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Plummeting Renewable Energy, Battery Prices Mean China Could Hit 62% Clean Power And Cut Costs 11% By 2030

China is the world’s largest greenhouse gas emitter, and is building the most power plants of any country in the world, making its decarbonization paramount to preventing dangerous climate change. But the costs of wind, solar, and energy storage have fallen so fast that building clean power is now cheaper than building fossil fuels – a lot cheaper.

New research shows plummeting clean energy prices mean China could reliably run its grids on at least 62% non-fossil electricity generation by 2030, while cutting costs 11% compared to a business-as-usual approach. Once again, it’s cheaper to save the climate than destroy it.

40MW Solar Power Plant Under Construction In Huaian
HUAI AN, CHINA - JUNE 11: Workers install solar panels at the construction site of 40MW photovoltaic on-grid power project of China Huaneng Group on June 11, 2018 in Huai an, China. The first phase with installed capacity of 30 megawatts will be put into operation at the end of June this year.  VCG VIA GETTY IMAGES

While fast-falling clean energy prices make China’s clean energy transition possible, only smart policy can achieve a low-carbon electricity future. Fortunately, this clean energy transition would also spur long-term sustainable economic growth while cleaning the country’s air.

Short-term decisions, long-term impact

COVID-19 sparked a global emissions drop—China’s tumbled by an estimated 25% in the first quarter of 2020. But without decisive action to transform the country’s energy system, the pandemic could be a blip in China’s long-term rising emissions trend. May data showed a rapid rebound driven by coal power and cement production, with emissions up 4% to 5% year over year.

The economic recovery choices China makes today could either improve or worsen its air and water quality. While the Ministry of Ecology and Environment recently affirmed the country’s climate commitment, which promises to peak emissions and reach 20% non-fossil electricity generation by 2030, its coronavirus recovery effort could lean heavily on polluting sources as China approved more coal permits in March 2020 than all of last year.

Environmentalist Creates Picture Book About Climate Change
SUIHUA, CHINA: Slum dwellings, pumping out coal smoke into an already highly polluted atmosphere pictured in Suihua, China. AN ENVIRONMENTAL campaigner was arrested in China for photographing the devastating effects of climate change. Ashley Cooper is collating a picture book of his work, which details the specific climate change occurrences from Alaska - where he started his journey - to Bolivia where he finished. The 54 year old originally decided to pursue the expedition 14 years ago when he witnessed the effects of global warming on 600 residents in Alaska who lost their homes to the altering sea conditions. Ashley Cooper / Barcroft Media via Getty Images

China’s scale makes these decisions globally important, and potentially perilous – emissions from the country’s power sector are comparable to combined power sector emissions from the United States and Europe.

Its coal capacity additions in 2019, for example, accounted for nearly two-thirds of all capacity added worldwide. Yet the country has also demonstrated unparalleled ability to scale zero-carbon generation, leading the world in installed wind and solar capacity, as well as nuclear power.

China plans its economy in “Five Year Plans” guiding development and serving as the principal measure of performance for government officials. The plans lay out binding, quantitative targets for everything from the economy and infrastructure, to health and social development, to the environment.

China’s leaders are currently developing the 14th Five Year Plan for 2021-2025, and greater climate and clean energy ambition could accelerate decarbonization. For example, the country’s current climate goals allow emissions to increase through 2030 before declining, and to date the country’s carbon dioxide (CO2) targets have been expressed as carbon intensity per unit of GDP allowing for emissions increases with economic growth.

A more realistic picture of energy costs

Despite the precarious future emissions outlook, China’s current climate targets are within reach, with multiple studies mapping out scenarios to achieve high penetrations of renewables in the coming decades.

But as the new paper from Stony Brook University and Lawrence Berkeley National Laboratory researchers points out, even these optimistic analyses fail to capture just how dramatically renewable energy and storage prices have dropped in recent years. The global weighted-average levelized costs of electricity (LCOE) of utility-scale solar panels, onshore wind, and battery storage have fallen by 77%, 35%, and 85%, respectively, between 2010 and 2018.

