Sustainable development within planetary boundaries: a functional revision of the definition based on the thermodynamics of complex social-ecological systems

IF 0.8 Q4 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY
B. Muys
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引用次数: 10

Abstract

The dominant paradigm of sustainable development (SD) where the environment is just the third pillar of SD has proven inadequate to keep humanity within the safe operational space determined by biophysical planetary boundaries. This implies the need for a revised definition compatible with a nested model of sustainable development, where humanity forms part of the overall social-ecological system, and that would allow more effective sustainable development goals and indicators. In this paper an alternative definition is proposed based on the thermodynamics of open systems applied to ecosystems and human systems. Both sub- systems of the global social-ecological system show in common an increased capability of buffering against disturbances as a consequence of an internal increase of order. Sustainable development is considered an optimization exercise at different scales in time and space based on monitoring the change in the exergy content and exergy dissipation of these two sub- systems of the social-ecological system. In common language it is the increase of human prosperity and well-being without loss of the structure and functioning of the ecosystem. This definition is functional as it allows the straightforward selection of quantitative indicators, discerning sustainable development from unsustainable development, unsustainable stagnation and sustainable retreat. The paper shows that the new definition is compatible with state of the art thinking on ecosystem services, the existence of regime shifts and societal transitions, and resilience. One of the largest challenges in applying the definition is our insufficient understanding of the change in ecosystem structure and function as an endpoint indicator of human action, and its effect on human prosperity and well-being. This implies the continued need to use midpoint indicators of human impact and related thresholds defining the safe operating space of the present generation with respect to future generations. The proposed definition can be considered a valuable complement to the recently emerged nested system discourse of sustainable development, by offering a more quantitative tool to monitor and guide the transition of human society towards a harmonious relationship with the rest of the biosphere.
地球边界内的可持续发展:基于复杂社会生态系统热力学定义的功能修正
将环境作为可持续发展的第三个支柱的主导模式已被证明不足以将人类保持在由生物物理地球边界决定的安全操作空间内。这意味着需要订正定义,使之符合可持续发展的嵌套模式,其中人类是整个社会-生态系统的一部分,这样才能实现更有效的可持续发展目标和指标。本文从开放系统热力学的角度出发,提出了一个适用于生态系统和人类系统的定义。全球社会生态系统的两个子系统共同表现出由于内部秩序的增加而对干扰的缓冲能力的增强。可持续发展被认为是一种基于监测社会生态系统中这两个子系统的能含量和能耗散变化的不同时间和空间尺度的优化工作。用通俗的语言来说,就是在不丧失生态系统结构和功能的情况下,增加人类的繁荣和福祉。这一定义是有效的,因为它允许直接选择定量指标,将可持续发展与不可持续的发展、不可持续的停滞和可持续的倒退区分开来。本文表明,新的定义与生态系统服务、制度变迁和社会转型的存在以及恢复力的最新思想是兼容的。应用这一定义的最大挑战之一是我们对作为人类活动终点指标的生态系统结构和功能的变化及其对人类繁荣和福祉的影响理解不足。这意味着继续需要使用人类影响的中点指标和界定当代人相对于后代人的安全作业空间的相关阈值。提议的定义可以被认为是对最近出现的可持续发展的嵌套系统论述的有价值的补充,它提供了一个更定量的工具来监测和指导人类社会向与生物圈其他部分和谐关系的过渡。
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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来源期刊
Challenges in Sustainability
Challenges in Sustainability GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY-
CiteScore
3.10
自引率
0.00%
发文量
6
审稿时长
4 weeks
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