Climate change in Japan

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Japanese topographic map Japan topo en.jpg
Japanese topographic map

Climate change is an urgent and significant issue affecting Japan. [1] In recent years, the country has observed notable changes in its climate patterns, with rising temperatures serving as a prominent indicator of this phenomenon. [1] As an archipelago situated in northeastern Asia, Japan is particularly vulnerable to the impacts of climate change due to its diverse geography and exposure to various weather systems. [1] The nation experiences a broad range of climates, spanning from the frigid winters of Hokkaido to the subtropical climates of Okinawa. [1] Changes in temperature patterns have the potential to disrupt ecosystems, impact agricultural productivity, modify water resources, and pose significant challenges to infrastructure and human settlements. [1]

Contents

Japanese government is increasingly enacting climate change policy to respond. The government criticised for lacking a credible plan to get to its pledged net zero greenhouse gas emissions by 2050. [2] As a signatory of the Kyoto Protocol, and host of the 1997 conference which created it, Japan is under treaty obligations to reduce its carbon dioxide emissions and to take other steps related to curbing climate change.

Greenhouse gas emissions

Out of the global GHG emissions, Japan is responsible for 2.6%. The average rate of CO2 emissions per person in Japan is almost double the global average. [3] Emissions have been slightly reduced since 2013 and the net zero emissions are set by 2050. [3]

Japan is one of the largest greenhouse gas polluters, both nationally and per person. 20210703 Variwide chart of greenhouse gas emissions per capita by country (includes OTHER).svg
Japan is one of the largest greenhouse gas polluters, both nationally and per person.

Japan has pledged to become carbon neutral by 2050. [5] In 2019 Japan emitted 1212 Mt CO2eq, [6] The per capita CO2 emissions were 9.31 tonnes in 2017 [7] and was the 5th largest producer of carbon emissions. [8] As of 2019 greenhouse gas emissions by Japan are over 2% of the annual world total, [9] partly because coal supplies over 30% of its electricity. [10] Coal-fired power stations were still being constructed in 2021 [11] some may become stranded assets. [12]

Carbon dioxide emissions from energy, 2011-2021 (Mt CO2) [13] :12
20112012201320142015201620172018201920202021
1237.31324.51314.11280.41239.91220.21214.11192.41151.41058.31081.7

Calculations in 2021 show that to give the world a 50% chance of avoiding a temperature rise of 2 degrees or more, Japan should increase its climate commitments by 49%. [14] For a 95% chance, it should increase the commitments by 151%. For a 50% chance of staying below 1.5 degrees, Japan should increase its commitments by 229%. [14] :Table 1 A March 2021 analysis by Climate Action Tracker said that Japan should reduce greenhouse gas emissions so that by 2030 the emissions are 60% below 2013 levels; this would support a goal of limiting warming to 1.5 °C. [15]

CO2 emission by sector
Sector2019 [16] 2021 [17]
Energy432.93430
Industry279.2269
Transportation198.58178
Commercial industry64.7159.9
Households53.3651.6
Industrial processes45.1743
Waste30.8829.9
Other3.112.9

Furthermore, Japan has witnessed a decrease in its annual emissions, with a 5.3% reduction in industrial emissions due to decreased steel production. Residential emissions fell by 1.4%, while vehicle emissions rose by 3.9%. Despite these changes, Japan still heavily relies on fossil fuels, which constitute about 70% of its power generation. In terms of renewable energy, Japan aims for 10 gigawatts of offshore wind capacity by 2030 but is currently projected to only reach 4.4 gigawatts. [18]

Transportation

The transportation sector accounts for 20% out of the total emission of Japan. [19] Within the transportation sector, it is mainly oil that is being used. [3] This particular sector currently relies on fossil fuels and is projected to continue doing so for a while. [19] One challenge to decarbonize the transportation sector is the cost of such technologies required for the transformation. [19] Emissions have been decreasing within the sector since 2001 due to fuel efficiency of cars and population decline. [19]

Energy supply and fossil fuels

The energy supply is mainly made out of fossil fuels, reaching up to 88% of the total primary energy supply in 2019. The fossil fuels are composed of a combination of oil (38%), coal (27%) and gas (23%). [3] In 2012, the Fukushima disaster led to an increase in Japan's dependence on fossil fuels. The country's energy supply has been impacted by the phasing out of nuclear power, [3] with only 4% of the supply coming from nuclear sources in 2019 compared to 15% in 2010. [3] Fossil fuel is mainly imported and the high dependence on the non-renewable sources is making it difficult to reach a carbon-neutral society. [3] Out of Japan's total primary energy supply, only 8% is made out of renewable sources; however, this has been doubled since 1990. [3]

Industrial emissions

Although Japan is a developed country, it still has a large presence of energy-intensive industries (such as the production of steel and cement) compared to other developed economies. [20] The country has a high energy consumption that can be compared to emerging countries like China, India, and Brazil. [20] In Japan, the overall industrial emissions domestically account for approximately 967.4 million tons of CO2 annually. [21] Among the industries the iron and steel sector has the highest emission rate, accounting for around 111.9 million tons of CO2. [21]

Current Emissions Overview

According to data released by the Ministry of Environment, Japan's total greenhouse gas emissions for the fiscal year ending in March 2023 declined by 2.3%, amounting to 1.085 billion metric tons of CO2 equivalent. This reduction marks a 23% decrease compared to the levels recorded in 2013. Despite this progress, Japan is yet to meet its ambitious target of a 46% reduction by 2030. The primary contributor to this decrease was the industrial sector, which saw a 5.3% drop in emissions, largely due to a decrease in steel production and a corresponding reduction in power demand. In addition, residential emissions decreased by 1.4%. However, not all sectors showed a decline; emissions from the transportation sector, for example, increased by 3.9%. [22]

