Climate change in South Korea

Climate change in South Korea has led to extreme weather events in South Korea that affects: social, economy, industry, culture, and many other sectors.[1] South Korea is experiencing changes in climate parameters. Such parameters include annual temperature, rainfall amounts, and precipitation.[2]

Visualisation of temperature anomaly in South Korea between 1901 and 2020.

The most distinct climate change predicted for South Korea is an increase in the range of temperature fluctuation throughout the four seasons. The number of record minimum temperature days has decreased rapidly. The maximum precipitation during the summer has increased. The increased possibility for new types of strong weather damage evokes the seriousness and the urgency of climate change. To quickly adapt to climate change, the South Korean government began an effort to reduce greenhouse gas emissions. They are one step closer to having a low-carbon based socio-economic nation.[3]

Industrialization and the increase in population have produced various pollutants and greenhouse gases, which are anthropogenic factors for climate change. In 2017 South Korea was the world's 7th largest emitter of carbon emissions and the 5th largest per capita.[4]

Greenhouse gas emissions

South Korea has among the highest greenhouse gas emissions per capita in the world.

700 million tonnes of greenhouse gases was emitted in 2019.[5] There was a 3.5% increase in emissions of greenhouse gases after a 6.5% drop in 2020.[6]As of 2021 Korea is funding construction of overseas coal power.[7]

South Korea is the ninth largest emitter of carbon dioxide. Dangjin Power Station is estimated to have been the coal-fired power plant which emitted the third most carbon dioxide in 2018, at 34 million tons, and relative emissions are estimated at 1.5 kg per kWh.[8]

Impacts on the natural environment

Temperature and weather changes

Current/past Köppen climate classification map for South Korea for 1980–2016
Predicted Köppen climate classification map for South Korea for 2071–2100

Precipitation increase

Seoul, the capital city of South Korea, has 228 years of precipitation records, starting with traditional cheugugi rain gauges which is the longest continual instrumental rainfall collection in the world. The record of daily precipitation provides a high-resolution dataset for detecting the singularity of extreme weather events and the multiple decades of precipitation variability. Precipitation was measured with cheugugi from 1778 to 1907, and modern observation equipment was developed and has been used since 1908. Comparing the cheugugi period and the modern period, the modern period shows a significant increase in mean rainfall rate. For example, statistical data for summer precipitation at cheugugi period is 861.8  mm whereas that for the modern period mean is 946.5  mm.[9]

As the amount of summer rainfall from 1912 to 2017 has increased by 11.6 mm/10 years,[10] because the number of heavy rain and torrential rain events have increased in frequency, the risk of heavy rain has become much higher in the southern part of a peninsula than the central region of the Korea peninsula. A large amount of water vapour entering the southern part of the peninsula (Southern coast, Jeju Island) flows into the Yellow Sea in summer and creates a high frequency of torrential rains. On the other hand, the east coast shows a low torrential rain frequency. In addition, localized heavy rainfall during the summer months is also associated with the number of typhoons, and a clear trend of increasing frequency of typhoons affecting South Korea since the mid-1970s and mid-1990s can be observed, which leads to an increase in localized heavy rainfall.[11] The frequency of localized heavy rainfall events with 1-hour peak precipitation of 50 millimeters or more has increased from an average of 2.4 events per year (1973~1982) to an average of 5.7 events per year(2013~2022).[12]

However, despite the long-term trend of increasing overall summer precipitation, precipitation patterns since the mid-2010s have been different from the past. In recent years, a series of unusually low summer precipitation years have been observed. In 2015, annual precipitation was the third lowest on record, and in 2016 and 2017, August and June precipitation were the lowest and third lowest on record, respectively. In addition, the 2018 ‘Changma’ period was the second shortest on record.[13]'

Precipitation distribution change
Precipitation distribution plot(1973) | Copyright(c)2015 KMA. The precipitation distribution plot is generated using Barnes interpolation based on observations from 95 points of ground weather observation.
Precipitation distribution plot(2022) | Copyright(c)2015 KMA. The precipitation distribution plot is generated using Barnes interpolation based on observations from 95 points of ground weather observation.

