Book contents
- Sustainability Assessment of Urban Systems
- Sustainability Assessment of Urban Systems
- Copyright page
- Contents
- Preface
- Acknowledgments
- Contributors
- General Introduction
- Part I Theoretical Background
- Part II Integrative Approaches for Sustainability Assessment
- Part III Perspectives on Urban Sustainability
- 10 Conceptualizing Urban Systems for Sustainability Assessment: Four Powerful Metaphors
- 11 Sustainability Issues in Urban Systems from a Metabolic Perspective
- 12 Urban-Industrial Supply Systems
- 13 Indicators for Assessing the Sustainability of Cities
- 14 Ontology-Based Integration of Urban Sustainability Indicators
- Part IV Focal Points of Urban Sustainability
- Index
- References
12 - Urban-Industrial Supply Systems
From Global Challenges to Strong Urban Sustainability
from Part III - Perspectives on Urban Sustainability
Published online by Cambridge University Press: 27 March 2020
By
Book contents
- Sustainability Assessment of Urban Systems
- Sustainability Assessment of Urban Systems
- Copyright page
- Contents
- Preface
- Acknowledgments
- Contributors
- General Introduction
- Part I Theoretical Background
- Part II Integrative Approaches for Sustainability Assessment
- Part III Perspectives on Urban Sustainability
- 10 Conceptualizing Urban Systems for Sustainability Assessment: Four Powerful Metaphors
- 11 Sustainability Issues in Urban Systems from a Metabolic Perspective
- 12 Urban-Industrial Supply Systems
- 13 Indicators for Assessing the Sustainability of Cities
- 14 Ontology-Based Integration of Urban Sustainability Indicators
- Part IV Focal Points of Urban Sustainability
- Index
- References
Summary
Global un-sustainability is shaped by a form of urbanisation that has created urban systems with disproportionate natural-resource consumption. This results in severe damage to the global ecosphere. The causal mechanisms of this relationship can be related to Castell’s ‘dominance of the space of flows’ or expressed in terms of World City Networks. Critical to sustainable transformation are material-resource and energy-network flows, understood as teleconnections between urban sinks and planetary sources. So far, there is no interpretation of this nested global urban-industrial network and its correlated impacts that builds links to a sustainability transformation strategy. Concepts such as global commodity chains (GCC) offer valuable impetus, as they address research on material and product flows in globalised urban-industrial finance, information, and service networks. However, to achieve levels of sustainability transformation, a perspective that goes beyond an analytical and descriptive lens is necessary with regard to the design of sustainable supply chains. Moreover, qualitative extensions of Sustainable Supply-Chain Management (SSCM) in the understanding of ecological economics provide possibilities for solutions. In order to pave the way for this further, this chapter provides an outline of a multi-domain framework for sustainable urban-industrial supply systems based on strong sustainability and nested systems organisation theory.
Keywords
- Type
- Chapter
- Information
- Sustainability Assessment of Urban Systems , pp. 290 - 310Publisher: Cambridge University PressPrint publication year: 2020
References
Ahern, J. (2011). From fail-safe to safe-to-fail: Sustainability and resilience in the new urban world. Landscape and Urban Planning, 100(4), 341–343.CrossRefGoogle Scholar
Amin, A., & Thrift, N. (2002). Cities: Reimagining the Urban. Cambridge. Polity Press.Google Scholar
Bai, X. (2007). Industrial ecology and the global impacts of cities. Journal of Industrial Ecology, 11(2), 1–6.Google Scholar
Bettencourt, L., & West, G. (2010). A unified theory of urban living. Nature, 467 (7318).Google Scholar
Bossel, H. (2007). Systems and Models: Complexity, Dynamics, Evolution, Sustainability. Norderstedt, Germany: BoD–Books on Demand.Google Scholar
