@inproceedings{LilliestamDuGilmanovaetal.2023, author = {Lilliestam, Johan and Du, Fengli and Gilmanova, Alina and Mehos, Mark and Wang, Zhifeng and Thonig, Richard}, title = {Scaling up CSP}, series = {AIP conference proceedings}, volume = {2815}, booktitle = {AIP conference proceedings}, number = {1}, publisher = {American Institute of Physics}, address = {Melville}, issn = {1551-7616}, doi = {10.1063/5.0148709}, pages = {10}, year = {2023}, abstract = {Concentrating solar power (CSP) is one of the few scalable technologies capable of delivering dispatchable renewable power. Therefore, many expect it to shoulder a significant share of system balancing in a renewable electricity future powered by cheap, intermittent PV and wind power: the IEA, for example, projects 73 GW CSP by 2030 and several hundred GW by 2050 in its Net-Zero by 2050 pathway. In this paper, we assess how fast CSP can be expected to scale up and how long time it would take to get new, high-efficiency CSP technologies to market, based on observed trends and historical patterns. We find that to meaningfully contribute to net-zero pathways the CSP sector needs to reach and exceed the maximum historical annual growth rate of 30\%/year last seen between 2010-2014 and maintain it for at least two decades. Any CSP deployment in the 2020s will rely mostly on mature existing technologies, namely parabolic trough and molten-salt towers, but likely with adapted business models such as hybrid CSP-PV stations, combining the advantages of higher-cost dispatchable and low-cost intermittent power. New third-generation CSP designs are unlikely to play a role in markets during the 2020s, as they are still at or before the pilot stage and, judging from past pilot-to-market cycles for CSP, they will likely not be ready for market deployment before 2030. CSP can contribute to low-cost zero-emission energy systems by 2050, but to make that happen, at the scale foreseen in current energy models, ambitious technology-specific policy support is necessary, as soon as possible and in several countries.}, language = {en} } @article{LilliestamOllierLabordenaMiretal.2020, author = {Lilliestam, Johan and Ollier, Lana and Labordena Mir, Merc{\`e} and Pfenninger, Stefan and Thonig, Richard}, title = {The near- to mid-term outlook for concentrating solar power}, series = {Energy sources. B, Economics, planning and policy}, volume = {16}, journal = {Energy sources. B, Economics, planning and policy}, number = {1}, publisher = {Taylor \& Francis}, address = {London [u.a.]}, issn = {1556-7249}, doi = {10.1080/15567249.2020.1773580}, pages = {23 -- 41}, year = {2020}, abstract = {The history of concentrating solar power (CSP) is characterized by a boom-bust pattern caused by policy support changes. Following the 2014-2016 bust phase, the combination of Chinese support and several low-cost projects triggered a new boom phase. We investigate the near- to mid-term cost, industry, market and policy outlook for the global CSP sector and show that CSP costs have decreased strongly and approach cost-competitiveness with new conventional generation. Industry has been strengthened through the entry of numerous new companies. However, the project pipeline is thin: no project broke ground in 2019 and only four projects are under construction in 2020. The only remaining large support scheme, in China, has been canceled. Without additional support soon creating a new market, the value chain may collapse and recent cost and technological advances may be undone. If policy support is renewed, however, the global CSP sector is prepared for a bright future.}, language = {en} } @article{ReschSchoenigerKleinschmittetal.2022, author = {Resch, Gustav and Sch{\"o}niger, Franziska and Kleinschmitt, Christoph and Franke, Katja and Thonig, Richard and Lilliestam, Johan}, title = {Deep decarbonization of the European power sector calls for dispatchable CSP}, series = {AIP conference proceedings}, journal = {AIP conference proceedings}, publisher = {American Institute of Physics}, address = {Melville}, issn = {1551-7616}, doi = {10.1063/5.0086710}, pages = {050006-1 -- 050006-9}, year = {2022}, abstract = {Concentrating Solar Power (CSP) offers flexible and decarbonized power generation and is one of the few dispatchable renewable technologies able to generate renewable electricity on demand. Today (2018) CSP contributes only 5TWh to the European power generation, but it has the potential to become one of the key pillars for European decarbonization pathways. In this paper we investigate how factors and pivotal policy decisions leading to different futures and associated CSP deployment in Europe in the years up to 2050. In a second step we characterize the scenarios with their associated system cost and the costs of support