Changes in precipitation

The tropical rain belt 'Changma front' is created in the Bay of Bengal and the western North Pacific as a sub-system of the East Asian Monsoon. The northward movement of the 'Changma front' is influenced by the development of the subtropical ridge.[14] This northward moving quasi-stationary front is called 'Changma' in South Korea, which represents the main precipitation period.[1][15] The 'Changma front' takes about 4 to 5 weeks to go through the Korea Peninsula. This slow movement results in a large, but steady, amount of summer rainfall over the entire Korea Peninsula in late June and July each year. However, in recent years, since the 2000s, ‘Changma’ precipitation has tended to start a little later and end a little later, with a secondary precipitation peak in early August after the ‘Changma’ period. In particular, since the 2010s, rainfall during the ‘Changma’ period has been decreasing, while localized heavy rainfalls of 30 millimeters or more per hour have been increasing. Furthermore, due to climate change, ‘Changma’ precipitation is predicted to increase in the future and become more intense. Specifically, ‘Changma’ precipitation has been predicted to increase by up to 5% in the near future (2020-2039) and up to 25% by the end of the 21st century (2080-2099).[16]

There is also another 'Changma' type which is sometimes called the 'Fall Changma'. This is not, of course, an official term from the Korea Meteorological Administration. However, this 'Fall Changma' is created due to recent climate change. The 'Fall Changma' starts normally in late August to early September. It occurs when a ‘Changma front’ that has moved up toward China collides with Siberian high pressure and passes over the Korea Peninsula. The amount of rainfall and number of rainy days in the ‘Fall Changma’ period is generally lower than when the front moves north in early summer. Rainfall is also very erratic from year to year. However, on occasion, torrential downpours and tropical cyclones (typhoons) can occur, damaging crops as they reach maturity.[17]

Temperature increases

Since 1999, the Korea Global Atmosphere Watch Center located at Anmyeon-do has been monitoring major greenhouse gasses (GHG) such as carbon dioxide (CO2), methane (CH4), nitrous oxide (N2O), and chlorofluorocarbons (CFC-11 and CFC-12). The Anyone-do station is located in a relatively pollution-free environment, an ideal site for observing the background atmosphere of Northeast Asia, including the Korean Peninsula.

Among these GHG, CO2 acts most to change many aspects of the climate factors.[18] The CO2 concentrations at Anmyeon-do are substantially higher than the global average; the average CO2 concentration for 2018 was recorded as 415.2 ppm.[19] It is an increase of 44 ppm (6.7%) relative to the annual average of 371.2 ppm for 1999 when carbon dioxide concentrations were first observed in the Anmyeon-do. And it is 7.4 ppm higher than the global average of 407.8 ppm for the same year as documented by WMO.[20] The annual growth rate of CO2 for the 10 years(2008~2018) was 2.4 ppm/year, which was higher than the global average of 2.2 ppm/year.

Methane, another prominent greenhouse gas in the Korean Peninsula's atmosphere, also shows a clear increase in atmospheric concentration over the decade from 2008 to 2018. The 2018 annual average concentration of methane observed in the Anmyeon-do was 1974 ppb, which is 115 ppb higher than the global average and 100 ppb higher than the Northern Hemisphere Mauna Loa average of 1874 ppb. The 2018 methane concentration in the Anmyeon-do is 113 ppb higher than in 1999, when observations first began.[21]

During the industrialization era (second industrial revolution) over the past few decades, people have been burning fossil fuels (coal, oil, gasoline, natural gas). This releases CO2 into the atmosphere which contributes the greenhouse effect.[22] A sharp temperature contrast is shown between the urban and rural areas due to this industrialization. The mean temperatures data variations observed at ten meteorological stations in South Korea show an annual mean temperature increase at a rate of 0.52 °C per decade. During the last 29 years, the increase in the annual mean temperature was 1.5 °C for the Seoul station (found in an urban area) and 0.6 °C for the rural and seashore stations. These rate differences are significantly larger over urbanized areas.[2]

