• Journal of Environmental Impact Assessment
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• v.33 no.5
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• pp.204-213
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• 2024

Greenhouse gas (GHG) emissions are a major cause of global warming and climate change, and are currently emerging as serious environmental problems worldwide. Among them, glass bottles do not decompose naturally, and a lot of resources and energy are input into the production and processing processes, so recycling of glass bottles is important in terms of resource conservation, minimizing environmental pollution, and reducing GHG. Therefore, this study created a material flow diagram of glass bottles using related statistical data such as domestic glass bottle production and processing volume. In addition, the US EPA WARM model, Germany Prognos calculation method, and Denmark Christensen's calculation method were used to estimate the greenhouse gas reduction amount of glass bottles. As a result of the study, out of about 490,000 tons of waste glass bottles discharged as municipal waste, about 300,000 tons (61.2%) were recycled, and the rest were incinerated (22.1%) and landfilled (17.3%). As of 2022, it is estimated that approximately 73,399 tons CO₂eq/yr will be reduced when applying the US EPA WARM model, approximately 52,847 tons CO₂eq/yr when applying the Prgonos calculation method, and approximately 135,201 tons CO₂eq/yr when applying the Christensen's calculation method. Further research is warranted that the methodology and GHG saving emission factors by reflecting glass recycling conditions and processes in Korea should be developed to reduce uncertainty of the results.

• Environmental and Resource Economics Review
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• v.18 no.2
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• pp.279-309
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• 2009

Greenhouse gas emissions should be precisely forecast to reduce the emissions from industrial production processes. This study calculated the direct and indirect $CO_2$ emission intensities of 401 industries using the Input-Output tables 2003 and statistical data on the amount of energy use. This study had some limitations in drawing study findings because overseas data were used given the lack of domestic data. Other limiting factors included the oil distribution problems in the oil refinery sector, re-review of carbon neutral, and insufficient consideration of waste treatment. Nonetheless, this study is very meaningful since the direct and indirect $CO_2$ emission intensities of 401 industries were calculated. Specifically, this study considered from the zero-waste perspective the effects of waste, which attract interest worldwide since coke gas and gas from the steel industry are obtained as byproducts for the first time in Korea. According to the results of the analysis of $CO_2$ emission intensity per industry, typical industries whose indirect $CO_2$ emission intensity is high include crude steel making, Remicon, steel wire rods & track rail, cast iron, and iron reinforcing rods & bar steel. These industries produce products using the raw materials produced in the industrial sector whose $CO_2$ emission intensity is high. The representative industries whose direct $CO_2$ emission intensity is high include cement, pig iron, lime & plaster products, andcoal-based compounds. These industries extract raw ore from nature and refine them into raw materials that are useful in other industries. The findings in this study can be effectively used for the following case: estimation of target $CO_2$ emission reduction level reflecting each industrial sector's characteristics, calculation of potential emission reduction of each policy to reduce $CO_2$ emissions, identification of a firm's $CO_2$ emission level, and setting of the target level of emission reduction. Moreover, the findings in this study can be utilized widely in fields such as System of integrated Environmental and Economic Accounting(SEEA) and Material Flow Analysis(MFA) as the current topic of research in Korea.