Climate change is the biggest environmental issue of our times. A variety of activities to reduce greenhouse gas emissions have been in progress to observe the Kyoto Protocol. Especially, the Energy Target Scheme is created to reduce greenhouse emission with the supervision of Korean government. This includes Green-house Gas Information Systems to promote activities in the private sector to reduce green-house gas emissions, to cut a cost of energy use, and to reduce GHG emissions. Also, the system has calculated the amount of greenhouse gases. Without any additional investment, 2.75% savings are increased over the previous year. In service sector, a cooperation of customers and employees is necessary. A reduction of GHG emissions requires a proper service organization, considering an amount of investment and payback period. Without any additional investment or replacement, employees can save energy easily turning off ventilation systems an hour before employees’ departure, installing timers to turn off water purifiers and vending machines after some period of no use. The Green-house Gas Information System is similar to that of Environmental Management System. However, the Excel is the best program to calculate an amount of green-house gas emissions, and to assess for a reduced amount of GHG emissions. A goal of this research is to propose a practical method in the private sector to calculate an amount of green-house gases. The Green-house gas Information System based on Excel spreadsheet gives standards for good evaluation. The greenhouse gas information system establishes and executes the policies and objectives related to greenhouse gas emissions Similar to ISO 14001 environment management system structures, the advantages of using simplified Excel Sheet for calculating GHG emissions and reducing GHG emissions are easy to access.

Climate change has been identified as one with the greatest challenges facing nations, government, business and over future decades. Activities to reduce greenhouse gas emissions by the Kyoto Protocol, the international community has been in progress. Korea also has introduced the Emission trading system to reduce greenhouse emission from the supervision of the government. Greenhouse gases emissions quantity should be internationally recognized. Mutual Recognition Arrangement should be recognized as the same greenhouse gas emission. International recognition of domestic verification body of international mutual recognition is required. Efforts are needed to secure the equivalence between the emission rights through direct cooperation with the relative nation accreditation body. Early entry into the IAF/PAC GHG MLA is essential for demonstrating equivalence between greenhouse gas emissions. Emissions trading will also require connection to the EU ETS, California, USA, and Tokyo, Japan to link Emissions trading. In the case of establishing accreditation standards and accreditation criteria, it will be necessary to distinguish between the domestic Energy Target Management System and the Emission Trading System. Independent greenhouse gases verification bodies should be established to meet the requirements of IAF and PAC. It is necessary to revise the qualification criteria for the verification of the greenhouse gas verification body according to international standards requirements. It is necessary to support the role of accreditation bodies of domestic greenhouse gas verification bodies. It is required to join international organizations of international mutual recognition of international trade and the need for pilot projects to link greenhouse gas emissions. The core link to our emission trading system is called EU-ETS, and we will need to join the IAF/PAC GHG MLA GHG. The International Mutual Recognition Agreement (IAF) is expected to allow international interoperability of GHG emissions verification between EA and the PAC. By signing a PAC GHG MLA, it will need to be prepared to prepare for the pilot project to link the emission trading system.

The concern on the greenhouse gas emissions is increasing globally. Especially, the greenhouse gas emission from fisheries is an important issue due to Cancun Agreements Mexico in 1992 and the Kyoto protocol in 2005. Furthermore, the Korean government has a plan to reduce the GHG emissions as 5.2% compared to the BAU in fisheries until 2020. However, the investigation on the GHG emissions from Korean fisheries has not been executed much. Therefore, the quantitative analysis of GHG emissions from Korean fishery industry is needed as the first step to find a relevant way to reduce GHG emissions from fisheries. The purpose of this research is to investigate which degree of GHG emitted from the major coastal fisheries such as coastal gillnet fishery, coastal dual purpose fishery, coastal pots fishery and coastal small scale stow net fishery. Here, we calculated the GHG emission from the fisheries using the LCA (Life Cycle Assessment) method. The system boundary and input parameters for each process level are defined for LCA analysis. The fuel use coefficients of the fisheries are also calculated according to the fuel type. The GHG emissions from sea activities by the fisheries will be dealt with. Furthermore, the GHG emissions for the unit weight of fishes are also calculated with consideration to the different consuming areas. The results will be helpful to understand the circumstances of GHG emissions from Korean fisheries.