Bugliarello, G. (2006). Urban sustainability: Dilemmas, challenges and paradigms. Technology in Society, 28(1–2): 19–26.CrossRefGoogle Scholar
Cajot, S., Peter, M., Bahu, J.-M., Koch, A., & Maréchal, F. (2015). Energy planning in the urban context: Challenges and perspectives. Energy Procedia, 78: 3366–3371.Google Scholar
Carter, C. R., & Rogers, D. S. (2008). A framework of sustainable supply chain management: Moving toward new theory. International Journal of Physical Distribution & Logistics Management, 38(5), 360–387.CrossRefGoogle Scholar
Castells, M. (1992). The world has changed: Can planning change? Landscape and Urban Planning 22(1): 73–78.CrossRefGoogle Scholar
Castells, M. (2002). Urban sociology in the twenty-first century. Cidades, Comunidades e Territórios, (5).Google Scholar
Chrysoulakis, N., Lopes, M., & San José, R., et al. (2013). Sustainable urban metabolism as a link between bio-physical sciences and urban planning: The BRIDGE project. Landscape and Urban Planning, 112, 100–117.Google Scholar
Coe, N. M., Dicken, P., & Hess, M. (2008). Global production networks: realizing the potential. Journal of Economic Geography, 8(3), 271–295.Google Scholar
Costanza, R., Daly, H. E., & Bartholomew, J. A. (1992). Goals, agenda and policy recommendations for ecological economics. Ecological Economics, 1–12.Google Scholar
Costanza, R., Wainger, L., Folke, C., & Mäler, K. G. (1993). Modeling complex ecological economic systems: Toward an evolutionary, dynamic understanding of people and nature. BioScience, 43(8), 545–555.Google Scholar
Costanza, R., & Patten, B. C. (1995). Defining and predicting sustainability. Ecological Economics, 15(3), 193–196.Google Scholar
Cooper, M. C., Lambert, D. M., & Pagh, J. D. (1997). Supply chain management: More than a new name for logistics. The International Journal of Logistics Management, 8(1), 1–14.Google Scholar
Daly, H. E. (1997). Beyond Growth: The Economics of Sustainable Development. Boston: Beacon Press.Google Scholar
Derudder, B., & Witlox, F. (2010). World cities and global commodity chains: An introduction. Global Networks, 10(1), 1–11.CrossRefGoogle Scholar
Ekins, P., Simon, S., Deutsch, L., Folke, C., & De Groot, R. (2003). A framework for the practical application of the concepts of critical natural capital and strong sustainability. Ecological Economics, 44(2–3), 165–185.Google Scholar
Findeisen, W., Bailey, F. N., Brdys, M., Malinowski, K., Tatjewski, P., & Wozniak, A. (1980). Control and Coordination in Hierarchical Systems. London: Wiley.Google Scholar
Friedmann, J. (1986). The World City hypothesis. Development and Change, 17(1), 69–83.Google Scholar
Gereffi, G., & Korzeniewicz, M. (Eds.) (1994). Commodity Chains and Global Capitalism. Westport: Praeger Publishers.Google Scholar
Girardet, H. (2000). Cities and the culture of sustainability. In Earth Summit 2002: A New Deal: Earthscan. New York: Routledge, pp. 202–211.Google Scholar
Grimm, N. B., Pickett, S. T., Hale, R. L., & Cadenasso, M. L. (2017). Does the ecological concept of disturbance have utility in urban social-ecological-technological systems? Ecosystem Health and Sustainability, 3(1).Google Scholar
Grimm, N., Faeth, S., Golubiewski, N., et al. (2008). Global Change and the ecology of cities. Science, 319(5864), 756–760.Google Scholar
Gruchmann, T., Melkonyan, A., & Krumme, K., (2018). Logistics business transformation for sustainability: Assessing the role of the lead sustainability service provider (6PL). Logistics. 2018, 2(4), 25.Google Scholar
Hashemian, B., Massaro, E., Bojic, I., Arias, J. M., Sobolevsky, S., & Ratti, C. (2017). Socioeconomic characterization of regions through the lens of individual financial transactions. PLoS ONE, 12(11), e0187031.CrossRefGoogle ScholarPubMed
Harvey, D. (1996). Justice, Nature and the Geography of Difference. Oxford: Blackwell Publishers.Google Scholar