South Korea is experiencing a rapid temperature increase. Higher daily maximum and minimum temperatures are very likely to increase in East Asia. There are more severe warm extremes, but less severe cold extremes.[23] These mean temperature increases, especially the temperature increase rate after the 1950s is 1.5 times higher than before the 1950s. In the absence of greenhouse gas mitigation efforts (RCP8.5 scenario), between 2071 and 2100, winters are projected to be about 40 days shorter and summers about 40 days longer than in the most recent decade (2009-2018).[24] When average temperature comparison for comparing 20th-century and 21st-century temperature averages, it is shown that there is a 4 °C increase. The mean yearly temperature for South Korea is 10~15 °C,[25] which means that future warming will result in the expansion of a subtropical climate zone with average temperatures above 27 °C on the Korean Peninsula.[26] The recent subtropical zone is located on the lower seaside of the Korea Peninsula, but as accelerated temperatures increase, it will result in the subtropical zone move migrating northward. Therefore, by 2100 the subtropical zone is projected to expand its region to the north end of Taebaek Mountains.[27]

Extreme weather events

Just like other countries, Korea cannot evade the effect of climate change.[28] Increase of flooding and typhoon, and damage from them is significant in recent few decades. The damage to property and loss of lives caused by natural disasters is a typical impact of climate change. Because of this point, decreasing the natural disaster is one of the goals for nations adapting to climate change.[29] Increases in the frequency of flooding, typhoons, or hurricane intensity results in a steady increase of the number of large-scale natural disasters. South Korea is not an exception. Especially, damage from flooding and typhoon is significant. Despite of the increasing threat, the vulnerability to natural disaster, especially typhoon, has been decreased possibly due to multiple factors, such as, improved disaster prevention, changed building codes, industrial structures, and land use.[30]

- a typhoon

There are about 25 typhoons every year in the northwest Pacific Ocean, and on average, three to four typhoons directly or indirectly affect the Korean Peninsula.[31][32] When we divide the typhoons that affected the Korean Peninsula from 1977 to 2012 into two periods, we can see that the frequency and intensity of typhoons have recently increased, and the point of occurrence of typhoons has shifted westward and the turning position has shifted north.[33] This is related to the weakening of vertical wind shear around the Korean Peninsula, the westward movement of high pressure in the Northwest Pacific Ocean, and the rising of sea temperature around the Korean Peninsula.

- heat waves

The Korea Meteorological Administration's heat wave standard is defined as a case where the daily maximum temperature of 33℃ or higher lasts for more than two days. The rise in global average temperatures, which has been accelerating since the 2010s, is increasing the frequency and intensity of heat waves throughout the world. In South Korea, too, heat waves have been frequent recently, including 2013, 2016, and 2018. In addtion, the intensity of heat waves is increasing, breaking the highest record of daily high of 41℃ per day in Hongcheon and daily low of 30.3℃ per day in Seoul in 2018.[34] Heat waves mainly occur inland in Gyeongsang-do and Jeolla-do. Among the weather variables, heat waves were more correlated with cloudiness than precipitation. There is a negative correlation between cloudiness and heat wave throughout the summer.[35] Recently, local and global causes of heat waves have been actively studied. However, in order to effectively predict when, where, and how long and how strong a heat wave will last, we need to study the mechanisms for heat wave occurrence and maintenance in more detail.

- droughts

Drought is one of the weather disasters that causes enormous damage to areas that greatly affect the national economy and people's lives, such as agriculture, forests, and livestock. Since most of the annual precipitation in South Korea is concentrated in summer, drought occurs frequently in winter and spring when precipitation is relatively insufficient. From 1980 to 2015, the SPI-12 (drought index calculated from 12-month accumulated precipitation) was calculated from rainfall observation at 55 locations on the Korean Peninsula and the rate of change was calculated to confirm that the severity of drought increased statistically significantly in the northeastern coast of South Korea. And also it confirm that the frequency of drought increased in late winter, early spring, and that early fall, and the frequency of drought decreased in summer.[36] Due to the recent rapid climate change, precipitation increases in summer, but there is no change or decrease in precipitation except for summer,[37] while temperature increases not only in summer but also throughout the entire season. Thus, the risk of drought may increase in seasons other than summer due to a decrease in precipitation and an increase in air moisture requirement due to rising temperatures. In particular, in July–August 2018, when a high temperature phenomenon occurred nationwide, drought occurred due to an increase in evaporation on the ground due to a high temperature phenomenon.[38]