본 논문에서는 MRV 규제 대응을 위해 선박 운항효율데이터 수집 및 검증 시스템을 구축하고 이를 활용하여 해운선사 업무 지원과 국가 온실가스 인벤토리 산정이 가능한 국제해운 에너지효율 포탈 시스템을 설계하였다. 시스템 요구조건을 도출하기 위하여 EU MRV 법안과 IMO MRV 논의사항, 해운선사의 선박에너지효율과 온실가스규제 대응 및 국제해운 온실가스 통계 현황에 대하여 분석 하고 선박 에너지효율과 온실가스 배출량 데이터 수집을 위하여 선내 장비, 에너지효율 측정 장비, 운항보고서를 활용한 데이터 수집 모듈과 선박에서 수집된 데이터를 육상으로 전송하기 위해 관리가 용이하고 사용량이 최소화된 데이터베이스기반 전송 모듈을 설계하 였다. 수집된 데이터의 표준보고양식 변환, 모니터링, 통계 및 분석, 검증, 보고서 자동생성과 국가 온실가스 인벤토리 지원이 가능한 국제해운 에너지 포탈시스템을 설계하였다.

The study was conducted to determine greenhouse gas (GHG) inventories in grasslands. After ‘Low Carbon Green Growth’ was declared a national vision on 2008, Medium-term greenhouse gas reduction was anticipated for 30% reduction compared to Business As Usual (BAU) by 2020. To achieve the reduction targets and prepare to enforce emissions trading (2015), national GHG inventories were measured based on the 1996 Intergovernmental Panel on Climate Change Guidelines (IPCC GL). The national Inventory Report (NIR) of Korea is published every year. Grassland sector measurement was officially added in 2014. GHG removal of grassland soil was measured from 1990 to 2012. Grassland area data of Korea was used for farmland area data in the「Cadastral Statistical Annual Report (1976~2012)」. Annual grassland area corresponding to the soil classification was used「Soil classification and commentary in Korea (2011)」. Grassland area was divided into ‘Grassland remaining Grassland’ and ‘Land converted to Grassland’. The accumulated variation coefficient was assumed to be the same without time series changes in grassland remaining grassland. Therefore, GHG removal of soil carbon was calculated as zero (0) in grassland remaining grassland. Since the grassland area increases constantly, the grassland soil sinks constantly . However, the land converted to grassland area continued to decrease and GHG removal of soil carbon was reduced. In 2012 (127.35Gg CO2), this removal decreased by 76% compared to 1990 (535.71 Gg CO2). GHG sinks are only grasslands and woodlands. The GHG removaled in grasslands was very small, accounting for 0.2% of the total. However, the study provides value by identifying grasslands as GHG sinks along with forests.

지구온난화 문제 해결을 위한 지속적인 노력과 더불어 온실가스의 국제적 배출 규제는 더욱 강화되고 있다. Non-CO2 사업단은 온실가스의 종류와 발생원에 따른 적합 기술을 선택적으로 개발함으로써 기술별 균형을 추구하고 발생원에 대한 대응방안을 모색하고 있다. 주로 화학, 전자, 자동차, 선박과 같은 수출주력산업에서 발생하므로 향후 무역규제와 연계될 경우 그 파급효과가 클 것으로 예상된다. 선택적, 집중 투자와 효율적인 관리를 통하여 우리나라 온실가스저감 목표 달성에 일조하고 수출주력산업에 도움이 될 것으로 기대한다. 본 연구는 Non-CO2 사업단개발기술, 특히 멤브레인 관련기술에 관한 토의이다. ※ 환경부 글로벌탑 환경기술개발사업 중 “Non-CO2 온실가스 저감기술개발 사업”의 지원으로 수행되었다.

PURPOSES: This study devotes its energies to estimate greenhouse gas emissions for types of horizontal highway designs. METHODS: This paper suggested two types of road scenarios, scenario 1 is made by the lack of road design consistency. Beside scenario 1, scenario 2 is made by good road design. For comparisons of greenhouse gas emissions, driving simulator was used. RESULTS: Emission rates of road scenario 1 are 1.4 times higher than scenario 2 in the driving simulator. CONCLUSIONS : This study may have important implications for contributing to the application of road alignment technology for reduction of greenhouse gases as quantifying the correlations between greenhouse emissions and various road alignments. Consequently, this study will help road designers determine which roads are best alternatives in the process of choosing the roads in the future in terms of environmental benefits.