Held, D., McGrew, A., Goldblatt, D., & Perraton, J. (2000). Global transformations: Politics, Economics and Culture. Stanford: Stanford University Press, pp. 1–28.Google Scholar
Hesse, M. (2010). Cities, material flows and the geography of spatial interaction: Urban places in the system of chains. Global Networks, 10(1), 75–91.Google Scholar
Hoekstra, A. Y. (2015). The sustainability of a single activity, production process or product. Ecological Indicators, 57, 82–84.Google Scholar
Hoekstra, A. Y., & Wiedmann, T. O. (2014). Humanity’s unsustainable environmental footprint. Science, 344(6188), 1114–1117.Google Scholar
Seto, K. C., Dhakal, S., Bigio, A., et al. (2014). Human settlements, infrastructure and spatial planning. In Edenhofer, O, Pichs-Madruga, R, Sokona, Y et al. (eds.), Climate Change 2014: Mitigation of Climate Change: Working Group III Contribution to the IPCC Fifth Assessment Report. Cambridge and New York: Cambridge University Press, pp. 923–1000.Google Scholar
Jackson, T. (2005). Live better by consuming less? Is there a “double dividend” in sustainable consumption? Journal of Industrial Ecology, 9(1–2), 19–36.Google Scholar
Kalmykova, Y., Rosado, L., & Patrício, J. (2015). Urban economies resource productivity and decoupling: metabolism trends of 1996–2011 in Sweden, Stockholm, and Gothenburg. Environmental Science & Technology, 49(14), 8815–8823.Google Scholar
Keivani, R. (2010). A review of the main challenges to urban sustainability. International Journal of Urban Sustainable Development, 1(1–2), 5–16.Google Scholar
Kestemont, B. (2015). The conditions for strong sustainability. Cosmopolis – A review of cosmopolitics, 1, 35–43.Google Scholar
King, A. (2009). Postcolonial cities. In Kitchin, R & Thrift, N (eds.), International Encyclopedia of Human Geography. Amsterdam: Elsevier, pp. 321–326.Google Scholar
Krumme, K. (2016). Sustainable development and social-ecological-technological systems (SETS): Resilience as a guiding principle in the urban-industrial nexus. Journal of Renewable Energy & Sustainable Development, 2(1).Google Scholar
Krumme, K. (2020). Supply chains and systems of sustainability: An attempt to close the gap. In Melkonyan, A & Krumme, K (eds.), Innovative Logistics Services and Sustainable Lifestyles:Interdependencies, Transformation Strategies and Decision Making. Cham: Springer Nature, pp. 21–60.Google Scholar
Krumme, K., & Melkonyan, A. (2020). Research and innovation perspectives for integrated supply chains in a sustainable economy. In Melkonyan, A & Krumme, K (eds.), Innovative Logistics Services and Sustainable Lifestyles: Interdependencies, Transformation Strategies and Decision Making. Cham: Springer Nature, pp. 289–307.Google Scholar
Linton, J. D., Klassen, R., & Jayaraman, V. (2007). Sustainable supply chains: An introduction. Journal of Operations Management, 25(6), 1075–1082.Google Scholar
Liu, J. Q., Hull, V., Batistella, M., et al. (2013). Framing sustainability in a telecoupled world. Ecology & Society 18(2), 26.Google Scholar
Liu, J., Mooney, H., Hull, V., et al. (2015). Systems integration for global sustainability. Science, 347(6225), 1258832.Google ScholarPubMed
Lorek, S., & Spangenberg, J. H. (2014). Sustainable consumption within a sustainable economy: Beyond green growth and green economies. Journal of Cleaner Production, 63, 33–44.CrossRefGoogle Scholar
Marchal, V., Dellink, R., Van Vuuren, D., et al. (2011). OECD environmental outlook to 2050. Organisation for Economic Co-operation and Development, 8, 397–413.Google Scholar
McHale, M., Pickett, S., Barbosa, O., et al. (2015). The new global urban realm: Complex, connected, diffuse, and diverse social-ecological systems. Sustainability, 7(5), 5211–5240.Google Scholar
McPhearson, T., Pickett, S. T., Grimm, N. B., et al. (2016). Advancing urban ecology toward a science of cities. BioScience, 66(3), 198–212.Google Scholar
