Powering Our Future with Trash

Categories: Waste Management, Biogeochemical Cycling

Source: Sustainable Living Library

Summary

Home – Research – Publications – Powering Our Future with Trash D I G E ST Powering Our Future with Trash RICHARD LING | MARCH 21, 2019 S HAR E O N EMERGING TECH, ELECTRICITY Waste-to-energy technology, which utilizes trash to produce viable energy, has the potential to address two of the most urgent needs of this century —waste destruction and energy demand. DOWN LOAD PDF Introduction Every year, our world produces around 2.1 billion tons of waste, which ultimately emits over 7.7 billion tons of greenhouse gases (GHGs) over a breakdown period of 20 years (Roberts 2018). Current tactics to combat GHG emissions from waste include recycling, composting, source reduction, and—the topic of this policy digest— waste-to-energy (WTE) technology. WTE technology can potentially address two of the world’s largest problems: waste destruction and energy demand (both of which will compound with population growth). To date, roughly 2,200 WTE plants are active worldwide, which constitute roughly 300 million tons of disposal capacity (Ecoprog 2018). The U.S., by comparison, currently holds around 86 WTE facilities, which account for just 0.25% of the nation’s total generation capacity (Research and Markets 2018; EIA 2017). Given WTE’s potential benefits and the U.S.’s scarce utilization of this seemingly-utopian technology, this policy digest will discuss the social, political, and economic environments that foster and inhibit WTE

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Local Knowledge Graph (26 entities)

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Stakeholders (10)

Agencies, organizations, and groups mentioned as actors in this document.

United States Environmental Protection AgencyThe World BankU.S. Army ReserveWorld Energy CouncilSolid Waste Authority of Palm BeachColumbia's Earth Engineering CenterSierra EnergyCenter for Climate and Energy Solutions

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University of PennsylvaniaKleinman Center for Energy Policy

Concepts & Topics (14)

carbon cycling greenhouse gas emissions greenhouse gas emissions biomass burning biomass burning detritus processing renewable energy detritus processing

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carbon oxidation carbon oxidation Clean Air Act standards Maximum Achievable Control Technology Standards electric power rates incineration

Species (1)

not specified

External References Cited (22)

Works cited by this document, grouped by type.

report (13)

World Bank 2018 (2018)
Ecoprog 2018 (2018)
Research and Markets 2018 (2018)
DSIRE 2018b (2018)
Roberts 2018 (2018) — Roberts

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DSIRE 2018a (2018)
DSIRE 2018d (2018)
DSIRE 2018c (2018)
DSIRE 2018e (2018)
EIA 2017 (2017)
World Energy Council 2016 (2016)
EPA 2016 (2016)
DSIRE 2014 (2014)

study (8)

Simmons et. al. 2015 (2015) — Simmons et. al.
Haneef and Memon 2014 (2014) — Haneef and Memon
Kasper 2013 (2013) — Kasper
Elliott 2013 (2013) — Elliott
Themelis et. al. 2011 (2011) — Themelis et. al.

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Sankey and Liceta 2010 (2010) — Sankey and Liceta
Tomain and Cudahy 2004 (2004) — Tomain and Cudahy
Pierce 1994 (1994) — Pierce

legislation (1)

1990 Clean Air Act Amendments (1990)

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