On the renewable energy front, Japan has set a target to achieve 10 gigawatts of offshore wind power by 2030. Yet, projections suggest that Japan is on pace to reach only 4.4 gigawatts by the end of the decade, indicating significant challenges ahead in meeting its renewable energy goals. [22]

Impacts on the natural environment

Temperature and weather changes

Average annual temperature anomaly in Japan, 1901 to 2020 Temperature Bar Chart Asia-Japan--1901-2020--2021-07-13.png
Average annual temperature anomaly in Japan, 1901 to 2020

Temperature

Koppen-Geiger Map JPN present.svg
Köppen climate classification map for Japan for 1980–2016
Koppen-Geiger Map JPN future.svg
2071–2100 map under the most intense climate change scenario. Mid-range scenarios are currently considered more likely [23] [24] [25]

Climate change has affected Japan drastically. The temperature and rainfall have increased rapidly in the years leading up to 2020. This has resulted in immature rice grains and also oranges that automatically get separated from their skin due to immature growth by inappropriate weather. Many corals in the Japanese seas and oceans have died due to rising sea temperatures and ocean acidification. Tiger mosquitoes, which transmit dengue fever, were found further north than before. [26]

Earth Simulator calculations reveal the daily increase in mean temperature in Japan during the period 2071 to 2100. The temperature will increase by 3.0 °C in Scenario B1 and 4.2 °C in A1B compared to that of 1971 to 2000. Similarly, the daily maximum temperature in Japan will increase by 3.1 °C in B1 and 4.4 °C in A1B. The precipitation in summer in Japan will increase steadily due to global warming (annual average precipitation will increase by 17% in Scenario B1 and by 19% in Scenario A1B during the period 2071–2100 compared to that of 1971–2000). [27]

Considering the projections in temperature for Japan, depending on the scenario there are different outcomes. In a worst-case scenario for 2100, where GHG emissions are not declining, an increase of almost 6 °C is expected during winter and almost 5 °C for summer in comparison to the annual in 1900. [28] If a drastic reduction in emissions occurs then the increases will be almost 2 °C and 1,5 °C respectively by 2100. [28]

Precipitation

Precipitation in Japan varies between 1000mm to 2,500mm annually, causing various events depending on the year, either flooding or lack of water availability for sectors such as agriculture. [3] It is also more complex to predict in any case scenario the effects of climate change, easily, for precipitation. [3] Extreme rainfall events are more frequent the total annual precipitation seems to decrease. [3]

Extreme weather events

Typhoon, Okinawa, Japan 2010 The wind whips through palm trees as Typhoon Chaba blows ashore at U.S. Marine Corps Base Smedley D. Butler, Okinawa, Japan, Oct. 28, 2010 101028-M-VG363-103.jpg
Typhoon, Okinawa, Japan 2010

Climate change will not only affect parameters such as temperature and precipitation. [3] Extreme events seem to have increased as well such as heat waves, droughts, tsunamis, storm surges, and typhoons. [3] An increased frequency and prolonged duration of such natural disasters are likely to impact upon the energy, agricultural and tourism sector of Japan. [3]

Sea level rise

Global warming has led to an increase in worldwide sea level rise due to the melting to glaciers and ice sheets. [29]

Southern and eastern coastal parts of Japan, have a high probability to be affected by phenomena such as tsunamis and storms. [29]

Water resources

Water resources are highly dependent on the country's rates of precipitation and evapotranspiration. [30] Temperature projections in Japan are increasingly affecting both water cycle processes, hurting the availability of water resources for Japan. [30] The effect of climate change upon water availability in Japan includes:

A decrease in water resources could potentially cause problems for Japanese sectors like agriculture which will have to find different cultivation methods to manage water waste, especially in the scenario of severe droughts. [3]

Ecosystems

Changes in temperature, precipitation patterns and sea level rise are some potential effects of climate change, which are leading to changes in the distribution and abundance of plant and animal species. [3] Listed below, are ecosystems that will potentially get affected by climate change in Japan:

Overall, climate change is having significant impacts on Japan's ecosystems, and these impacts are likely to continue and even accelerate in the future. [3] Japan must take steps to mitigate and adapt to these impacts to protect its biodiversity and the services that ecosystems provide. [3]

Biodiversity

Japan is a biodiverse region with over 90,000 recognized species, of which more than 30% of amphibians, reptiles, and freshwater and marine species, and more than 20% of mammals and plants are threatened with extinction. [31] Ecological changes are increasingly reported, and climate change is recognized as a major threat to biodiversity. [31] Phenological and distributional records show that ecological changes are occurring in response to climate change in Japan. [31]

On average, the phenology of numerous animal species has been delayed, leading to shifts in species interactions. [31] Rapid range expansions have been observed for insects and corals, while future projections indicate rapid shifts of plants toward higher elevations and significant losses of climatically suitable areas for high-altitude species. [31] The impacts of climate change on Japanese species are not always consistent with the observations and projections previously reported in other regions. [31] There is a need for further investigations in other less-known regions to improve understanding of regional impacts, which can be facilitated by utilizing locally available data and publications, especially in non-English speaking countries. [31]

Coral reefs

Sekisei Lagoon in Okinawa has suffered coral bleaching. ISS005-E-10686 Sekisei Lagoon.jpg
Sekisei Lagoon in Okinawa has suffered coral bleaching.