Wind Turbines Installation On Mountain In Ji'an
JI'AN, CHINA - JUNE 15: Workers install wind turbines at Yuxia wind farm on mountain on June 15, 2020 in Ji'an, Jiangxi Province of China.  VCG VIA GETTY IMAGES

And widely cited references such as the International Energy Agency’s World Energy Outlook and the U.S. government’s International Energy Outlook have underestimated clean energy development due to fast-falling costs quickly rendering previous analysis outdated.

Given the mismatch between projections and real-world project economics, the researchers updated SWITCH-China, an optimization model originally developed at University of California-Berkeley, to determine how different renewable energy cost scenarios affect future deployment (SWITCH is a loose acronym for investment in solar, wind, transmission, conventional, and hydro sources).

The study explores four scenarios: business-as-usual, which assumes current policies continue with moderate cost drops for renewables; low-cost renewables, with continuing rapid decreases in costs for renewables and storage; a carbon constraints scenario, in which carbon is capped at 50% lower than the 2015 level in 2030 on top of the low-cost renewables scenario; and a deep carbon constraints scenario capping 2030 emissions 80% below 2015 levels.

China’s clean energy economic opportunity

If the rapid downward price trend for renewable energy continues and capital investment choices shift away from fossil fuels —as outlined in the second scenario above—China can provide 62% of its electricity from non-fossil sources by the end of the decade.

Power costs decrease in this scenario by 11%, from $73.52 per megawatt-hour (MWh) under the status-quo to $65.08/MWh. Power sector emissions would be 22% lower compared to 2015 levels instead of 5% higher. This trend mirrors widely reported modeling showing the U.S. can reach 90% clean energy by 2035 while cutting wholesale power costs 10%

With a lower carbon cap of 50%, though, China could cut 2015 electricity sector emissions in half and still come in with costs 6% lower than the base case.

Higher wind and solar energy concentrations on the grid spur a major uptick in storage capacity. To support 62% non-fossil energy, the analysis estimates storage capacity should increase more than eightfold from the current trajectory, from 34 gigawatts (GW) to 290 GW. The model also allows existing natural gas generation to fill in the gaps to meet peak load, though the need for natural gas capacity would be cut nearly in half in this low-cost renewables scenario.

China transmission system in 2030 under a low-carbon scenario
Provincial total capacity mix and new transmission lines required by 2030 under the R scenario. The pie charts shows the total power capacity mix in each province, and the red lines show the new interprovincial transmission lines to bring electricity from resource centers to demand centers.  STONY BROOK UNIVERSITY, LAWRENCE BERKELEY NATIONAL LABORATORY

Regional variations in demand and renewable generation capacity also will require changes to China’s transmission infrastructure. Much of the nation’s solar capacity is concentrated in the northwest, which becomes a net exporter of electricity to the central, northern, and eastern regions under the low-cost renewables scenario. As much as 35 GW of transmission capacity could be needed to move solar and wind generation to centers of demand such as Jing-Jin-Ji, the Yangtze Delta, and the Pearl River Delta—double today’s cross-provincial transmission capacity.

China can have clean air and economic growth thanks to cheap clean energy

While plummeting prices for wind, solar, and energy storage technologies make this clean energy transition possible for China, policy action is required for its’ low-carbon electricity future.

Because the 14th Five Year Plan and other policies expected in coming years will determine China’s energy investment priorities and decarbonization trajectory, policymakers should leverage current and projected low prices for renewable energy to set ambitious targets for deploying clean power. These targets should be accompanied by decisions to reduce fossil fuel investments, and provide job training to help workers transition to the clean energy economy.

Wind Turbines Installation On Mountain In Ji'an
JI'AN, CHINA - JUNE 15: Workers install wind turbines at Yuxia wind farm on mountain on June 15, 2020 in Ji'an, Jiangxi Province of China. VCG VIA GETTY IMAGES

China could also accelerate its “peaking” date by five years, ensuring that official plans include reducing overall emissions starting in 2025. The country could also support an absolute carbon cap with stronger underlying targets for key economic sectors—power, industry, transportationbuildings, and non-CO2 emissions.

These targets would generate demand for new infrastructure that fuels near-term economic recovery through clean energy additions, and wise long-term investments that provide cleaner air at lower costs.

Dirty air is incompatible with economic growth and a prosperous modern society – thanks to cheap clean energy, China can have both.

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