London Politica

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China’s push for hydrogen energy: The power of ambition for green infrastructure

In March 2022, China announced its target to produce approximately 200,000 tonnes per year of green hydrogen and at least 50,000 hydrogen-fuelled vehicles by 2025 to supplement its target of reaching net-zero carbon emissions by 2060. This comes after a huge push for hydrogen use during the 2022 Winter Olympics in Beijing. With China being the world’s largest producer of hydrogen at 33 million tonnes annually—80% being grey or blue hydrogen, widespread usage of green hydrogen is anticipated for China’s energy infrastructure.

 

In understanding hydrogen, there are three main forms: grey, blue, and green. Grey hydrogen is generated using fossil fuels and other high carbon-emitting sources and blue hydrogen is produced using low carbon-emitting sources such as steam methane reformation with Carbon Capture, Usage and Storage (CCUS) or other fossil fuels with CCUS. On the other hand, green hydrogen is made through the electrolysis of renewable energy sources and emits no carbon emissions.

 

The success of China’s move towards green hydrogen will depend on whether it can geographically connect its renewable-rich regions in the western provinces to the high hydrogen demand areas on the coast in China’s eastern provinces, as well as efficiently and cost-effectively store hydrogen during periods of high production yet low demand for green hydrogen energy. For example, while energy supply of hydrogen produced from solar energy sources usually outweighs demand during the summer months, energy demand rises during winter months due to higher electricity needs—such as for heating—and lower solar energy generation on account of shorter days during the winter. For this reason, green hydrogen energy storage is crucial to meet mismatched demand and supply periods.

 

In terms of transportation, hydrogen can be transported in a variety of ways depending on the transportation distance. For shorter distances, retrofitted pipelines for high-pressure gases or natural gas blending are the best options. Currently, China has two pure hydrogen pipelines in place—although both are under 500 kilometres—and one hydrogen-natural gas blending pilot project. For longer distances, hydrogen could be shipped in the form of ammonia, gas tanks,  liquefied, or through retrofitted subsea transmission pipelines. However, converting hydrogen to ammonia or cryogenic liquid is still extremely expensive and nascent in terms of technology, especially as liquid hydrogen technology is only used in China’s aerospace and defence sectors. This also poses a problem for hydrogen storage in the form of liquid. 


Another option is underground storage within depleted oil and gas reservoirs, salt caverns, or aquifers. However, China’s natural storage options are limited; thus, there is large scale investment into developing underground gas storage across China. Hydrogen can also be stored through gaseous storage and tube trailer technologies; however, steel containers used in China for hydrogen storage have a lower pressure capacity than that used in Europe, North America, Japan, and South Korea. Hydrogen regulations must therefore be amended to improve China’s competitive hydrogen storage ability.

 

While challenges for transportation and storage persist, ambition for green hydrogen energy usage across China is growing. The country now has more than 250 hydrogen refuelling stations, making it the country with the highest number of hydrogen refuelling stations globally. Moreover, investments are being poured into green hydrogen infrastructure and technology solutions in China. There is no doubt that in due time, China will be a key player in the global hydrogen industry.