Energy and material flows of megacities

Christopher A. Kennedy; Iain Stewart; Angelo Facchini; Igor Cersosimo; Renata Mele; Bin Chen; Mariko Uda; Arun Kansal; Anthony Chiu; Kwi Gon Kim; Carolina Dubeux; Emilio Lebre La Rovere; Bruno Cunha; Stephanie Pincetl; James Keirstead; Sabine Barles; Semerdanta Pusaka; Juniati Gunawan; Michael Adegbile; Mehrdad Nazariha; Shamsul Hoque; Peter J. Marcotullio; Florencia González Otharán; Tarek Genena; Nadine Ibrahim; Rizwan Farooqui; Gemma Cervantes; Ahmet Duran Sahin

doi:10.1073/pnas.1504315112

Energy and material flows of megacities

Christopher A. Kennedy^*, Iain Stewart, Angelo Facchini, Igor Cersosimo, Renata Mele, Bin Chen, Mariko Uda, Arun Kansal, Anthony Chiu, Kwi Gon Kim, Carolina Dubeux, Emilio Lebre La Rovere, Bruno Cunha, Stephanie Pincetl, James Keirstead, Sabine Barles, Semerdanta Pusaka, Juniati Gunawan, Michael Adegbile, Mehrdad NazarihaShamsul Hoque, Peter J. Marcotullio, Florencia González Otharán, Tarek Genena, Nadine Ibrahim, Rizwan Farooqui, Gemma Cervantes, Ahmet Duran Sahin

^*Corresponding author for this work

Department of Meteorological Engineering

Research output: Contribution to journal › Article › peer-review

347 Citations (Scopus)

Abstract

Understanding the drivers of energy and material flows of cities is important for addressing global environmental challenges. Accessing, sharing, and managing energy and material resources is particularly critical for megacities, which face enormous social stresses because of their sheer size and complexity. Here we quantify the energy and material flows through the world's 27 megacities with populations greater than 10 million people as of 2010. Collectively the resource flows through megacities are largely consistent with scaling laws established in the emerging science of cities. Correlations are established for electricity consumption, heating and industrial fuel use, ground transportation energy use, water consumption, waste generation, and steel production in terms of heating-degree-days, urban form, economic activity, and population growth. The results help identify megacities exhibiting high and low levels of consumption and those making efficient use of resources. The correlation between per capita electricity use and urbanized area per capita is shown to be a consequence of gross building floor area per capita, which is found to increase for lower-density cities. Many of the megacities are growing rapidly in population but are growing even faster in terms of gross domestic product (GDP) and energy use. In the decade from 2001-2011, electricity use and ground transportation fuel use in megacities grew at approximately half the rate of GDP growth.

Original language	English
Pages (from-to)	5985-5990
Number of pages	6
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	112
Issue number	19
DOIs	https://doi.org/10.1073/pnas.1504315112
Publication status	Published - 12 May 2015

Funding

Funders	Funder number
National Science Foundation	1229429

Keywords

Industrial ecology
Sustainability
Sustainable development
Urban metabolism
Urbanization

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1073/pnas.1504315112

Cite this

Kennedy, C. A., Stewart, I., Facchini, A., Cersosimo, I., Mele, R., Chen, B., Uda, M., Kansal, A., Chiu, A., Kim, K. G., Dubeux, C., La Rovere, E. L., Cunha, B., Pincetl, S., Keirstead, J., Barles, S., Pusaka, S., Gunawan, J., Adegbile, M., ... Sahin, A. D. (2015). Energy and material flows of megacities. Proceedings of the National Academy of Sciences of the United States of America, 112(19), 5985-5990. https://doi.org/10.1073/pnas.1504315112

@article{c0dc53e4d7fd40dc956571edf414f60e,

title = "Energy and material flows of megacities",

abstract = "Understanding the drivers of energy and material flows of cities is important for addressing global environmental challenges. Accessing, sharing, and managing energy and material resources is particularly critical for megacities, which face enormous social stresses because of their sheer size and complexity. Here we quantify the energy and material flows through the world's 27 megacities with populations greater than 10 million people as of 2010. Collectively the resource flows through megacities are largely consistent with scaling laws established in the emerging science of cities. Correlations are established for electricity consumption, heating and industrial fuel use, ground transportation energy use, water consumption, waste generation, and steel production in terms of heating-degree-days, urban form, economic activity, and population growth. The results help identify megacities exhibiting high and low levels of consumption and those making efficient use of resources. The correlation between per capita electricity use and urbanized area per capita is shown to be a consequence of gross building floor area per capita, which is found to increase for lower-density cities. Many of the megacities are growing rapidly in population but are growing even faster in terms of gross domestic product (GDP) and energy use. In the decade from 2001-2011, electricity use and ground transportation fuel use in megacities grew at approximately half the rate of GDP growth.",

keywords = "Industrial ecology, Sustainability, Sustainable development, Urban metabolism, Urbanization",

author = "Kennedy, {Christopher A.} and Iain Stewart and Angelo Facchini and Igor Cersosimo and Renata Mele and Bin Chen and Mariko Uda and Arun Kansal and Anthony Chiu and Kim, {Kwi Gon} and Carolina Dubeux and {La Rovere}, {Emilio Lebre} and Bruno Cunha and Stephanie Pincetl and James Keirstead and Sabine Barles and Semerdanta Pusaka and Juniati Gunawan and Michael Adegbile and Mehrdad Nazariha and Shamsul Hoque and Marcotullio, {Peter J.} and Othar{\'a}n, {Florencia Gonz{\'a}lez} and Tarek Genena and Nadine Ibrahim and Rizwan Farooqui and Gemma Cervantes and Sahin, {Ahmet Duran}",