Melkonyan, A., & Krumme, K. (2020). Integrating perspectives of logistics and lifestyles for a sustainable economy. In Melkonyan, A & Krumme, K (eds.), Innovative Logistics Services and Sustainable Lifestyles: Interdependencies, Transformation Strategies and Decision Making. Cham: Springer Nature, pp. 3–20.Google Scholar
Meadows, D. H., & Wright, D. (2008). Thinking in Systems: A Primer. White River Junction: Chelsea Green Publishing.Google Scholar
Mesarovic, M. D., Takahara, Y., & Macko, D. (1970). Theory of Hierarchical, Multilevel Systems. Cambridge, MA: Academic Press.Google Scholar
Moore, J. (2015). Ecological footprints and lifestyle archetypes: Exploring dimensions of consumption and the transformation needed to achieve urban sustainability. Sustainability, 7(4), 4747–4763.Google Scholar
Moser, S. C., & Hart, J. A. F. (2015). The long arm of climate change: Societal teleconnections and the future of climate change impacts studies. Climatic Change, 129(1–2), 13–26.Google Scholar
Neumayer, E. (2003). Weak Versus Strong Sustainability: Exploring the Limits of Two Opposing Paradigms. Cheltenham: Edward Elgar Publishing.Google Scholar
Newman, P. (1999). Sustainability and cities: Extending the metabolism model. Landscape and Urban Planning, 44(4), 219–226.Google Scholar
Newman, P. (2006). The environmental impact of cities. Environment and Urbanization 18(2), 275–295.Google Scholar
Newman, P., & Jennings, I. (2012). Cities as Sustainable Ecosystems: Principles and Practices. Washington, DC: Island Press.Google Scholar
O’Rourke, D. (2014). The science of sustainable supply chains. Science, 344(6188), 1124–1127.Google Scholar
Ostrom, E. (2009). A general framework for analyzing sustainability of social-ecological systems. Science, 325(5939), 419–422.Google Scholar
Pelenc, J., & Ballet, J. (2015). Strong sustainability, critical natural capital and the capability approach. Ecological Economics, 112, 36–44.Google Scholar
Pickett, S. T., Burch, W. R., Dalton, S. E., Foresman, T. W., Grove, J. M., & Rowntree, R. (1997). A conceptual framework for the study of human ecosystems in urban areas. Urban ecosystems, 1(4), 185–199.Google Scholar
Rees, W. E. (1992). Ecological footprints and appropriated carrying capacity: what urban economics leaves out. Environment and Urbanization, 4(2), 121–130.Google Scholar
Rees, W., & Wackernagel, M. (1996). Urban ecological footprints: Why cities cannot be sustainable – and why they are a key to sustainability. Environmental Impact Assessment Review 16(4–6): 223–248.Google Scholar
Rodrigue, J. P., & Hesse, M. (2006). Global Production Networks and the role of logistics and transportation. Growth and Change, 37(4), 499–509.Google Scholar
Sassen, S. (1991). The Global City: New York, London, Tokyo, Princeton University Press.Google Scholar
Sassen, S. (2002). Locating cities on global circuits. In Sassen, S (ed.), Global Networks, Linked Cities. New York: Routledge, pp. 1–37.Google Scholar
Sassen, S. (2009). Human settlement development: The central role of cities in our environment’s future: Constraints and possibilities. UNESCO: Encyclopedia of Life Support Systems (EOLSS). www.eolss.net/Google Scholar
Sassen, S. (2010a). Global inter‐city networks and commodity chains: Any intersections? Global Networks 10(1): 150–163.Google Scholar
Sassen, S. (2010b). Cities are at the center of our environmental future. S.A.P.I.EN.S, 2(3).Google Scholar
Sassen, S., & Dotan, N. (2011). Delegating, not returning, to the biosphere: How to use the multi-scalar and ecological properties of cities. Global Environmental Change, 21(3), 823–834.Google Scholar
Sassen, S. (2015). Cities: Capital, global, and world. In Wright, J. D. (ed.), International Encyclopedia of the Social & Behavioral Sciences. Amsterdam: Elsevier, pp. 585–592.Google Scholar
Schandl, H., Fischer‐Kowalski, M., West, J., et al. (2018). Global material flows and resource productivity: forty years of evidence. Journal of Industrial Ecology, 22(4), 827–838.CrossRefGoogle Scholar
