China's Low-carbon Frontier

Large and Small Hydropower, the “Old” Technologies

LHP has been a major strategic industry in China since the 1950s. Mao Zedong promoted dam construction mainly for flood protection and irrigation in 1960s and 1970s;Footnote ⁵⁷ in the 1980s, Chinese state energy sector reforms and loans extended by foreign creditors accelerated dam construction for hydroelectricity.Footnote ⁵⁸ Hydropower entities that were formerly arms of government ministries were reorganized as professional corporations and allowed to establish subsidiaries, finance companies and research institutes – what Webber and Han call China's “water machine.”Footnote ⁵⁹ Indeed, five of the hundred or so enterprises directly situated under the powerful State-Owned Assets Supervision and Administration Commission are large hydro-engineering corporations, while others are owned by central or provincial governments. These SOEs are responsible for all LHP construction in China, and are contractors for more than 70 per cent of hydropower plants around the world.Footnote ⁶⁰

The GWDS was a boon for the LHP industry. The “best” hydropower resources in China are located in Yunnan and Sichuan, where rivers drop continuously in elevation in gorges suitable for dam construction. Chinese state discourse viewed LHP as a key energy source for national economic development and modernization, particularly for manufacturing industries in the Pearl River Delta.Footnote ⁶¹ In the process, China's leaders maintained, LHP would pull “backward” western regions forward through investment and industrial growth.Footnote ⁶² Preferential policies for LHP – including access to capital, state investment in grid infrastructure and guaranteed electricity uptake by the state grid – made Yunnan and Sichuan a major destination for SOEs developing new projects in the untapped Yangtze River and its watersheds.Footnote ⁶³ As a result, China's installed LHP capacity more than tripled from 90 GW in 2000 to 305 GW in 2015, increasing its share in the national electricity mix from 8 per cent to 22 per cent.Footnote ⁶⁴

The characteristics of SHP in western China are somewhat different. SHP in China refers to plants with an installed capacity of less than 50 MW; internationally, the definition is generally set at less than 10 MW.Footnote ⁶⁵ China's first hydropower plant began operating in Yunnan in 1911, and since then more than 47,000 have been constructed.Footnote ⁶⁶ In the Mao Zedong era, SHP construction was encouraged by the central government in order to generate electricity for areas outside of the grid network; local governments and villagers responded by building micro (<100 kilowatts) and mini (<1 MW) plants out of local materials.Footnote ⁶⁷ In the 1980s and 1990s, the State Council introduced and extended subsidies for SHP plants in hundreds of “rural electrification” counties, the majority of them in western China.Footnote ⁶⁸ Hydropower industry reforms in the 1990s enabled the private sector to purchase local-government-owned SHP plants and construct new (and larger) plants in areas with a guaranteed grid connection. Indeed, compared to the SOE-dominated large hydropower industry, SHP is the domain of private enterprises that operate 80 per cent of all SHP assets.Footnote ⁶⁹

Despite these differences, though, LHP and SHP followed similar boom trajectories in western China. In the early 2000s, after the announcement of the GWDS, the Ministry of Water Resources launched the Small Hydropower to Replace Fuelwood Programme (xiao shuidian dai ranliao xiangmu 小水电代燃料项目) that offered subsidies for some SHP plants in mountainous areas of the south-west. In 2002, the National Energy Administration (NEA) under the National Development and Reform Commission (NDRC) implemented energy sector reforms that centralized all grids under two state-owned grid enterprises and forced the connection of all power plants to the grid, including SHP plants.Footnote ⁷⁰ Then, in 2006, the National People's Congress passed the Renewable Energy Law that required the two grid enterprises to purchase and prioritize electricity from renewable sources – effectively awarding SHP operators the grid uptake guarantee that LHP SOEs already enjoyed. Moreover, SHP was included in cadre promotion criteria for local governments in Yunnan and Sichuan, incentivizing them to increase approvals.Footnote ⁷¹ As a result, thousands of new SHP plants were constructed in a short time, tripling installed capacity from 31 GW in 2000 to 76 GW in 2015; 43 per cent of this capacity was built in western China, mainly Yunnan and Sichuan.Footnote ⁷²

