An emergy evaluation of complexity, information and technology, towards maximum power and zero emissions
- 作者:Sergio Ulgiati ; Silvia Bargigli ; Marco Raugei
- 关键词:Zero emissions ; Emergy life cycle assessment ; Maximum power principle
- 刊名:Journal of Cleaner Production
- 出版年:2007
- 期刊代码:47_09596526
- 类别:ce
- 出版时间:September 2007
- 卷:15
- 期:13-14
- 页码:1359-1372
- 文件大小:477 K
摘要
This paper mostly deals with the role of energy, matter and information flows within both environmental and human-dominated systems. Sustainable growth and development of both kinds of systems require optimum use of available resources for maximum power output, as suggested by Lotka's Maximum Power Principle [Lotka AJ. Contribution to the energetics of evolution. In: Proceedings of the national academy of sciences of the United States of America, vol. 8. 1922, p. 147–50; Lotka AJ. Natural selection as a physical principle. In: Proceedings of the national academy of sciences of the United States of America, vol. 8. 1922, p. 151–5.], recently restated by Odum [Odum HT. Maximum power and efficiency: a rebuttal. Ecol Model 1983;20:71–82; Odum HT. Environmental accounting. Emergy and environmental decision making. N.Y.: John Wiley & Sons; 1996.] as Maximum Em-Power Principle within the framework of his Emergy Synthesis approach. In times of declining resources, this principle translates into increased efficiency and optimum use of any kind of waste and co-products. Ecosystems and any self-organizing systems always apply this strategy and their selection–evolution mechanisms are based on their ability of growing on any untapped resource available. In order to do so, they increase the number of components and patterns for resource degradation in order to optimize the resource throughput and power output. Such a strategy also applies to human-dominated, economic systems, where the ability of dealing with co-products and wastes by means of appropriate designs as well as reuse and recycling processes may lead to “zero-emission” patterns (increased complexity, optimal resource throughput, minimization of emissions, resource exchange among system's components) and be the key for successful and sustainable development. In this paper Life Cycle Assessment and Emergy Synthesis approaches are suggested as joint tools for qualitative and quantitative evaluation of progresses towards industrial symbiosis and more sustainable production and consumption patterns within a zero emission framework.