V. Vinichenko, J. Jewell, J. Jacobsson, A. Cherp. (2023). Historical diffusion of nuclear, wind and solar power in different national contexts: implications for climate mitigation pathways. Environmental Research Letters 18, 094066. Open Access. DOI: https://doi.org/10.1088/1748-9326/acf47a

Climate change mitigation requires rapid expansion of low-carbon electricity but there is a disagreement on whether available technologies such as renewables and nuclear power can be scaled up sufficiently fast. Here we analyze the diffusion of nuclear (from the 1960s), as well as wind and solar (from the 1980–90s) power. We show that all these technologies have been adopted in most large economies except major energy exporters, but solar and wind have diffused across countries faster and wider than nuclear. After the initial adoption, the maximum annual growth for nuclear power has been 2.6% of national electricity supply (IQR 1.3%–6%), for wind − 1.1% (0.6%–1.7%), and for solar − 0.8% (0.5%–1.3%). The fastest growth of nuclear power occurred in Western Europe in the 1980s, a response by industrialized democracies to the energy supply crises of the 1970s. The European Union (EU), currently experiencing a similar energy supply shock, is planning to expand wind and solar at similarly fast rates. This illustrates that national contexts can impact the speed of technology diffusion at least as much as technology characteristics like cost, granularity, and complexity. In the Intergovernmental Panel on Climate Change mitigation pathways, renewables grow much faster than nuclear due to their lower projected costs, though empirical evidence does not show that the cost is the sole factor determining the speed of diffusion. We demonstrate that expanding low-carbon electricity in Asia in line with the 1.5 °C target requires growth of nuclear power even if renewables increase as fast as in the most ambitious EU's plans. 2 °C-consistent pathways in Asia are compatible with replicating China's nuclear power plans in the whole region, while simultaneously expanding renewables as fast as in the near-term projections for the EU. Our analysis demonstrates the usefulness of empirically-benchmarked feasibility spaces for future technology projections.

M. Hyun, A. Cherp, J. Jewell, Y. J. Kim & J. Eom. (2023). Feasibility trade-offs in decarbonisation of power sector with high coal dependence: A case of Korea. Renewable and Sustainable Energy Transition, 3, 100050. Open Access. DOI: https://doi.org/10.1016/j.rset.2023.100050

Decarbonising the power sector requires feasible strategies for the rapid phase-out of fossil fuels and the expansion of low-carbon sources. This study assesses the feasibility of plausible decarbonisation scenarios for the power sector in the Republic of Korea through 2050 and 2060. Our power plant stock accounting model results show that achieving zero emissions from the power sector by the mid-century requires either an ambitious expansion of renewables backed by gas-fired generation equipped with carbon capture and storage or a significant increase of nuclear power. The first strategy implies replicating and maintaining for decades the maximum growth rates of solar power achieved in leading countries and becoming an early and ambitious adopter of the carbon capture and storage technology. The alternative expansion of nuclear power has historical precedents in Korea and other countries but may not be acceptable in the current political and regulatory environment. Hence, our analysis shows that the potential hurdles for decarbonisation in the power sector in Korea are formidable but manageable and should be overcome over the coming years, which gives hope to other similar countries.

H. Brauers, I. Braunger & J. Jewell. (2021). Liquefied natural gas expansion plans in Germany: The risk of gas lock-in under energy transitions. Energy Research & Social Science, 76, 102059. Open Access. DOI: https://doi.org/10.1016/j.erss.2021.102059

The German energy transition has been hailed as a role model for climate action. However, plans for the con­struction of three large-scale Liquefied Natural Gas (LNG) import terminals are receiving strong state support. This is inconsistent with Germany’s climate targets, which require a reduction rather than expansion of natural gas consumption. In our paper, we aim to unpack the connection between the risk of natural gas lock-in and the energy transition. We analyse the co-evolution of the techno-economic, socio-technical and political realms of the German natural gas sector and influence of actors within that process. We use a combination of energy system and interview data, and introduce a new approach to triangulate material and actor analysis. We show that four natural gas lock-in mechanisms cause the support for LNG in Germany: (A) the geopolitical influence from the United States, combined with (B) security of supply concerns due to the planned coal and nuclear phase-out, (C) pressure from a wide variety of state and private sector actors, and (D) sunk investments in existing gas infra­ structure. Two additional mechanisms supporting the strong position of natural gas are (E) the strength of the emerging synthetic gas niche, and (F) weak opposition against LNG and natural gas. We highlight the severely overlooked lock-in potential and related emissions, which could complicate and decelerate energy transitions as more countries reach a more advanced phase of the energy transition.