Biochar amendment to agricultural soil is regarded as a promising option to mitigateclimate change and enhance soil quality. It could sequester more carbon within the soil systemand increase plant yield by changing soil physicochemical characteristics. However, sustainableuse of biochar requires comprehensive environmental assessment. In this sense, it is important tomeasure additional greenhouse gas emission from soils after biochar addition. We investigatedemissions of CO2, N2O, and CH4from incubated soils collected from rice paddy and cultivatedgrassland after amendment of 3% biochar(wt.) produced from rice chaff. During incubation,soils were exposed to three wet-dry cycles ranging from 5~~85% soil gravimetric water content(WC) to investigate the changes in effect of biochar when influenced by different water levels. TheCO2emission was reduced in biochar treatment compared to the control at WC of 30~~70% bothin rice paddy and grassland soils. This indicates that biochar could function as a stabilizer for soilorganic carbon and it can be effective in carbon sequestration. The N2O emission was alsoreduced from the grassland soil treated with biochar when WC was greater than 30% because thebiochar treated soils had lower denitrification due to better aeration. In the rice paddy soil,biochar addition resulted in decrease in N2O emission when WC was greater than 70%, while anincrease was noted when WC was between 30~~70%. This increase might be related to the factthat available nutrients on biochar surface stimulated existing nitrifying bacterial community,resulting in higher N2O emission. Overall results imply that biochar amendment to agriculturalsoil can stabilize soil carbon from fast decomposition although attention should be paid toadditional N2O emission when biochar addition is combined with the application of nitrogenfertilizer.

PURPOSES: To analyze the specific factors of drivers behaviors that amount of cause the greenhouse gas emissions per vehicle. METHODS: Drivers behaviors at intersections are analyzed on the conditions of acceleration and deceleration. RESULTS : First, it is resulted greenhouse gas emissions per vehicle is produced more at intersections than at the main lines of highway. Second, it is resulted that the average speed, the average acceleration rate and the maximum speed are three major factors to produce greenhouse gas per vehicle in acceleration sections. Third, it is resulted that rapid deceleration 20m before entering intersections is the major factor to produce greenhouse gas per vehicle in deceleration sections. CONCLUSIONS: At intersections, sudden acceleration and deceleration is not good for greenhouse gas emissions. Thus, and the average speed, the average acceleration rate and the maximum speed are the chosen as factors to be controlled for drivers' behavior to reduce vehicles' greenhouse gas at intersections.

Climate change has been identified as one of the greatest challenges facing nations,government, business and citizens over future decades. Activities to reduce greenhouse gas emissions by the Kyoto Protocol, the international community has been in progress. Korea also has introduced the green house gas and energy Target Scheme to reduce greenhouse emission under the supervision of the government. Established green house gas information systems to promote activities of the private sector to reduce greenhouse gas emissions, The main propulsion is intended to be used as a basis in the private sector to reduce greenhouse gas utilized in the calculation of greenhouse gas emissions program (Excel spreadsheet), and to reduce greenhouse gas emissions evaluation standards published.