Sea level Rise

In the seas around the Korean Peninsula, sea levels have risen by about 10 cm over the past 40 years, and the rate of increase is 2.9 mm, which is somewhat higher than the global average every year. By region, the area near Jeju was the highest with an increase of 4.44 mm, with the east coast increasing by 3.70 mm, the south coast by 2.41 mm, and the west coast by 2.07 mm.[39] According to the RCP 2.6/4.5/6.0/8.5 scenario, Korea's average sea level is expected to rise 37.8, 48.1, 47.7, and 65.0 cm at the end of the 21st century, respectively. In particular, in all scenarios, the southern coastal region is expected to have a higher degree of sea level rise than other regions, and the western coastal region is expected to have a lower degree of sea level rise than other regions.[40]

The ecosystem affected by rising sea levels is the coastal ecosystem. The coast has a unique ecosystem as the boundary between land and the sea, and a wide variety of species inhabit and high productivity is maintained, performing a biologically important function. However, the coast is vulnerable to climate change because it is directly affected by rising sea levels, which is the most direct change in climate change, such as an increase in the risk of erosion and flooding.[41] In particular, as Korea is surrounded by the sea on three sides, the damage to the coastal ecosystem will be great due to climate change and rising sea levels.

Impacts on people

Economic impacts

According to the map of industry distribution in Korea, it is noticeable that north-east part of the Korea does not have significant industry. High-tech, heavy and IT industries are placed near the capital, or more close to the sea in the south of Korea. Unlike the industry distribution density, according to the map of damage from natural disaster, the damage is the most dense in the north-east part of the Korea.

Mitigation and adaptation

Carbon trading

There is a carbon trading system.[42]

Green New Deal

The Green New Deal is a plan set up by the ruling party the DPK ahead of the 2020 parliament elections. The plan includes to reach zero emission by 2050, to stop providing construction for coal power plants overseas and to reduce fine dust by 40% in 2040.[43] The government also aims to achieve a target of 40% renewable power by 2034 and the replacement of some coal capacity with liquefied natural gas.[44]

The South Korean president Moon Jae in pledged in September 2020 that South Korea would be carbon free in 2050.[45] The 2030 goal is almost a quarter reduction from 2017 levels.[46]

Energy transition

The South Korean Ministry of Trade, Industry, and Energy (MOTIE) has claimed that an energy transition is necessary in order to comply with the public's demands for their lives, their safety, and the environment. In addition, the ministry has stated that the direction of the future energy policy is "to transition (from conventional energy sources) to safe and clean energy sources." Unlike in the past, the keynote of the policy is to put emphasis on safety and the environment rather than on stability of supply and demand and economic feasibility and is to shift its reliance on nuclear power and coal to clean energy sources like renewables.[47]

In 1981, the primary energy was sourced predominantly by oil and coal with oil accounting for 58.1% and coal 33.3%. As the shares of nuclear power and liquefied natural gas have increased over the years, the share of oil has decreased gradually. The primary energy broke down as follows in 1990: 54% oil, 26% coal, 14% nuclear power, 3% liquefied natural gas, and 3% renewables. Later on, with efforts to reduce greenhouse gas emissions in the country through international cooperation and to improve environmental and safety performances, it broke down as follows in 2017: 40% oil, 29% coal, 16% liquefied natural gas, 10% nuclear power, and 5% renewables.[49] Under the 8th Basic Plan for Long-term Electricity Supply and Demand, presented at the end of 2017, the shares of nuclear and coal are getting decreased while the share of renewables is expanding.

In June 2019, the Korean government confirmed the Third Energy Master Plan, also called a constitutional law of the energy sector and renewed every five years. Its goal is to achieve sustainable growth and enhance the quality of life through energy transition. There are five major tasks to achieve this goal. First, with regards to consumption, the goal is to improve energy consumption efficiency by 38% compared to the level of 2017 and to reduce energy consumption by 18.6% below the BAU level by 2040. Second, with respect to generation, the task is to bring a transition towards a safe and clean energy mix by raising the share of renewable energy in power generation (30~35% by 2040) and by implementing a gradual phase-out of nuclear power and a drastic reduction of coal. Third, regarding the systems, the task is to raise the share of distributed generation nearby where demand is created with renewables and fuel cells and to enhance the roles and responsibility of local governments and residents. Fourth, with regards to the industry, the task is to foster businesses related to renewables, hydrogen, and energy efficiency as a future energy industry, to help the conventional energy industry develop higher value-added businesses, and to support the nuclear power industry to maintain its main ecosystem. The fifth task is to improve the energy market system of electricity, gas, and heat in order to promote energy transition and is to develop an energy big data platform in order to create new businesses.[50][51]