The warming of the world's oceans over the past few decades has had a significant impact on coastal ecosystems, particularly on coral reefs found in tropical and subtropical regions. [35] The potential future outcome of global warming in Sekisei Lagoon could lead to extreme heating and mass bleaching, which would have synergistic effects with local stressors. [35]

In 2015–2016, coral bleaching occurred on a large scale due to elevated sea temperatures, and the Ryukyu Islands' coral reefs experienced extreme thermal stress and extensive bleaching in the summer of 2016. [35] This bleaching affected about 90% of the coral in Sekisei Lagoon. [35] Analysis indicated that the decline in corallivores and herbivores' density matched the decrease in coral cover after mass bleaching, while changes in species richness were not correlated with coral cover change. [35] Short-term declines in corallivores were common in the Great Barrier Reef after the 2016 mass bleaching, and at Ishigaki Island and other sites during the 1998 bleaching event. [35] The response of herbivores varied from place to place. All potential stocks, including fisheries production, aquarium fish production, recreational diving, and seaweed control by herbivores, decreased following the bleaching. [35] In January 2017 the Japanese environment ministry said that 70% of the Sekisei lagoon in Okinawa, Japan's biggest coral reef, had been killed by coral bleaching. [36]

These findings suggest that severe bleaching and extreme heating were the main causes of the loss of fish diversity and associated potential stocks of ecosystem services in Sekisei Lagoon. [35]

Impacts on people

Climate change is expected to have an impact on various sectors of Japan's population. In the economic sector, it will affect agriculture, urbanization, and energy, while in the health sector, it will affect people in terms of mortality and increased exposure to heatwaves, among other impacts

Agriculture

Changing climatic conditions, with increasing temperature trends, decreasing rainfall and intensifying heat waves, droughts and other external phenomena, affect food production. [3] These conditions tend to decrease crop yields and quality. [3] Responses to the increase in temperature may be directed to the displacement of crop zones to higher elevations where ideal climatic conditions for growth can be found. [3] With the increase in temperature, there may be changes in the length of the vegetative period and the early appearance of phenological phases. [3]

Studies have shown that climate change is already having a significant impact on rice agriculture with the increase of extreme events such as heat or dry spells. [37] These changes represent a serious concern for growers and may become a source of the vulnerability of the crop production system and pose a threat to national food security. [38] It has been shown that there is a direct relationship between rice production and temperature, when the degree of climate change is large, production decreases. [39] Yield reductions have been reported in specific areas or in extremely hot years. [40]

Irrigation demand could be increased by higher temperatures due to higher plant evapotranspiration. [3] The expansion of irrigated areas could become a threat to water resources, in terms of quantity and quality, if demand and cereal production increase. [3]

Urbanization

Japan is one of the most urbanized countries in the world, with 91.8% of its population concentrated in urban areas by 2020. [41] This trend will continue and increase. [41] By 2050 the urbanization rate is expected to be almost 95%. [41]

The elderly are especially vulnerable to the impacts of heat waves and according to data from the Euro-Mediterranean Center on Climate Change, [3] by 2035, approximately 38% of the population will be over the age of 65. High levels of air pollution have been found to increase the effects of urban heat. [3] In 2017, nearly 77% of the total population was exposed to air pollution levels above WHO thresholds. [33]

Coastal flooding

According to the Euro-Mediterranean Center on Climate Change, [3] due to its geography, high rates of soil sealing and dense urbanization along the Japanese coastline, the country is vulnerable to extreme rainfall and coastal flooding, particularly on the more populated island of Honshu. [3] Japan is subject to the regular arrival of typhoons. [3]

In 2018, torrential rains caused flash floods and landslides, resulting in more than 200 deaths the evacuation of 2.3 million people and more than US$7 billion in damages. [42] The Euro-Mediterranean Center on Climate Change refers, that rising sea levels, wave heights and the frequency of typhoons are expected to increase damage to human settlements. [3] The risk of flooding will increase in the future, with the depth of flooding in Tokyo increasing by 170% by 2050. [3] This would result in damages to real estate and infrastructure of 220% to 240%. [3]

Energy

According to the Euro-Mediterranean Center on Climate Change, [3] the Japanese energy system has been significantly impacted by severe flooding resulting from heavy precipitation and typhoons. [3] In September and October 2020, the Faxai and Hagibis typhoons caused power outages that affected 10 million households in Japan. [3] Due to the faster-than-global-average temperature increases and the rising frequency of heat waves, the demand for cooling has been increasing in the country. [3]

The trend for heating needs is somewhat opposite to that of cooling needs. [3] There will be significant decreases in heating needs across the country, with the largest decrease in Hokkaido and a moderate decrease in the southern islands. [3] On the other hand, cooling needs will increase considerably in the southern islands of Shikoku and Kyushu, while only a slight increase is expected in Hokkaido and elevated areas of Honshu. [3]

Health

The climate and weather patterns in Japan have undergone changes that have led to an increase in mean temperature. [41] As a result, vulnerable populations such as the elderly are at high risk due to the intensity of heat waves and heat stress. [43] The rise in temperatures is anticipated to enable the transmission of diseases throughout Japan, including vector-borne illnesses like dengue, which tend to thrive in warmer climates. [44]

Heatwaves and heat stress

Mortality and morbidity would increase in the country and may even double in eastern and northern Japan due to higher average temperatures and an increase in the frequency and duration of heat waves. [41]  

Japan is experiencing an increasing trend in deaths from heat-related illnesses. [41] Between 1968 and 1994, 2,326 deaths from heat stroke were recorded, 589 of them in 1994 alone, when a severe heat wave caused temperatures to exceed 38 °C. [41] In the abnormally hot summer of 2018, there were 95,137 emergency patients with heat stroke symptoms of which 160 died, 50% were over 65 years of age. [43] That trend could continue to increase in the absence of adaptation measures to address climate change. [43]