How did hydropower in western China resemble a low-carbon frontier? The first aspect was the prevalence of a discourse of exploitable low-carbon value. In the 1980s and 1990s, when LHP plants were being constructed in western China, they were framed by the state as modern infrastructure that contributed to economic growth and energy security.Footnote ⁷³ By the mid-2000s, the discourse had shifted: Lee notes that, after the 2004 United Nations Declaration on Hydropower and Sustainable Development, the NDRC referred to hydropower as a “clean” renewable energy – language included in the 11th (2006–2010), 12th (2011–2015) and 13th (2016–2020) Five-Year Plans.Footnote ⁷⁴ SHP, in particular, was recognized as a model of “green development” and became the main technology to receive financing from the Clean Development Mechanism (CDM).Footnote ⁷⁵ This discourse, in turn, represented Yunnan and Sichuan as stores of hydropower potential that had to be tapped to further national low-carbon transitionFootnote ⁷⁶ – especially since, in the mid-2000s, wind and solar were in their infancy in China.

Hydropower infrastructure, meanwhile, turned low-carbon value into a commodity that could be bought and sold in the form of electricity. In the case of LHP, the central government awarded SOEs river rights in particular basins and established a price at which the grid would purchase electricity from each plant.Footnote ⁷⁷ For SHP, prefectural development and reform commissions (DRCs) were allowed to grant construction rights to operators for plants with a capacity of less than 50 MW and negotiate on-grid purchase prices directly.Footnote ⁷⁸ Local officials in Yunnan and Sichuan offered high purchase prices, tax holidays and express approvals for SHP plants in their administrative districts.Footnote ⁷⁹ SHP investors from Zhejiang, Fujian and Guangdong were able to obtain low-interest loans to from local banks to construct new plants; many also received financing from the CDM.Footnote ⁸⁰ The pace of hydropower construction grew to a frenzy in the mid-to-late 2000s and early 2010s, with LHP projects catalysing investment in transmission infrastructure that SHP operators could use to access new sites in remote areas. Chinese state media would later characterize this period as a “disorderly, unregulated and environmentally destructive” period of SHP developmentFootnote ⁸¹ – a kind of frontier boom dynamic.

Much of the value of this new hydropower commodity was transferred to eastern China, even as local governments took in royalties. West-to-east transmission was always the stated purpose of most LHP projects, and was facilitated by dedicated high-voltage grid infrastructure that (for the largest dams) bypassed the local network.Footnote ⁸² SOE operators were required to pay royalties to the central and provincial governments,Footnote ⁸³ generating consistent local revenues during the boom. SHP in western China also followed this model; in parts of Yunnan, for example, more than 80 per cent of SHP electricity was transmitted outside of the prefecture, much of it to Guangdong.Footnote ⁸⁴ Still, local governments greatly expanded their budgets by collecting tax based on SHP power output, and by attracting mining and mineral processing industries to use hydroelectricity.Footnote ⁸⁵ Nevertheless, infrastructure-adjacent communities experienced negative impacts of the boom: villagers near large dams were forced to resettle and shift their livelihoods from farming,Footnote ⁸⁶ and some villages near SHP plants experienced reduced irrigation water access.Footnote ⁸⁷

Hydropower construction began to slow in the 2010s, and by mid-decade LHP and SHP plants faced significant curtailment, reaching a rate of 13.7 per cent in Yunnan in 2016.Footnote ⁸⁸ The reasons for LHP curtailment were diverse, including an economic slowdown, inadequate transmission capacity, governance challenges, inflexible electricity markets and extreme seasonal and annual variability in precipitation.Footnote ⁸⁹ New project approvals slowed as a result. SHP was much harder hit, primarily due to overcapacity problems and grid bottlenecks that prevented electricity from being “exported” outside of the local area. SHP operators were forced to curtail generation by up to 50 per cent in the wet season, doubling the amount of time to obtain a return on investment and vastly reducing local government tax revenues. In 2016, the Yunnan and Sichuan governments halted the ability of prefectural DRCs to approve plants,Footnote ⁹⁰ followed by denunciations of SHP in state-run media.Footnote ⁹¹ An association of SHP operators in Yunnan complained to the Yunnan government and sought to negotiate a new on-grid purchase price, but to no avail. Some small SHP companies faced bankruptcy, while others managed to sell assets at a discount to SOEs. In 2018, provincial governments began demolishing plants they considered illegal; in 2019, new SHP construction was severely limited by the NEA.Footnote ⁹² Today, LHP curtailment rates have improved and new projects have somewhat rebounded – with significant new dams and pumped storage targeted in the 14th Five-Year Plan – but the SHP boom for local governments is over.