Seitzinger, S. P., Svedin, U., Crumley, C. L., et al. (2012). Planetary stewardship in an urbanizing world: Beyond city limits. AMBIO: A Journal of the Human Environment, 41, 787–794.Google Scholar
Seto, K. C. , Golden, J. S., Alberti, M., & Turner, B. L. (2017). Sustainability in an urbanizing planet. Proceedings of the National Academy of Sciences, 114(34), 8935–8938.Google Scholar
Seto, K. C., Reenberg, A., Boone, C. G., et al. (2012). Urban land teleconnections and sustainability. Proceedings of the National Academy of Sciences, 109(20), 7687–7692.Google Scholar
Seuring, S., & Müller, M. (2008). From a literature review to a conceptual framework for sustainable supply chain management. Journal of Cleaner Production, 16(15), 1699–1710.Google Scholar
Sheffi, Y., & RiceJr., J. B. (2005). A supply chain view of the resilient enterprise. MIT Sloan Management Review, 47(1), 41.Google Scholar
Steffen, W., Richardson, K., & Rockström, J., et al. (2015). Planetary boundaries: Guiding human development on a changing planet. Science, 347(6223), 1259855.Google Scholar
Taylor, P. (1995). World cities and territorial states: The rise and fall of their mutuality. In Knox, P. L. & Taylor, P. J. (eds.), World Cities in a World System. Cambridge and New York: Cambridge University Press, pp. 48–62.Google Scholar
Taylor, P. (1997). Hierarchical tendencies amongst world cities: A global research proposal. Cities, 14(6), 323–332.Google Scholar
Taylor, P., & Csomós, G. (2012). Cities as control and command centres: Analysis and interpretation. Cities, 29(6), 408–411.Google Scholar
Taylor, P., & Derudder, B. (2015). World City Network: A Global Urban Analysis. New York: Routledge.Google Scholar
Thomson, G., & Newman, P. (2018). Urban fabrics and urban metabolism: From sustainable to regenerative cities. Resources, Conservation and Recycling, 132, 218–229.Google Scholar
Torreggiani, D., Dall’Ara, E., & Tassinari, P. (2012). The urban nature of agriculture: Bidirectional trends between city and countryside. Cities, 29(6), 412–416.Google Scholar
Ullman, E. L. (1953). Human geography and area research. Annals of the Association of American Geographers, 43(1), 54–66.Google Scholar
United Nations. (2017). World Population Prospects: The 2017 Revision. United Nations.Google Scholar
Wackernagel, M., Kitzes, J., Moran, D., Goldfinger, S., & Thomas, M. (2006). The ecological footprint of cities and regions: Comparing resource availability with resource demand. Environment and Urbanization, 18(1), 103–112.Google Scholar
Worldwatch Institute (2016). State of the World: Can a City Be Sustainable? Washington, DC: Island Press.Google Scholar
Weber, M. (1921). Die Stadt. Archiv für Sozialwissenschaft und Sozialpolitik, 47: 621ff.Google Scholar
Wiedmann, T., Minx, J., Barrett, J., & Wackernagel, M. (2006). Allocating ecological footprints to final consumption categories with input–output analysis. Ecological Economics, 56(1), 28–48.Google Scholar
Wiedmann, T. O., Schandl, H., Lenzen, M., et al. (2015). The material footprint of nations. Proceedings of the National Academy of Sciences, 112(20), 6271–6276.Google Scholar
Wiek, A., Ness, B., Schweizer-Ries, P., Brand, F. S., & Farioli, F. (2012). From complex systems analysis to transformational change: A comparative appraisal of sustainability science projects. Sustainability Science, 7(1), 5–24.Google Scholar
Yeung, H. W. C. (1994). Critical reviews of geographical perspectives on business organizations and the organization of production: Towards a network approach. Progress in Human Geography, 18(4), 460–490.Google Scholar
Zasada, I., Loibl, W., Berges, R., et al. (2013). Rural–urban regions: A spatial approach to define urban–rural relationships in Europe. In Nilsson, K, Pauleit, S, Bell, S, Aalbers, C & Nielsen, T. S. (eds.), Peri-urban futures: Scenarios and models for land use change in Europe. Berlin: Springer, pp. 45–68.Google Scholar