Labor

The impact of global warming is twofold as it affects both labor supply and productivity. [45] As climate change progresses, a reduction in both labor supply and productivity is expected to occur in most regions of the world, particularly in tropical areas. [45] According to the study by Dasgupta et al. (2021), [45] under a 3.0 °C warming scenario, it is projected that future climate change will lead to a reduction of 18 percentage points in global total labor for low-exposure sectors and a reduction of 24.8 percentage points for high-exposure sectors. In Japan, under a low emissions scenario, the total labor force is estimated to decrease by 0.88%, whereas, under a medium emissions scenario, it is expected to decline by 2.2%. [45]

Disease

The effects of climate change are expected to widen the geographic range and environmental conditions suitable for various vector-borne infectious diseases, including dengue. [44] The likelihood of dengue transmission is amplified by rising temperatures, as the development and proliferation of mosquitoes are substantially impacted by factors such as temperature, precipitation, and humidity. [44] The risks associated with transmission suitability due to climate change have intensified over time, and if the planet continues to warm, more than 1.3 billion individuals could face temperatures conducive to Zika transmission by the year 2050. [3]

The dengue outbreak that occurred in Japan in 2014 suggests that the environmental conditions necessary for its transmission may be increasing. [46] The Asian tiger mosquito, which has adapted well to urban environments, is a significant factor in these changing dynamics. [47] According to the CMCC (2022), [3] if emissions continue at a moderate level, 84.7% of the population could face transmission-suitable mean temperatures for dengue by 2050, and under a high emissions scenario, 81.8% could be at risk. In the case of Zika, 80.7% of the population could be at risk by 2050 under a medium emissions scenario, while 82.7% could be at risk under a high emissions scenario. [3]

Japan was previously affected by malaria, and although it is no longer considered endemic, the mosquitoes responsible for its transmission still exist. [48] According to projections, by 2050, 40.4% of the Japanese population could be at risk of malaria under a low-emissions scenario, while 42.5% could be at risk under a high-emissions scenario. [3]

Research suggests that a general rise of 10 μg/m3 in daily PM2.5 concentrations in Japan is linked to a 1.3% increase in total non-accidental mortality. [49] Projections indicate that by 2060, there could be 779 deaths per year per million people in Japan due to outdoor air pollution, which is an increase from 468 deaths in 2010. [3]

Mitigation and adaptation

Adaptation

In terms of adaptation measures for agriculture and water resources, efforts should focus on the management and renovation of irrigation facilities, as well as anticipating the transplanting of crops in the hottest periods and developing crop varieties resistant to projected increases in temperatures. [3]

In terms of adaptation measures for mortality and morbidity due to higher average temperatures and the increase in the frequency and duration of heat waves, different studies have suggested that lifestyle changes such as the widespread use of air conditioners may represent an important adaptation to the risk of heat stress emergencies. [43]

Japan adopted its National Plan for Adaptation to the Impacts of Climate Change in 2015, which contains specific measures for various sectors such as Agriculture, Forestry, and Fisheries, Water Resources, Natural Ecosystems, Natural Disasters and Coastal Areas, Human Health, Industrial and Economic Activity, as well as the Life of Citizenry and Urban Life. [50]

Energy transition

In terms of energy, in 2020, Japan made a commitment to achieve full decarbonization by 2050, but it is still dedicated to reducing emissions by 26% by 2030. [3] As a result, fossil fuels will continue to be relevant and potentially vulnerable for the next few years, while carbon-free sources such as renewables and residual nuclear energy are expected to become more dominant and potentially face their own vulnerabilities in the second half of the century. [3]

G20 Countries members in map G20 map.png
G20 Countries members in map

Japan's overall performance in the Energy Transition indicator is in line with the G20 country average. [3] The country has shown high performance in the Efficiency and Electrification domains, which has been driving the transformation of the energy sector. [3] There is still room for improvement in terms of increasing the installed capacity of renewables and reducing the use of fossil fuels. [3] By making progress in these areas, Japan could also decrease the level of urban air pollution and reduce CO2 emissions per capita, leading to further improvements in the emissions indicator. [3]

Japan’s 2030 greenhouse gas emissions reduction targets by sector [51] :48
Sector20302013Reduction 2013-30
Energy originated CO2 (in Mt CO2)9271,235-25%
Industry401429-7%
Commercial168279-40%
Residential122201-39%
Transport163225-28%
Energy conversion73101-30%
Non-energy originated greenhousegases (in Mt CO2-eq)152173-12%
Land use, land-use change, and forestry (in Mt CO2-eq)-37--

Building upon its existing environmental initiatives, Japan is considering a revised climate target aimed at further reducing its greenhouse gas emissions. The government plans to achieve a reduction of 66% in emissions from 2013 levels by the fiscal year 2035. This ambitious target is part of a comprehensive strategy intended to adjust the country's energy mix by 2040, designed to provide businesses with a predictable framework for future investment and to ensure compliance with international environmental standards set by the Paris Agreement. The intermediate target for 2030 has been established at a 46% reduction in emissions. Additionally, the strategy includes a significant enhancement of nuclear power's role in the national energy portfolio, aiming to increase its share from less than 10% currently to up to 22%. This shift is seen as a key component in accelerating Japan's transition towards more sustainable energy sources. [52]

Policies and legislation

As a member in the Paris Agreement, Japan was the first nation to release a new national climate plan by 2020 as required in the 2015 agreement. However, this new plan included no major changes from the 2013 national climate plan, which aimed to reduce emissions by 26% from 2013 rates. This lack of aggressive action as the fifth largest polluter in the world led the World Resources Institute to describe the plan as "putting the world on a more dangerous trajectory." Similarly, the head of the World Wildlife Fund Japan climate and energy group, Naoyuki Yamagishi, described the plan as "completely the wrong signal." [53]