Society and culture

Population response

There are about 1.5 million people in South Korea that follow some sort of plant-based diet, and about 500,000 vegans who do not eat any animal products at all.[52] The most common reason blog authors cited for cutting down on meat consumption was for health, with 63.1 percent of blogs mentioning healthy cooking, followed by ethical reasons at 52.9 percent, environmental protection concerns at 36.2 percent, and wanting to lose weight at 26.3 percent.[53]

Company response: Green IT industry

A new Korean Government IT strategy project is projected to have a 20% increase in green IT and IT product by 2012 [54] by the Ministry of Knowledge and Economy. Meanwhile, the Ministry of Public Administration and Security have already started a computational center for green energy-saving and have formulated a comprehensive plan to promote the 'energy-saving'. Through professional organizations comprehensive energy-saving, environmental protection, and budget savings procedures are in progress for energy diagnostic purposes. In addition to what has already been discussed the plan for idle shut-off, demolition equipment, and main contents as 'a green-based computational center for environmental improvement plans' will also go ahead as scheduled.[55]

Activism

Data from 2021 showed that, for giving the world a 50% chance of avoiding a temperature rise of 2 degrees or more South Korea should increase its climate commitments by 136%.[56]:Table 1 For a 95% chance it should increase the commitments by 487%. For giving a 50% chance of staying below 1.5 degrees South Korea should increase its commitments by 875%.[56]