Wind and Solar PV, the “New” Technologies

Wind and solar PV, like SHP, were first promoted in China for rural electrification and local development.Footnote ⁹³ In 1996, as part of the Ninth Five-Year Plan (1996–2000), the NEA introduced a “new energy” development programme of grants and loans to local governments for wind and solar energy infrastructure construction.Footnote ⁹⁴ An additional 2.6 billion yuan was allocated for home and village wind/solar PV systems through the Brightness Programme (guangming xiangcun xiangmu 光明乡村项目) and Township Electrification Programme (xiangzhen dianqihua xiangmu 乡镇电气化项目) in the 10th Five-Year Plan (2001–2005), specifically targeting the north-western provinces of Gansu, Qinghai, Inner Mongolia, the Tibet Autonomous Region and Xinjiang as part of the GWDS.Footnote ⁹⁵ For rural and remote communities in western China – especially the north-west – wind and solar systems were cheaper and easier to install than small-scale thermal plants or SHP.Footnote ⁹⁶ Expenditures by the Ministry of Water Resources and grid enterprises on rural grid expansion and upgrades in the mid-to-late 2000s connected many off-grid villages to the electricity network and increased the stability of supply.Footnote ⁹⁷

These rural renewable energy programmes also helped foster the development of China's wind turbine and solar PV technology manufacturing industries. In 1996, the NDRC announced the Riding the Wind Programme (chengfeng jihua 乘风计划), which encouraged R&D for domestic wind turbines; preferential policies that followed slashed taxes on turbine imports, allowing domestic wind enterprises to learn from foreign technologies.Footnote ⁹⁸ State-owned power engineering and construction firms established wind turbine manufacturing arms to compete with a burgeoning private market. The central government extended similar policies to the solar industry in the early 2000s to both fulfil domestic needs and to stake a position in the global market for PV cells.Footnote ⁹⁹ Solar production capacity quickly ramped up in the mid-2000s, led by private corporations with aggressive policy support from local governments.Footnote ¹⁰⁰ In 2010, after the 2007–2008 Great Financial Crisis (GFC), solar PV was highlighted in the State Council's list of strategic emerging industries, and the China Development Bank extended 500 billion yuan in credit lines to the solar PV technology manufacturers.Footnote ¹⁰¹

Investments in the production of components set the stage for a western China wind and solar infrastructure boom. In 2003, the NDRC began a wind concession pilot project that granted 20-year operational concessions for large-scale wind farms through a competitive bidding process.Footnote ¹⁰² The Renewable Energy Law in 2006 required grid operators to purchase all generated wind energy and established a national fund to award subsidies for wind and solar construction, adding to a 2001 policy that cut the value-added tax (VAT) for wind projects in half (to 8.5 per cent). To speed up approvals, the NDRC empowered provincial DRCs to approve wind farms of up to 50 MW installed capacity.Footnote ¹⁰³ A domestic feed-in tariff (FiT) for wind energy was introduced by the NDRC in 2009 based on wind resource potential – western China was given the lowest tariff, but continued to attract the most investment.Footnote ¹⁰⁴ The 11th Five-Year Plan,Footnote ¹⁰⁵ the 11th Five-Year Energy Development Plan (2006–2010)Footnote ¹⁰⁶ and the Medium- and Long-term Development Plan for Renewable Energy (kezaisheng nengyuan zhongchangqi fazhan guihua 可再生能源中长期发展规划)Footnote ¹⁰⁷ set ambitious targets for installed wind capacity. By the late 2000s, wind farm construction in western China had proceeded so rapidly that the NDRC decided to shift approvals from for plants of less than 50 GW capacity from the provincial back to the central level (though this policy was again reversed in 2013).Footnote ¹⁰⁸ Installed wind capacity leapt from just 2 GW in 2006 to 186 GW in 2013, 49 per cent of which was situated in western China.Footnote ¹⁰⁹