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Kennedy, CA, Stewart, I, Facchini, A, Cersosimo, I, Mele, R, Chen, B, Uda, M, Kansal, A, Chiu, A, Kim, KG, Dubeux, C, La Rovere, EL, Cunha, B, Pincetl, S, Keirstead, J, Barles, S, Pusaka, S, Gunawan, J, Adegbile, M, Nazariha, M, Hoque, S, Marcotullio, PJ, Otharán, FG, Genena, T, Ibrahim, N, Farooqui, R, Cervantes, G & Sahin, AD 2015, 'Energy and material flows of megacities', Proceedings of the National Academy of Sciences of the United States of America, vol. 112, no. 19, pp. 5985-5990. https://doi.org/10.1073/pnas.1504315112

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T1 - Energy and material flows of megacities

AU - Kennedy, Christopher A.

AU - Stewart, Iain

AU - Facchini, Angelo

AU - Cersosimo, Igor

AU - Mele, Renata

AU - Chen, Bin

AU - Uda, Mariko

AU - Kansal, Arun

AU - Chiu, Anthony

AU - Kim, Kwi Gon

AU - Dubeux, Carolina

AU - La Rovere, Emilio Lebre

AU - Cunha, Bruno

AU - Pincetl, Stephanie

AU - Keirstead, James

AU - Barles, Sabine

AU - Pusaka, Semerdanta

AU - Gunawan, Juniati

AU - Adegbile, Michael

AU - Nazariha, Mehrdad

AU - Hoque, Shamsul

AU - Marcotullio, Peter J.

AU - Otharán, Florencia González

AU - Genena, Tarek

AU - Ibrahim, Nadine

AU - Farooqui, Rizwan

AU - Cervantes, Gemma

AU - Sahin, Ahmet Duran

PY - 2015/5/12

Y1 - 2015/5/12

N2 - Understanding the drivers of energy and material flows of cities is important for addressing global environmental challenges. Accessing, sharing, and managing energy and material resources is particularly critical for megacities, which face enormous social stresses because of their sheer size and complexity. Here we quantify the energy and material flows through the world's 27 megacities with populations greater than 10 million people as of 2010. Collectively the resource flows through megacities are largely consistent with scaling laws established in the emerging science of cities. Correlations are established for electricity consumption, heating and industrial fuel use, ground transportation energy use, water consumption, waste generation, and steel production in terms of heating-degree-days, urban form, economic activity, and population growth. The results help identify megacities exhibiting high and low levels of consumption and those making efficient use of resources. The correlation between per capita electricity use and urbanized area per capita is shown to be a consequence of gross building floor area per capita, which is found to increase for lower-density cities. Many of the megacities are growing rapidly in population but are growing even faster in terms of gross domestic product (GDP) and energy use. In the decade from 2001-2011, electricity use and ground transportation fuel use in megacities grew at approximately half the rate of GDP growth.

AB - Understanding the drivers of energy and material flows of cities is important for addressing global environmental challenges. Accessing, sharing, and managing energy and material resources is particularly critical for megacities, which face enormous social stresses because of their sheer size and complexity. Here we quantify the energy and material flows through the world's 27 megacities with populations greater than 10 million people as of 2010. Collectively the resource flows through megacities are largely consistent with scaling laws established in the emerging science of cities. Correlations are established for electricity consumption, heating and industrial fuel use, ground transportation energy use, water consumption, waste generation, and steel production in terms of heating-degree-days, urban form, economic activity, and population growth. The results help identify megacities exhibiting high and low levels of consumption and those making efficient use of resources. The correlation between per capita electricity use and urbanized area per capita is shown to be a consequence of gross building floor area per capita, which is found to increase for lower-density cities. Many of the megacities are growing rapidly in population but are growing even faster in terms of gross domestic product (GDP) and energy use. In the decade from 2001-2011, electricity use and ground transportation fuel use in megacities grew at approximately half the rate of GDP growth.

KW - Industrial ecology

KW - Sustainability

KW - Sustainable development

KW - Urban metabolism

KW - Urbanization

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U2 - 10.1073/pnas.1504315112

DO - 10.1073/pnas.1504315112

M3 - Article

AN - SCOPUS:84929222987

SN - 0027-8424

VL - 112

SP - 5985

EP - 5990

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 19

ER -

Energy and material flows of megacities

Abstract

Funding

Keywords

UN SDGs

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