policies. We show that the role of CSP in Europe critically depends on political developments and the success or failure of policies outside renewable power. In particular, the uptake of CSP depends on the overall decarbonization ambition, the degree of cross border trade of renewable electricity and is enabled by the presence of strong grid interconnection between Southern and Norther European Member States as well as by future electricity demand growth. The presence of other baseload technologies, prominently nuclear power in France, reduce the role and need for CSP. Assuming favorable technological development, we find a strong role for CSP in Europe in all modeled scenarios: contributing between 100TWh to 300TWh of electricity to a future European power system. This would require increasing the current European CSP fleet by a factor of 20 to 60 in the next 30 years. To achieve this financial support between € 0.4-2 billion per year into CSP would be needed, representing only a small share of overall support needs for power-system transformation. Cooperation of Member States could further help to reduce this cost.}, language = {en} } @incollection{SchoenigerReschKleinschmittetal.2022, author = {Sch{\"o}niger, Franziska and Resch, Gustav and Kleinschmitt, Christoph and Franke, Katja and Thonig, Richard and Lilliestam, Johan}, title = {The need for dispatchable RES}, series = {Renewable energy based solutions}, volume = {87}, booktitle = {Renewable energy based solutions}, editor = {Uyar, Tanay S{\i}dk{\i} and Javani, Nader}, publisher = {Springer International Publishing}, address = {Cham}, isbn = {978-3-031-05124-1}, doi = {10.1007/978-3-031-05125-8_8}, pages = {219 -- 239}, year = {2022}, abstract = {Concentrating Solar Power (CSP) offers flexible and decarbonised power generation and is one of the few switchable renewable technologies that can generate renewable power on demand. Today (2018), CSP only contributes 5 TWh to European electricity generation but has the potential to become an important generation asset for decarbonising the electricity sector within Europe as well as globally. This chapter examines how factors and key political decisions lead to different futures and the associated CSP use in Europe in the years up to 2050. In a second step, we characterise the scenarios with the associated system costs and the costs of the support policy. We show that the role of CSP in Europe depends crucially on political decisions and the success or failure of policies outside of renewable energies. In particular, the introduction of CSP depends on the general ambitions for decarbonisation, the level of cross-border trade in electricity from renewable sources and is made possible by the existence of a strong grid connection between the southern and northern European Member States and by future growth in electricity demand. The presence of other baseload technologies, particularly nuclear energy in France, diminishes the role and need for CSP. Assuming a favourable technological development, we find a strong role for CSP in Europe in all modelled scenarios: Contribution of 100 TWh to 300 TWh of electricity to a future European electricity system. The current European CSP fleet would have to be increased by a factor of 20 to 60 over the next 30 years. To achieve this, stable financial support for CSP would be required. Depending on framework conditions and assumptions, the amount of support ranges at the EU level from € 0.4 to 2 billion per year, which represents only a small proportion of the total support requirement for the energy system transformation. Cooperation between the Member States could further help reduce these costs.}, language = {en} } @article{SchoenigerThonigReschetal.2021, author = {Sch{\"o}niger, Franziska and Thonig, Richard and Resch, Gustav and Lilliestam, Johan}, title = {Making the sun shine at night}, series = {Energy sources. B, Economics, planning and policy}, volume = {16}, journal = {Energy sources. B, Economics, planning and policy}, number = {1}, publisher = {Taylor \& Francis Group}, address = {Philadelphia}, issn = {1556-7249}, doi = {10.1080/15567249.2020.1843565}, pages = {55 -- 74}, year = {2021}, abstract = {Sustainable electricity systems need renewable and dispatchable energy sources. Solar energy is an abundant source of renewable energy globally which is, though, by nature only available during the day, and especially in clear weather conditions. We compare three technology configurations able to provide dispatchable solar power at times without sunshine: Photovoltaics (PV) combined with battery (BESS) or thermal energy storage (TES) and concentrating solar power (CSP) with TES. Modeling different periods without sunshine, we find that PV+BESS is competitive for shorter storage durations while CSP+TES gains economic advantages for longer storage periods (also over PV+TES). The corresponding tipping points lie at 2-3 hours (current cost), and 4-10 hours if expectations on future cost developments are taken into consideration. PV+TES becomes only more competitive than CSP+TES with immense additional cost reductions of PV. Hence, there remain distinct niches for two technologies: PV+BESS for short storage durations and CSP+TES for longer ones.