In 2018, Japan established its Strategic Energy Plan, with goals set for 2030. The plan aimed to reduce coal use from 32 to 26 percent, to increase renewables from 17 to 22–24 percent, and to increase nuclear from 6 to 20–22 percent of the energy production mix. As part of this goal, Japan announced a goal of shutting down 100 old, low-efficiency coal-fired plants out of its 140 coal fired power plants. As of 2020, 114 of Japan's 140 coal-fired plants are deemed old and inefficient. Twenty-six are considered high-efficiency, and 16 new high-efficiency plants are currently under construction. [54] Funding of overseas coal power ended in 2021. [55] The Japanese government said that they would try to be carbon neutral as soon as possible in the second half of the century. The official goal of the Japanese government is to be net zero in 2050. [56] [57]

The Cool Biz campaign introduced under former Prime Minister of Japan Junichiro Koizumi was targeted at reducing energy use through the reduction of air conditioning use in government offices. [58]

Carbon price

Since 2012 the country has levied a "Tax for Climate Change Mitigation" on petroleum, coal and natural gas at ¥ 289 ( US$ 2.63) per nominal tonne of carbon they emit when burned. [59] In addition, Tokyo has had a local carbon emissions trading system since 2010 in which carbon permits are valued at approximately US$50. [60]

In December 2009, nine industry groupings opposed a carbon tax at the opening day of the COP-15 Copenhagen climate conference stating, "Japan should not consider a carbon tax as it would damage the economy which is already among the world's most energy-efficient." The industry groupings represented the oil, cement, paper, chemical, gas, electric power, auto manufacturing and electronics, and information technology sectors. [61]

Japan launched a carbon credit market on Oct. 11, 2023, with a carbon levy expected in 2028. [62]

Municipality level

Local governments, both prefectures and municipalities, are responsible for creating their own climate change adaptation plans under the Climate Change Adaptation Act, which came into force in December 2018. They are also tasked with creating Local Climate Change Adaptation Centers to study climate change adaptation, which can be established in partnership with research institutes, universities, or other appropriate local institutions. By 2021, 22 of the 47 prefectures and 30 of the 1,741 municipalities had established plans, while 23 prefectures and 2 municipalities had established research centers. While local governments can create joint plans and centers under the legislation, by 2021 none had done so. [63]

Japan's capital Tokyo is preparing to force industry to make big cuts in greenhouse gases, taking the lead in a country struggling to meet its Kyoto Protocol obligations. Tokyo's outspoken governor, Shintaro Ishihara, decided to go it alone and create Japan's first emissions cap system, reducing greenhouse gas emission by a total of 25% by 2020 from the 2000 level. [64]

International cooperation

Protesters opposing Japan's climate change mitigation policies at the 2016 United Nations Climate Change Conference. Special Fossil of the Day Message to Japan (30948154581).jpg
Protesters opposing Japan's climate change mitigation policies at the 2016 United Nations Climate Change Conference.

Japan created the Kyoto Protocol Target Achievement Plan to lay out the necessary measures required to meet their 6% reduction commitment under the Kyoto Protocol. It was first established as an outcome of the evaluation of the Climate Change Policy Program carried out in 2004. The main branches of the plan are ensuring the pursuit of environment and economy, promoting of technology, raising public awareness, utilizing of policy measures, and ensuring international collaboration. [65]

See also

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<span class="mw-page-title-main">Climate change in Kenya</span> Emissions, impacts and responses of Kenya related to climate change

Climate change is posing an increasing threat to global socioeconomic development and environmental sustainability. Developing countries with low adaptive capacity and high vulnerability to the phenomenon are disproportionately affected. Climate change in Kenya is increasingly impacting the lives of Kenya's citizens and the environment. Climate change has led to more frequent extreme weather events like droughts which last longer than usual, irregular and unpredictable rainfall, flooding and increasing temperatures.

<span class="mw-page-title-main">Climate change in Austria</span> Overview of impacts and politics of climate change in Austria

Climate change is affecting Austrian temperatures, weather, ecosystems and biodiversity. Since 1950 temperatures have risen by 1.8 °C, and in the past 150 years glaciers have melted, losing a significant amount of their volume. Changed precipitation patterns, increased temperatures, reduced snowfall, melting glaciers and more frequent extreme weather phenomenon, such as droughts, are expected effects from climate change. Ecosystems and biodiversity in Austria are facing changes due to increasing temperatures and the spread of thermophile species, heat and drought stress on animals and plants, an increase in alien and invasive species and an increase in pathogenic organisms and the spread of disease.

<span class="mw-page-title-main">Climate change in Poland</span> Climate change in Poland: emissions, climate observations, ecological and social impacts, responses

In Poland, climate change has resulted in an increase of average temperature above 2 degrees Celsius compared to preindustrial levels, which is higher than the average level of climate change in Europe. Temperature has been observed to increase over the last decades due to anthropogenic activity, and without significant reductions in greenhouse gas emissions the effects of climate change will become ever more noticeable.

<span class="mw-page-title-main">Climate change in Italy</span> Impact of climate change in Italy

Italy is experiencing widespread impacts of climate change, with an increase in extreme events such as heatwaves, droughts and more frequent flooding; for example, Venice is facing increasing issues due to sea level rise. Italy faces many challenges adapting to climate change including the economic, social, and environmental impacts that climate change creates, and an increasingly problematic death toll from the health risks that come with climate change.

<span class="mw-page-title-main">Climate change in Indonesia</span> Emissions, impacts and responses of Indonesia

Due to its geographical and natural diversity, Indonesia is one of the countries most susceptible to the impacts of climate change. This is supported by the fact that Jakarta has been listed as the world's most vulnerable city, regarding climate change. It is also a major contributor as of the countries that has contributed most to greenhouse gas emissions due to its high rate of deforestation and reliance on coal power.