See also

References

  1. www.kricccs.com https://web.archive.org/web/20140523012721/http://www.kricccs.com/detail.php?number=682&thread=22r03r01. Archived from the original on 2014-05-23. {{cite web}}: Missing or empty |title= (help)
  2. Cha, Josh Smith, Sangmi (2020-06-08). "Jobs come first in South Korea's ambitious 'Green New Deal' climate plan". Reuters. Retrieved 2021-03-09.
  3. 김나영 (2021-12-31). "S. Korea emitted 701.3 mln tons of greenhouse gas in 2019: environment ministry". Yonhap News Agency. Retrieved 2022-01-02.
  4. "South Korea's GHG emissions rose by 3.5% in 2021, after a 6.2% drop in 2020". www.enerdata.net. 2022-06-28. Retrieved 2022-10-21.
  5. "Japan, South Korea to run with Viet coal plant despite climate vows". Prothomalo. 2021-01-01.
  6. Grant, Don; Zelinka, David; Mitova, Stefania (2021). "Reducing CO2 emissions by targeting the world's hyper-polluting power plants". Environmental Research Letters. 16 (9): 094022. doi:10.1088/1748-9326/ac13f1. ISSN 1748-9326.
  7. Wang, B., J.G. Jhun., and B.K. Moon., 2006: Variability and Singularity of Seoul, South Korea, Rainy Season (1778-2004). Journal of Climate, 20, 2572-2580
  8. 국립기상과학원 (2008). "한반도 100년의 기후변화". 국립기상과학원: 31.
  9. Choi, J. W.; Cha, Y.; Kim, H. D. (2017). "Interdecadal variation of precipitation days in August in the Korean Peninsula". Dynamics of Atmospheres and Oceans. 77: 74–88.
  10. 이, 경원 (13 October 2022). "[사실은] 국지성 호우, 최근 들어 정말 잦아졌나요?". SBS NEWS. Retrieved 1 May 2023.
  11. 기상청 (2020). "2020 한국 기후변화 평가보고서": 46. {{cite journal}}: Cite journal requires |journal= (help)
  12. LinHo; Wang, Bin (2002). "The Time-Space structure of the Asian-Pacific Summer Monsoon: A fast annual cycle view". J. Clim. 15 (15): 2001–2019. Bibcode:2002JCli...15.2001L. doi:10.1175/1520-0442(2002)015<2001:TTSSOT>2.0.CO;2. S2CID 53455729.
  13. Seo, K.H, and L.J. Lee., 2011: A white book of Changma. KMA., 268p. print. http://www.climate.go.kr/home/bbs/view.php?bname=publicity&category1=&category2&code=25&skind=&sword=&vcode=4462
  14. 기상청 (2022). 장마백서 2022. 기상청. pp. 224–237.
  15. 두산백과. "가을장마". 네이버 두산백과. Retrieved 1 May 2023.
  16. Korea Meteorological Administration (KMA). 2012: Summary of Korea Global Atmosphere Watch 2011 Report. KMA, 10pp.
  17. 기상청 (2019). "2018 지구대기 감시보고서". 국립기상과학원 환경기상연구과: 268.
  18. WMO Greenhouse Gas Bulletin. "Carbon dioxide levels continue at record levels, despite COVID-19 lockdown". WORLD METEOROLOGICAL ORGANIZATION. Retrieved 1 May 2023.
  19. 기상청 (2019). "기상청 이상기후분석 시스템". {{cite journal}}: Cite journal requires |journal= (help)
  20. "The Greenhouse Effect".
  21. Christensen, J.H., B. Hewitson, A. Busuioc, A. Chen, X. Gao, I. Held, R. Jones, R.K. Kolli, W.-T. Kwon, R. Laprise, V. Magaña Rueda, L. Mearns, C.G. Menéndez, J. Räisänen, A. Rinke, A. Sarr and P. Whetton, 2007: Regional Climate Projections. In: Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [Solomon, S., D. Qin, M. Manning, Z. Chen, M. Marquis, K.B. Averyt, M. Tignor and H.L. Miller (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA. Archived 2007-12-15 at the Wayback Machine
  22. 박, 창용; 최, 영은; 권, 영아; 권, 재일; 이, 한수 (2013). "남한 상세 기후변화 시나리오를 이용한 아열대 기후대 및 극한기온사상의 변화에 대한 연구". 한국지역지리학회지. 19 (4): 600–614.
  23. "한국 > 우리나라기후 > 국내기후자료 > 기후자료 > 날씨 > 기상청". Archived from the original on 2010-01-22. Retrieved 2012-11-30.
  24. 이, 현재; 김, 가영; 박, 창용; 차, 동현 (2017). "다중지역기후모델을 이용한 남한 지역의 미래 기후대 분포와 극한기온사상의 변화에 대한 연구". 기후연구. 12 (2): 149–164.
  25. Jeong, H.S., 2010: Prospect of Korea Climate change. Rural and Environmental Engineering Journal, 109, 22–30.
  26. "우리나라 자연재해 현황". 국가기후변화정보센터. Archived from the original on 2016-03-04. Retrieved 2015-08-12.
  27. "기후변화로 인한 도시 자연재해". 국가기후변화적응센터. Archived from the original on 2016-09-13. Retrieved 2015-08-12.
  28. Park, Doo-Sun R; Ho, Chang-Hoi; Nam, Chaehyeon C; Kim, Hyeong-Seog (1 May 2015). "Evidence of reduced vulnerability to tropical cyclones in the Republic of Korea". Environmental Research Letters. 10 (5): 054003. Bibcode:2015ERL....10e4003P. doi:10.1088/1748-9326/10/5/054003.