The solar boom in western China began a few years later than wind, as manufacturers had previously only targeted export markets and were faced with a huge glut of panels after the 2007–2008 GFC.Footnote ¹¹⁰ In 2009, the Ministry of Science and Technology and the NEA launched the Golden Sun Programme (jin taiyang xiangmu 金太阳项目) that provided a 50 per cent up-front subsidy for grid-connected systems, setting a max of 20 MW installed capacity for each province – an approach that led to extensive subsidy fraud as developers engaged in false bidding and used low-quality products.Footnote ¹¹¹ That same year, the NEA led (as it did with wind) a concession programme for large-scale solar PV, with 20-year operational leases and competitive bidding, with all 290 MW of new capacity installed in north-west China.Footnote ¹¹² After lobbying from the industry and provincial governments,Footnote ¹¹³ the NDRC established a nationwide solar FiT in 2011 based on power output.Footnote ¹¹⁴ Like FiT for wind generation, the solar FiT was set at different levels based on “zones” of solar potential, but which still made the solar-rich western provinces hugely attractive to developers. The provinces of Gansu, Qinghai and Ningxia submitted more than 3 GW of solar projects for NDRC approval in early 2011 so as to obtain a higher FiT rate for projects initiated before July of that year.Footnote ¹¹⁵ This FiT policy catalysed the solar energy boom that grew from a mere 2 GW in 2011 to 39 GW in 2015;, 44 per cent of which was situated in western China.Footnote ¹¹⁶

How do wind and solar in western China resemble a low-carbon frontier? Discursively, the region was framed as a huge store of exploitable potential in state media: an area near Urumqi in Xinjiang was called China's “Wind Valley”;Footnote ¹¹⁷ a large wind project in Inner Mongolia was hailed as the “Grassland Three Gorges”;Footnote ¹¹⁸ and a high-altitude region of Qinghai was described as a “Solar Plateau.”Footnote ¹¹⁹ Indeed, western China was singled out for development of “wind bases” and “solar bases” in central government energy planning,Footnote ¹²⁰ due to “extremely favourable” conditions.Footnote ¹²¹ Provincial governments in western China, keen to attract investment, produced maps of wind capacity factor and solar radiation highlighting their province's vast resources. Yet, while this discourse was couched in the context of national low-carbon transition, government and industry proponents also made a point to link wind and solar expansion to GWDS goals of poverty alleviation and ecological protection. Wind and solar were emphasized as key industries in the 12th (2011–2015)Footnote ¹²² and 13th (2016–2020)Footnote ¹²³ Western Development Five-Year Plans, alongside continued state investment in solar-based rural electrification.Footnote ¹²⁴ In this way, wind and solar symbolized a new phase in the GWDS that would pull the region closer to eastern China and boost its economy through electricity transfers.

The actual infrastructure of wind and solar farms – turbines, PV panels and modules, and generators – enabled firms to enclose low-carbon value. This process occurred extremely rapidly with little coordination between projects, as industry and local governments sought to capitalize on subsidies. In the wind industry in the 2000s, local governments offered tax incentives, rebates on land purchases and a streamlined approvals process to attract investment in wind farms of under 50 MW of capacity – the upper limit of what the province could approve. NDRC lists of wind projects in western China in that period showed that nearly all had a nameplate installed capacity of between 49 and 50 MWFootnote ¹²⁵ – many of them situated right next to each other as part of the same farm. The shift to central approvals for wind projects in 2011 (and then back to the province level in 2013) did little to cool off investment due to highly attractive FiT rates, as established SOEs and private companies flocked to western China to build infrastructure. The solar industry, too, experienced a construction blitz, but one that was largely led by private enterprises drawn to western China by subsidies and the 2011 FiT. Like in the SHP industry, investment capital came from PV manufacturers and developers situated in eastern China, while utility-scale solar was primarily located in western China. New companies entered the sector seemingly every day to supply components for western China's solar farms, while local officials signed 20-year leases for hundreds of square kilometres of solar development.