<span class="mw-page-title-main">Climate change in India</span> Emissions, impacts and responses of India related to climate change

India was ranked seventh among the list of countries most affected by climate change in 2019. India emits about 3 gigatonnes (Gt) CO2eq of greenhouse gases each year; about two and a half tons per person, which is less than the world average. The country emits 7% of global emissions, despite having 17% of the world population. The climate change performance index of India ranks eighth among 63 countries which account for 92% of all GHG emissions in the year 2021.

<span class="mw-page-title-main">Climate change in the Middle East and North Africa</span> Emissions, impacts and responses of the MENA region related to climate change

Climate change in the Middle East and North Africa (MENA) refers to changes in the climate of the MENA region and the subsequent response, adaption and mitigation strategies of countries in the region. In 2018, the MENA region emitted 3.2 billion tonnes of carbon dioxide and produced 8.7% of global greenhouse gas emissions (GHG) despite making up only 6% of the global population. These emissions are mostly from the energy sector, an integral component of many Middle Eastern and North African economies due to the extensive oil and natural gas reserves that are found within the region. The region of Middle East is one of the most vulnerable to climate change. The impacts include increase in drought conditions, aridity, heatwaves and sea level rise.

<span class="mw-page-title-main">Climate change in South Africa</span> Emissions, impacts and responses of South Africa related to climate change

Climate change in South Africa is leading to increased temperatures and rainfall variability. Evidence shows that extreme weather events are becoming more prominent due to climate change. This is a critical concern for South Africans as climate change will affect the overall status and wellbeing of the country, for example with regards to water resources. Just like many other parts of the world, climate research showed that the real challenge in South Africa was more related to environmental issues rather than developmental ones. The most severe effect will be targeting the water supply, which has huge effects on the agriculture sector. Speedy environmental changes are resulting in clear effects on the community and environmental level in different ways and aspects, starting with air quality, to temperature and weather patterns, reaching out to food security and disease burden.

Climate change may have a range of impacts in the Republic of Ireland. Increasing temperatures may change weather patterns, with the potential for increased heatwaves, rainfall and storm events, with subsequent impacts on people through flooding Climate change has been assessed to be the single biggest threat to Ireland, according to the head of the Defence Forces of Ireland, Mark Mellett.

<span class="mw-page-title-main">Climate change in Israel</span>

Israel, like many other countries in the Middle East and North Africa, experiences adverse effects from climate change. Annual and mean temperatures are increasing in Israel, with mean temperature expected to increase between 1.6 and 1.8 °C by 2100. There is a reduction in annual precipitation and delayed winter rains. Israel is already experiencing droughts and water shortages. Heatwaves are other natural hazards expected to increase with climate change.