이 연구는 경안천 토양에서 기후 조건의 차이, 식물의 유무, 질소 농도의 차이에 따른 토양의 생물학적 유기물 분해속도의 변화가 대기 중 온실가스(CH4, CO2) 발생에 미치는 영향을 알아보고자 하였다. 본 연구 결과, 유기물 분해속도와 CH4, CO2 flux 모두 환경 조건이 동시에 변화하는 경우에 영향을 받음을 알 수 있었다. 유기물 분해 속도는 기후 조건의 차이와 질소 농도의 차이, 기후 조건 차이와 식물의 유무가 있는 경우 에 영향을 받음을 알 수 있었다. CH4 flux는 기후 조건 차이와 질소 농도의 차이, 기후 조건 차이와 식물의 유 무, 식물의 유무와 질소 농도의 차이가 있는 경우에 영향 이 있었으며 CO2 flux는 기후 조건 차이와 식물의 유무, 식물의 유무와 질소 농도의 차이가 있는 경우에 영향이 있음을 통해 기후 조건 차이와 식물의 유무, 질소 농도의 차이가 유기물 분해속도에 영향을 주어 대기 중 온실가 스 발생에 영향을 줄 수 있음을 알 수 있었다. 기후 조건 차이는 토양의 분해를 증진시켜 대기로 방 출되는 온실가스 또한 가중시킬 수 있다고 알려져 있으 나, 본 연구를 통해 기후변화가 유기물의 분해와 대기로 의 온실가스 방출을 감소시킬 수 있다는 결과를 도출할 수 있었으며 기후 조건 차이 외의 질소가 유입될 경우, 순영향(positive effect)을 주게 됨을 알 수 있었다. 그러 나 식물의 영향이 작용할 경우 질소의 유입으로 인한 순 영향을 감소시킬 수 있음을 알 수 있었으며, 이에 따른 추가적인 연구가 필요할 것으로 판단된다.

우리나라는 2015년부터 육상 온실가스 다배출 부문을 대상으로 기후변화의 위험성 감소를 위해 온실가스 배출권거래제도 시행을 통하여 온실가스배출 감축을 추진하고 있다. 그러나 해운부문은 선박활동방식의 국제성을 기반으로 국제해사기구(IMO)를 통해 부문별 접근방식으로 전 세계 모든 선박이 일률적인 규제를 통하여 온실가스 배출을 제한하는 제도를 마련하고 있다. 이미 2011년 기술적․운항적 온실가스 규제안을 마련한데 이어 시장기반적 조치에 대하여 선박을 대상으로 논의 중에 있다. 그 중에서도 전통적인 시장기반 조치 중의 하나인 배출권거래제도에 대하여 중요하게 논의되고 있다. 그러나 해운부문은 배출권거래제도 제안문서에서 지목되고 있는 안전경영증서상의 선박운항자가 온실가스관리 업무를 맡기에는 계약구조에 따른 선박의 소유, 점유 및 사용하는 방식의 차이에 따라 일률적으로 적용하기에는 한계가 있다. 육상부문의 배출권거래제도가 점오염원을 대상으로 시행되는 것과는 달리 선박은 비점오염원으로서의 특성이 있어서 관리가 쉽지 않은 실정이다. 또한 해운이 자본집약적 산업임에도 불구하고 글로벌 초대형선사와 중․소형선사간에 인력운용에 따른 수준 격차로 인해 배출권거래제도 편입에 따른 대응문제 등 다양한 문제점이 있다. 이 논문에서는 선박 온실가스배출규제를 위한 배출권거래제도 도입에 있어 앞서 제기한 문제점을 극복하고 국제해사기구의 부문별 접근방식, 전통적인 환경법의 원칙인 오염자 부담의 원칙 이행 및 기후변화협약의 유연성체제 등을 균형 있게 이행할 수 있는 방안에 대해 검토하였다.

지속적으로 강화되고 있는 국제 환경규제로, 해운사들은 선박의 온실가스 배출량을 줄이기 위한 노력을 해야 하는 상황에 직면해 있다. 본 연구에서는 총 온실가스 배출량에 대한 제약이 있는 상황에서 복수개의 항로를 운영하는 해운사에서 일 평균 선박 운영비용의 총합을 최소화하는 항로별 최적 선박대수와 운항속도를 결정하는 문제를 다룬다. 이 문제를 풀기위해 라그랑지안 휴리스틱 알고리즘을 개발하고 라그랑지안 쌍대문제를 풀어 최적해에 대한 하한값을 구한다. 제시한

Chuncheon according to the IPCC guideline, and they increased from 1,014,382 ton-CO2 in 2000 to 1,084,914 ton-CO2 in 2009. Using BAU scenario GHG emissions in 2020 was estimated to be 1,518,526 ton-CO2, which increase approximately 40% from those for 2009. Six reduction methods were applied in this study, including solar power generation, substitution of LED lights, individual and families' energy reduction efforts, cogeneration of incinerator, and expansion of natural gas line. Estimated total reduced GHG emission was 174,340 ton-CO2.