少对原始资源的需求,从而就地保护自然保护区,还可以减少废物排放,从而保护环境承载能力。资源回收的标准商业模式是产业共生(IS),在这种模式下,产业以集群形式组织起来,并分配废物矩阵的处理过程,从而以最优成本实现有价值资源的回收。我们的工作是在舍伍德图(SP)的分析框架内,为从废水基质中回收增值化合物(VAC),开发出一种化学租赁(Ch.L.)合同的连贯微观经济架构。舍伍德图描述了 VAC 在废水基质中的稀释程度与其回收成本之间的关系。ChL 将 SP 作为一种金融合约进行设计,以市场最低成本和互惠互利的方式激发产业协同效应,在目标稀释水平上提供 VAC。在此背景下,我们开发了一种 ChL 市场类型学,即通过库尔贝-莱布勒发散度(DKL)度量,哪个行业在每个稀释水平上回收 VAC 的成本效率最高,其信息完整性决定了市场支配地位。反过来,我们通过三个 ChL 合同定价系统、它们的盈利极限以及它们在不同市场类型下的拟合潜力来模拟行业间如何分配报酬。最后,我们讨论了 ChL 金融工程在资源回收和自然资本保护三大重要支柱方面的新兴应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chemical Leasing (Ch.L.) and the Sherwood Plot
Although the Circular Economy (CE) has made remarkable technological progress by offering a wide range of alternative engineering solutions, an obstacle for its large-scale commercialization is nested in the adoption of those business and financial models that accurately depict the value generated from resource recovery. Recovering a resource from a waste matrix conserves natural reserves in situ by reducing demand for virgin resources, as well as conserving environmental carrying capacities by reducing waste discharges. The standard business model for resource recovery is Industrial Symbiosis (IS), where industries organize in clusters and allocate the process of waste matrices to achieve the recovery of a valuable resource at an optimal cost. Our work develops a coherent microeconomic architecture of Chemical Leasing (Ch.L.) contracts within the analytical framework of the Sherwood Plot (SP) for recovering a Value-Added Compound (VAC) from a wastewater matrix. The SP depicts the relationship between the VAC’s dilution in the wastewater matrix and its cost of recovery. ChL is engineered on the SP as a financial contract, motivating industrial synergies for delivering the VAC at the target dilution level at the market’s minimum cost and with mutual profits. In this context, we develop a ChL market typology where information completeness on which industry is most cost-efficient in recovering a VAC at every dilution level determines market dominance via a Kullback–Leibler Divergence (DKL) metric. In turn, we model how payoffs are allocated between industries via three ChL contract pricing systems, their profitability limits, and their fitting potential by market type. Finally, we discuss the emerging applications of ChL financial engineering in relation to three vital pillars of resource recovery and natural capital conservation.
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来源期刊
Resources
Resources Environmental Science-Nature and Landscape Conservation
CiteScore
7.20
自引率
6.10%
发文量
0
审稿时长
11 weeks
期刊介绍: Resources (ISSN 2079-9276) is an international, scholarly open access journal on the topic of natural resources. It publishes reviews, regular research papers, communications and short notes, and there is no restriction on the length of the papers. Our aim is to encourage scientists to publish their experimental and theoretical research in as much detail as possible. Full experimental and methodical details must be provided so that the results can be reproduced. There are, in addition, unique features of this journal: manuscripts regarding research proposals and research ideas will be particularly welcomed, electronic files or software regarding the full details of the calculation and experimental procedure, if unable to be published in a normal way, can be deposited as supplementary material. Subject Areas: natural resources, water resources, mineral resources, energy resources, land resources, plant and animal resources, genetic resources, ecology resources, resource management and policy, resources conservation and recycling.
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