Like with hydropower, the vast majority of wind and solar energy in western China was exported to consumers in eastern China. Indeed, the western provinces had less need for additional electricity and could only consume a fraction of overall generation.Footnote ¹²⁶ Some local officials followed the example of SHP and sought to attract energy-intensive industries to the region, though with varying levels of success due to their inability to set a sale price for electricity. Moreover, though local governments received an influx of revenues from land lease agreements, tax benefits from electricity sales were limited by policies discounting or exempting firms from initial income tax and VAT.Footnote ¹²⁷ In the wind industry in particular, local governments lacked tax jurisdiction over SOE developers registered at the central level or in other provinces, causing tax collection uncertainty.Footnote ¹²⁸ Local officials in wind and solar districts became increasingly dependent upon attracting new installations oriented towards long-distance transmission in order to meet their fiscal and economic growth targets.

This expansion of solar and wind in western China generated an electricity surplus that was not being fully exported to eastern China, forcing installations to curtail production beginning in the late 2000s.Footnote ¹²⁹ Scholars have identified several factors that contributed to this curtailment.Footnote ¹³⁰ One important factor was the over-building of solar and wind installations in western China, and an under-provision of high-voltage transmission infrastructure. Indeed, reports also identified hundreds of MW of new installed capacity that had no grid connection and was effectively “abandoned.”Footnote ¹³¹ More important, however, were institutional and regulatory barriers to renewable power purchasing and cross-provincial transmission. The grid companies, for example, did not compensate solar and wind producers for curtailed energy (despite a requirement for them to do so), and were also contracted with thermal plants in eastern China to uphold minimum operating hours.Footnote ¹³² The lack of effective inter-provincial market-based pricing also made it difficult for producing and receiving provinces to agree on sale terms.Footnote ¹³³ After a pause in 2013–2014, curtailment continued to increase, with curtailment of wind reaching 47 per cent in Gansu and 45 per cent in Inner Mongolia by 2015, and curtailment of solar surpassing 30 per cent in both Gansu and Xinjiang in the same year.Footnote ¹³⁴ Despite central government regulatory counter-measures,Footnote ¹³⁵ by 2017 curtailment was so severe in western China that the NDRC began repeatedly halting construction in Gansu and Xinjiang, and extended restrictions to the Tibet Autonomous Region in 2019.Footnote ¹³⁶

In the late 2010s, the NDRC decided to take the step to vastly reduce the FiT for wind and solar. The new wind FiT was announced in mid-2016 and took effect on 1 January 2017, with developers in western China rushing to finish projects before the cut-off.Footnote ¹³⁷ The new solar FiT, in contrast, took effect without warning on 31 May 2018 – a date so consequential for the industry that it was dubbed “5-3-1” (wu san yi 五三一) for short. Utility-scale solar projects in western China that had been highly profitable were suddenly much less economic for all but the largest firms; as a result, demand for panels and components began to rapidly dry up, and smaller companies exited the industry or went bankrupt.Footnote ¹³⁸ Curtailment rates for wind and solar improved in 2018 and 2019, but operators complained of thin margins and profit losses from western China installations that faced a backlog in subsidies. In a move paralleling the SHP industry, SOEs used their preferential access to loans to purchase wind and solar infrastructure from private firms.Footnote ¹³⁹ By 2020, utility-scale construction had fully resumed in western China, with local governments encouraged to develop their own policy instruments to support investment.Footnote ¹⁴⁰ A continued fall in curtailment rates and the price of components has made wind and solar investment attractive once again,Footnote ¹⁴¹ though without government subsidies of the previous decade. Whether local governments will be able to reap more sustained rewards from future growth in installations remains to be seen.