References

  1. 1 2 3 4 5 "CP - Home". www.climate-of-the-past.net. Retrieved 2023-05-16.
  2. "Japan has a chequered record on climate change". The Economist. ISSN   0013-0613 . Retrieved 2023-05-16.
  3. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 "Japan". G20 Climate Risk Atlas. 2021-10-19. Retrieved 2023-05-17.
  4. ● Source for carbon emissions data: "Territorial (MtCO₂) / Emissions / Carbon emissions / Chart View". Global Carbon Atlas. 2024.
    ● Source for country population data: "Population 2022" (PDF). World Bank. 2024. Archived (PDF) from the original on 22 October 2024.
  5. McCurry, Justin (2020-10-26). "Japan will become carbon neutral by 2050, PM pledges". The Guardian. ISSN   0261-3077 . Retrieved 2020-10-26.
  6. "Japan documents". unfccc.int. Archived from the original on 2019-11-14. Retrieved 2021-05-12.
  7. "Per capita CO₂ emissions". Our World in Data. Retrieved 2021-08-24.
  8. "Annual CO₂ emissions". Our World in Data. Retrieved 2021-03-12.
  9. "Report: China emissions exceed all developed nations combined". BBC News. 2021-05-07. Retrieved 2021-05-07.
  10. "As global carbon emissions surge, can China and Japan quit the coal?". www.cbsnews.com. Retrieved 2021-05-12.
  11. "Last planned coal plant project in Japan scrapped amid green push | The Asahi Shimbun: Breaking News, Japan News and Analysis". The Asahi Shimbun. Retrieved 2021-09-18.
  12. "New study finds potential $71 billion stranded asset problem for coal in Japan". Institute for Energy Economics & Financial Analysis. 2019-10-07. Retrieved 2021-09-18.
  13. "bp Statistical Review of World Energy" (PDF). www.bp.com (71st ed.). 2022. p. 12. Retrieved 27 April 2024.
  14. 1 2 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 (1): 29. Bibcode:2021ComEE...2...29L. doi: 10.1038/s43247-021-00097-8 . PMC   8064561 . PMID   33899003.
  15. "1.5°C-consistent benchmarks for enhancing Japan's 2030 climate target | Climate Action Tracker". climateactiontracker.org. 4 March 2021. Archived from the original on 2021-03-04. Retrieved 2021-03-10.
  16. "Japan: CO2 emissions by sector". Statista. Retrieved 2021-08-24.
  17. "Japan: CO2 emissions by sector". Statista. Retrieved 2024-04-19.
  18. "Japan's Annual Emissions Drop as Industrial Pollution Shrinks". Bloomberg.com. 2024-04-11. Retrieved 2024-04-13.
  19. 1 2 3 4 Kii, M., Isikawa, R., & Komeani, Y. (2023). Toward a carbon neutral urban transportation system in Japan. Urban Forestry & Urban Greening, Volume 62, 2021, 127171
  20. 1 2 Ju, Y., Sugiyama, M., Kato, E. et al. (2021). Industrial decarbonization under Japan’s national mitigation scenarios: a multi-model analysis. Sustain Sci 16, pp. 411 – pp. 427
  21. 1 2 Statista. 2020. Carbon dioxide emissions from the manufacturing sector in Japan in 2020, by industry. Available at, https://www.statista.com/statistics/1305632/japan-carbon-dioxide-emissions-manufacturing-sector-by-industry Accessed: 2023-04-10
  22. 1 2 "Japan's Annual Emissions Drop as Industrial Pollution Shrinks". Bloomberg.com. 2024-04-11. Retrieved 2024-04-12.
  23. Hausfather, Zeke; Peters, Glen (29 January 2020). "Emissions – the 'business as usual' story is misleading". Nature. 577 (7792): 618–20. Bibcode:2020Natur.577..618H. doi: 10.1038/d41586-020-00177-3 . PMID   31996825.
  24. Schuur, Edward A.G.; Abbott, Benjamin W.; Commane, Roisin; Ernakovich, Jessica; Euskirchen, Eugenie; Hugelius, Gustaf; Grosse, Guido; Jones, Miriam; Koven, Charlie; Leshyk, Victor; Lawrence, David; Loranty, Michael M.; Mauritz, Marguerite; Olefeldt, David; Natali, Susan; Rodenhizer, Heidi; Salmon, Verity; Schädel, Christina; Strauss, Jens; Treat, Claire; Turetsky, Merritt (2022). "Permafrost and Climate Change: Carbon Cycle Feedbacks From the Warming Arctic". Annual Review of Environment and Resources. 47: 343–371. doi: 10.1146/annurev-environ-012220-011847 . Medium-range estimates of Arctic carbon emissions could result from moderate climate emission mitigation policies that keep global warming below 3°C (e.g., RCP4.5). This global warming level most closely matches country emissions reduction pledges made for the Paris Climate Agreement...
  25. Phiddian, Ellen (5 April 2022). "Explainer: IPCC Scenarios". Cosmos . Archived from the original on 20 September 2023. Retrieved 30 September 2023. "The IPCC doesn't make projections about which of these scenarios is more likely, but other researchers and modellers can. The Australian Academy of Science, for instance, released a report last year stating that our current emissions trajectory had us headed for a 3°C warmer world, roughly in line with the middle scenario. Climate Action Tracker predicts 2.5 to 2.9°C of warming based on current policies and action, with pledges and government agreements taking this to 2.1°C.
  26. "Japan 2030: Tackling climate issues is key to the next decade". Deep reads from The Japan Times. Retrieved 2020-11-08.
  27. The latest global warming projection by using the Earth Simulator has been completed Archived 2009-02-26 at the Wayback Machine , Center for Climate System Research, University of Tokyo
  28. 1 2 BBC Visual and Data Journalism team (2019) How much warmer is your city? - BBC News, News. Available at: https://www.bbc.co.uk/news/resources/idt-985b9374-596e-4ae6-aa04-7fbcae4cb7ee Accessed: 2023-04-10
  29. 1 2 Lindsey, R. (2022) Climate Change: Global Sea Level | NOAA Climate.gov. Available at: http://www.climate.gov/news-features/understanding-climate/climate-change-global-sea-level Accessed: 2023-04-26
  30. 1 2 Kim, S., Tachikawa, Y., Nakakita, E., & Takara, K. (2009). Climate change impact on water resources management in the Tone River Basin, Japan. Kyoto University Disaster Prevention Research Institute Annual Report. no. 52B, pp. 587-606
  31. 1 2 3 4 5 6 7 8 9 10 11 Ogawa-Onishi, Y. and Berry, P.M. (2013) ‘Ecological impacts of climate change in Japan: The importance of integrating local and international publications’, Biological Conservation, 157, pp. 361–371. Available at: https://doi.org/10.1016/j.biocon.2012.06.024
  32. 1 2 Hiura, Tsutom; Go, Sato; Iijima, Hayato (2019-10-01). "Long-term forest dynamics in response to climate change in northern mixed forests in Japan: A 38-year individual-based approach". Forest Ecology and Management. 449: 117469. doi:10.1016/j.foreco.2019.117469. ISSN   0378-1127.