  29. Chan, J. C. (2005). "Interannual and interdecadal variations of tropical cyclone activity over the western North Pacific". Meteorology and Atmospheric Physics. 89: 143–152.
  30. Wu, M. C.; Chang, W. L.; Leung, W. M. (2004). "Impacts of El Niño–Southern Oscillation events on tropical cyclone landfalling activity in the western North Pacific". Journal of Climate. 17: 1419–1428.
  31. 강, 현웅; 손, 찬영; 박, 진혁; 장, 수형; 김, 정민 (2018). "경년별 한반도 영향 태풍 활동 및 태풍 동반 강우 특성 변화 분석". 한국 방재학회 논문집. 18: 395–402.
  32. 기상청 (2020). "2020 기후변화 평가보고서": 279–280. {{cite journal}}: Cite journal requires |journal= (help)
  33. Choi, N.; Lee, M.-I. (2019). "Spatial variability and long-term trend in the occurrence frequency of heatwave and tropical night in Korea". Asia-Pacific Journal of Atmospheric Science. 55 (5): 101–114.
  34. Azam, M.; Maeng, S. J.; Kim, H. S.; Lee, S. W.; Lee, J. E. (2018). "Spatial and temporal trend analysis of precipitation and drought in South Korea". Water. 10 (6): 765.
  35. 김, 연희; 김, 맹기; 전, 은지; 이, 중대; 민, 경우; 장, 용석 (2010). "한반도 강수의 양극화 현상". 기후연구. 5 (1): 1–15.
  36. Chou, C.; Lan, C. W. (2012). "Changes in the annual range of precipitation under global warming". Journal of Climate. 25: 222–235.
  37. 국립해양조사원 (2018). "해양조사기술연보 2018". {{cite journal}}: Cite journal requires |journal= (help)
  38. 허, 태경; 김, 영미; 부, 경온; 변, 영화; 조, 천호 (2018). "CMIP5 자료를 활용한 우리나라 미래 해수면 상승". 대기. 28 (1): 22–35.
  39. 조, 광우; 맹, 준호 (2007). "우리나라 해수면 상승 대응 방향에 대한 소고". 한국해양환경에너지학회. 10 (4): 227–234.
  40. "Carbon Emission-related Cost Burden Weighing on Korean Companies". Businesskorea (in Korean). 2020-12-31. Retrieved 2021-01-01.
  41. Stangarone, Troy. "South Korea's Green New Deal". thediplomat.com. Retrieved 2020-09-29.
  42. "The Carbon Brief Profile: South Korea". Carbon Brief. 2020-04-06. Retrieved 2021-01-06.
  43. Herald, The Korea (2020-09-08). "Moon vows to shut down 30 more coal plants to bring cleaner air and battle climate change". www.koreaherald.com. Retrieved 2020-09-29.
  44. 송상호 (2020-12-31). "S. Korea submits greenhouse gas reduction target to U.N. climate convention secretariat". Yonhap News Agency. Retrieved 2021-01-01.
  45. "?????- ?????????". www.etrans.or.kr (in Korean). Archived from the original on 29 June 2020. Retrieved 5 August 2020.
  46. "[정책위키] 한눈에 보는 정책 - 에너지전환 정책". www.korea.kr (in Korean). Archived from the original on 3 October 2020. Retrieved 5 August 2020.
  47. "FAQ - ?????????". www.etrans.or.kr (in Korean). Archived from the original on 29 June 2020. Retrieved 5 August 2020.
  48. "제3차 에너지기본계획 최종 확정 - 대한민국 정책브리핑 | 뉴스 | 브리핑룸 | 보도자료". www.korea.kr (in Korean). Archived from the original on 24 August 2020. Retrieved 5 August 2020.
  49. "Third Energy Master Plan" (PDF). etrans. 2019. Archived (PDF) from the original on 3 October 2020. Retrieved 9 September 2020.
  50. Herald, The Korea (2020-06-11). "[Weekender] Fake meat no more faux pas in Korea". www.koreaherald.com. Retrieved 2021-01-06.
  51. Gibson, Jenna. "More and More South Koreans Are Going Vegetarian". thediplomat.com. Retrieved 2021-01-06.
  52. Ministry of Strategy and Finance (MSF), 2009: New development vision & Strategies. Ministry of Strategy and Finance Report., 73p. http://www2.korea.kr/expdoc/viewDocument.req;JSESSIONID_KOREA=H1NGQj2pf9WhG8SQt2KtNbsyYHHZPtXgJ1zHMPhGBbpzj5hlcQgS!-187360298?id=10136 Archived 2015-09-10 at the Wayback Machine
  53. Kim, K. J., 2008: Eco-friendly Green IT present condition & Implications: IT service industry. The Korea Development Bank, 29p. http://rd.kdb.co.kr/jsp/re/content/REIss0101_3893.jsp%5B%5D
  54. R. Liu, Peiran; E. Raftery, Adrian (9 February 2021). "Country-based rate of emissions reductions should increase by 80% beyond nationally determined contributions to meet the 2 °C target". Communications Earth & Environment. 2. doi:10.1038/s43247-021-00097-8. PMC 8064561. PMID 33899003.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.