Nandan U. Ukidwe
Presidential Fellow
Department of Chemical and
Biomolecular Engineering
The Ohio
State University
Koffolt Laboratories
140
W.19th Avenue
Columbus, OH43210
Phone:
+1-614-292-4944 (office)
+1-614-286-2592 (home)
Email:
Ukidwe.1@osu.edu
Dissertation
Abstract
It is widely recognized that
conservation of natural capital is vital for sustainable development. However,
techniques for evaluating natural capital flows are not yet satisfactorily
developed. Traditional methods in engineering, economics and other disciplines
tend to focus on economic capital while ignoring the contribution of ecological
resources. In this dissertation a new thermodynamic approach is proposed that
addresses this shortcoming. The new approach, called Thermodynamic Input-Output
Analysis (TIOA), calculates degradation of energy quality in the economic and
ecological stages of the production chain of a process or product. In this
analysis energy quality is measured in terms of exergy or available energy.
TIOA synthesizes data about natural and human resource consumption and
emissions from various public domain databases. It uses concepts from systems
ecology to determine exergy flows in the ecological stages and economic
input-output analysis to determine exergy flows in the economic stages of a
production chain. This dissertation applies TIOA to analyze the 91-sector 1992
and the 488-sector 1997 representations of the US
economy. It calculates natural capital throughputs of individual industry
sectors in terms of their Ecological Cumulative Exergy Consumption (ECEC). It
also juxtaposes natural capital throughputs with economic capital throughputs
by calculating ECEC/money ratios. These ratios indicate the discrepancy between
thermodynamic work and the willingness of people to pay for economic goods and
services. ECEC/money ratios are found to decrease from basic infrastructure
industries to value-added service industries suggesting that the service
industries are better at valuing ecosystem contribution than the resource
extraction and manufacturing industries. These results are shown to have
important implications to construction of pro-ecological macroeconomic
policies. TIOA also calculates ECEC/ICEC ratios to determine the degree to
which conventional thermodynamic techniques underestimate the contribution of
ecosystems. The industry-specific ECEC/money and ICEC/money ratios are a major
improvement over single economy-wide emergy/$ ratios in emergy analysis and
similar aggregate metrics in thermoeconomics. Such industry specific ratios are
useful in hybrid thermodynamic analysis of industrial systems and provide a
unique insight into their environmental implications. This has been illustrated
by comparing alternative electricity generation systems. Industry specific
ECEC/money and ICEC/money ratios are also useful in constructing the
hierarchical thermodynamic metrics of sustainability. Such metrics have many
desirable attributes of ideal sustainability metrics such as stackability, robustness, non-perverseness in indicating
progress towards sustainability and communicable to diverse audiences and
stake-holders. In the end, this dissertation proposes a multiscale statistical
framework for Life Cycle Inventory (LCI) analysis. Such framework treats LCI as
a statistical data fusion problem and ensures maximum utilization available
data and models. It can also identify missing data, reconcile conflicting data
and determine confidence bounds on LCA results by incorporating stochastic and
subjective knowledge.
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[Tutorial]
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