S. Pai, H. Zerriffi, J. Jewell & J. Pathak. (2020). Solar has greater techno-economic resource suitability than wind for replacing coal mining jobs. Environmental Research Letters. 15 (3), 034065. Open Access. DOI: https://doi.org/10.1088/1748-9326/ab6c6d.

Coal mining directly employs over 7 million workers and benefits millions more through indirect jobs. However, to meet the 1.5 °C global climate target, coal's share in global energy supply should decline between 73% and 97% by 2050. But what will happen to coal miners as coal jobs disappear ?Answering this question is necessary to ensure a just transition and to ensure that politically powerful coal mining interests do not impede energy transitions. Some suggest that coal miners can transition to renewable jobs. However, prior research has not investigated the potential for renewable jobs to replace 'local' coal mining jobs. Historic analyses of coal industry declines show that coal miners do not migrate when they lose their jobs. By focusing on China, India, the US, and Australia, which represent 70% of global coal production, we investigate: (1) the local solar and wind capacity required in each coal mining area to enable all coal miners to transition to solar/wind jobs; (2) whether there are suitable solar and wind power resources in coal mining areas in order to install solar/wind plants and create those jobs; and (3) the scale of renewables deployment required to transition coal miners in areas suitable for solar/wind power. We find that with the exception of the US, several GWs of solar or wind capacity would be required in each coal mining area to transition all coal miners to solar/wind jobs. Moreover, while solar has more resource suitability than wind in coal mining areas, these resources are not available everywhere. In China, the country with the largest coal mining workforce, only 29% of coal mining areas are suitable for solar power. In all four countries, less than 7% of coal mining areas have suitable wind resources. Further, countries would have to scale-up their current solar capacity significantly to transition coal miners who work in areas suitable for solar development.

Cherp, A., Vinichenko, V., Jewell, J., Suzuki, M. & Antal, M. (2017). Comparing electricity transitions: a historical analysis of nuclear, wind and solar power in Germany and Japan. Energy Policy, 101, 612-628. Open Access. DOI: https://doi.org/10.1016/j.enpol.2016.10.044.

This paper contributes to understanding national variations in using low-carbon electricity sources by comparing the evolution of nuclear, wind and solar power in Germany and Japan. It develops and applies a framework for analyzing low-carbon electricity transitions based on interplay of techno-economic, political and socio-technical processes. We explain why in the 1970s–1980s, the energy paths of the two countries were remarkably similar, but since the 1990s Germany has become a leader in renewables while phasing out nuclear energy, whereas Japan has deployed less renewables while becoming a leader in nuclear power. We link these differences to the faster growth of electricity demand and energy insecurity in Japan, the easier diffusion of onshore wind power technology and the weakening of the nuclear power regime induced by stagnation and competition from coal and renewables in Germany. We show how these changes involve the interplay of five distinct mechanisms which may also play a role in other energy transitions.

G. C. Leung, A. Cherp, J. Jewell & Y.-M. Wei. (2014). Securitization of energy supply chains in China. Applied Energy, 123, 316-326. Gated. DOI: https://dx.doi.org/10.1016/j.apenergy.2013.12.016.

Three sources of energy security risks, namely sovereignty, robustness and resilience, affect China’s energy chains. Energy security issues in China both have shaped and at the same time were shaped by ideas and institutions. China remains rigid with equating ‘security’ with ‘national security’ and the notion of “national” is socially constructed. Powerful actors, such as Chinese NOCs, inclined to interpret the problem so that it fits their preferred solution. Securitization of any energy supply chains results from their historical roots, system properties and institutional agents.

J. Jewell. (2010). A nuclear-powered North Africa: just a desert mirage or is there something on the horizon? Energy Policy, 39 (8), 4445-4457. In Press, Corrected Proof. Gated. DOI: https://dx.doi.org/10.1016/j.enpol.2010.09.042.

All of the North African countries have plans to develop nuclear power. If successful, nuclear energy could supply up to 9-15% of all electricity consumption in the region by 2030. How realistic are these plans and under what conditions can they be implemented? This paper seeks to answer this question by analyzing the motivations and capacities for deploying nuclear energy in the five North African countries by examining both regional and national factors. These factors are compared to similar characteristics of the countries with existing nuclear power programs using a series of quantitative indicators. While all five countries have strong motivations to develop nuclear power, which result from the high growth rates in demand for electricity and energy security concerns, their financial and institutional capacities to deploy nuclear energy vary and are generally lower than in those countries which already operate nuclear power plants. Most likely, North Africa will need to rely on external assistance to implement its nuclear energy plans. The article identifies three scenarios of nuclear power development from the interplay between internal and external factors, particularly the success of renewable energy projects and the ability to attract international investment in nuclear power.