  33. 1 2 "Japan". G20 Climate Risk Atlas. 2021-10-19. Retrieved 2023-04-29.
  34. 1 2 Komatsu, Masayuki; Nakamura, Tomoko (2021-10-01). "Ecosystem management for protection of Japanese ocean and fishery resources". Marine Policy. 132: 104682. doi:10.1016/j.marpol.2021.104682. ISSN   0308-597X.
  35. 1 2 3 4 5 6 7 8 Sato, M. et al. (2020) ‘Changes in the potential stocks of coral reef ecosystem services following coral bleaching in Sekisei Lagoon, southern Japan: implications for the future under global warming’, Sustainability Science, 15(3), pp. 863–883. Available at: https://doi.org/10.1007/s11625-019-00778-6
  36. McCurry, Justin (2017-01-12). "Almost 75% of Japan's biggest coral reef has died from bleaching, says report". The Guardian. ISSN   0261-3077 . Retrieved 2023-05-16.
  37. Hasegawa, T.; Kuwagata, T.; Nishimori, M.; Ishigooka, M.; Murakami, M.; Yoshimoto, M.; Matsuzaki, H. (2009). "Recent warming trends and rice growth and yield in Japan. In MARCO Symposium on Crop Production under Heat Stress: Monitoring, Impact Assessment and Adaptation". National Institute for Agro-Environmental Studies, Tsukuba, Japan.
  38. Ishigooka, Y., Nishimori, M., Kuwagata, T., & Hasegawa, T. (2019). Impact of Climate Change on Rice Productivity and Adaptation Strategy in Japan. Climate Smart Agriculture for the Small-Scale Farmers in the Asian and Pacific Region, vol 177
  39. Matsumoto, K., & Takagi, M. (2017). Climate Change Impact and Adaptation on Rice Production in Japan. Environmental Science, vol 30, no. 6, pp. 346–356
  40. .Ishigooka, Y., Fukui, S., Hasegawa, T., Kuwagata, T., Nishimori, M., & Kondo, M. (2017). Large-scale evaluation of the effects of adaptation to climate change by shifting transplanting date on rice production and quality in Japan. Journal of Agricultural Meteorology, 73(4), 156-173
  41. 1 2 3 4 5 6 7 Department of Economic and Social Affairs (DESA) (2019), Population Division. United Nations, 2018 Revision of World Urbanization Prospects
  42. Japanese Red Cross Society (JRC) (2018). Japan Floods and Landslides 2018. Available at: https://www.jrc.or.jp/english/relief/180719_005356.html Accessed: 2023-04-28
  43. 1 2 3 4 Nakamura, S., Kusaka, H., Sato, R., & Sato, T. (2022). Heatstroke Risk Projection in Japan under Current and Near Future Climates. Journal of the Meteorological Society of Japan.Ser. II, 100(4), 597-615
  44. 1 2 3 Ryan, S. J., Carlson, C. J., Mordecai, E. A., & Johnson, L. R. (2019). Global expansion and redistribution of Aedes-borne virus transmission risk with climate change. PLoS neglected tropical diseases, 13(3), e0007213
  45. 1 2 3 4 Dasgupta, S., van Maanen, N., Gosling, S. N., Piontek, F., Otto, C., & Schleussner, C. F. (2021). Effects of climate change on combined labour productivity and supply: an empirical, multi-model study. The Lancet Planetary Health, vol. 5, no. 7, pp.455-465
  46. Quam, M. B., Sessions, O., Kamaraj, U. S., Rocklöv, J., & Wilder-Smith, A. (2016). Dissecting Japan's dengue outbreak in 2014. The American Journal of Tropical Medicine and Hygiene, 94(2), 409
  47. "Climate change brings more risk of diseases from mosquitoes | The Asahi Shimbun: Breaking News, Japan News and Analysis". The Asahi Shimbun. Retrieved 2024-04-19.
  48. Macnee, R., Tokai, A., & Kim, O. Y. (2016). A Comparative Analysis of Malaria Risk in Japan and the Republic of Korea: Current Trends and Future Risk in the Context of Climate Change. Journal of the Japan Society for Risk Research, 25(4), 189-198
  49. Michikawa, T., Ueda, K., Takami, A., Sugata, S., Yoshino, A., Nitta, H., & Yamazaki, S. (2019). Japanese nationwide study on the association between short-term exposure to particulate matter and mortality. Journal of epidemiology, 29(12), 471-477
  50. Climate Policy Radar (2015), National Plan for Adaptation to the Impacts of Climate Change. Available at: https://climate-laws.org/document/national-plan-for-adaptation-to-the-impacts-of-climate-change_7186 Accessed at: 2023-04-28
  51. IEA, International Energy Agency (2021). "Japan 2021 Energy Policy Review". www.iea.org. p. 48. Retrieved 24 April 2024.
  52. "Japan Considers Emissions Cuts in New Energy Plan, Says Nikkei". Bloomberg.com. 2024-04-15. Retrieved 2024-04-15.
  53. Sengupta, Somini (1 April 2020). "Japan's climate plan sends 'wrong signal'". The New York Times. Retrieved 1 April 2020.
  54. "Japan aims to shut down 100 inefficient coal plants within decade". The Japan Times. Archived from the original on 3 July 2020. Retrieved 3 July 2020.
  55. Farand, Chloé (2021-12-27). "2021 in coal: China's dirty recovery mars international finance crackdown". Climate Home News. Retrieved 2021-12-28.
  56. "Japan 2030: Tackling climate issues is key to the next decade". Deep reads from The Japan Times. Retrieved 2020-09-24.
  57. "Japan's New Climate Pledge Faces a Massive Hurdle". www.msn.com. Retrieved 2020-11-08.
  58. "'Cool Biz' energy-saving campaign begins in Japan". The Japan Times. May 1, 2020.
  59. "Taxing Energy Use 2019: Country Note – Japan" (PDF). oecd.org. 2019. Archived (PDF) from the original on 4 September 2021. Retrieved 2021-07-06.
  60. Arimura, Toshi H.; Abe, Tatsuya (2021-03-18). "The impact of the Tokyo emissions trading scheme on office buildings: what factor contributed to the emission reduction?". Environmental Economics and Policy Studies. 23 (3): 517–533. doi: 10.1007/s10018-020-00271-w . ISSN   1432-847X. S2CID   216294026.
  61. "Japan industry unites against carbon tax". Reuters. 7 December 2009. Archived from the original on 19 November 2021. Retrieved 9 August 2010.
  62. Obayashi, Yuka; Golubkova, Katya; Obayashi, Yuka (2023-10-11). "Explainer: Japan's carbon pricing scheme kicks off at Tokyo Stock Exchange". Reuters. Retrieved 2023-11-12.
  63. Yuki Ohashi; Takuya Hattori; Yoshifumi Masago (January 2021). "Progress of Local Adaptation in Japan" (PDF). Institute for Global Environmental Strategies. Retrieved 2 April 2021.
  64. World Business Council for Sustainable Development (WBCSD) Archived January 4, 2009, at the Wayback Machine
  65. Gist of the Kyoto Protocol Target Achievement Plan” United Nations Framework Convention on Climate Change and then they beat each other up