}, language = {en} } @misc{ThonigDelRioKieferetal.2020, author = {Thonig, Richard and Del Rio, Pablo and Kiefer, Christoph and Lazaro Touza, Lara and Escribano, Gonzalo and Lechon, Yolanda and Spaeth, Leonhard and Wolf, Ingo and Lilliestam, Johan}, title = {Does ideology influence the ambition level of climate and renewable energy policy?}, series = {Zweitver{\"o}ffentlichungen der Universit{\"a}t Potsdam : Wirtschafts- und Sozialwissenschaftliche Reihe}, journal = {Zweitver{\"o}ffentlichungen der Universit{\"a}t Potsdam : Wirtschafts- und Sozialwissenschaftliche Reihe}, number = {1}, issn = {1867-5808}, doi = {10.25932/publishup-57798}, url = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-577981}, pages = {19}, year = {2020}, abstract = {We investigate whether political ideology has an observable effect on decarbonization ambition, renewable power aims, and preferences for power system balancing technologies in four European countries. Based on the Energy Logics framework, we identify ideologically different transition strategies (state-centered, market-centered, grassroots-centered) contained in government policies and opposition party programs valid in 2019. We compare these policies and programs with citizen poll data. We find that ideology has a small effect: governments and political parties across the spectrum have similar, and relatively ambitious, decarbonization and renewables targets. This mirrors citizens' strong support for ambitious action regardless of their ideological self-description. However, whereas political positions on phasing out fossil fuel power are clear across the policy space, positions on phasing in new flexibility options to balance intermittent renewables are vague or non-existent. As parties and citizens agree on strong climate and renewable power aims, the policy ambition is likely to remain high, even if governments change.}, language = {en} } @article{ThonigDelRioKieferetal.2020, author = {Thonig, Richard and Del Rio, Pablo and Kiefer, Christoph and Lazaro Touza, Lara and Escribano, Gonzalo and Lechon, Yolanda and Spaeth, Leonhard and Wolf, Ingo and Lilliestam, Johan}, title = {Does ideology influence the ambition level of climate and renewable energy policy?}, series = {Energy sources, part B: economics, planning, and policy}, volume = {16}, journal = {Energy sources, part B: economics, planning, and policy}, number = {1}, publisher = {Taylor \& Francis Group}, address = {Philadelphia}, issn = {1556-7249}, doi = {10.1080/15567249.2020.1811806}, pages = {4 -- 22}, year = {2020}, abstract = {We investigate whether political ideology has an observable effect on decarbonization ambition, renewable power aims, and preferences for power system balancing technologies in four European countries. Based on the Energy Logics framework, we identify ideologically different transition strategies (state-centered, market-centered, grassroots-centered) contained in government policies and opposition party programs valid in 2019. We compare these policies and programs with citizen poll data. We find that ideology has a small effect: governments and political parties across the spectrum have similar, and relatively ambitious, decarbonization and renewables targets. This mirrors citizens' strong support for ambitious action regardless of their ideological self-description. However, whereas political positions on phasing out fossil fuel power are clear across the policy space, positions on phasing in new flexibility options to balance intermittent renewables are vague or non-existent. As parties and citizens agree on strong climate and renewable power aims, the policy ambition is likely to remain high, even if governments change.}, language = {en} } @article{ThonigGilmanovaZhanetal.2022, author = {Thonig, Richard and Gilmanova, Alina and Zhan, Jing and Lilliestam, Johan}, title = {Chinese CSP for the world?}, series = {AIP conference proceedings}, journal = {AIP conference proceedings}, publisher = {American Institute of Physics}, address = {Melville}, issn = {1551-7616}, doi = {10.1063/5.0085752}, pages = {1 -- 11}, year = {2022}, abstract = {For three consecutive five-year plans since 2006, China has worked on building up an internationally competitive CSP industry and value chain. One big milestone in commercializing proprietary Chinese CSP technology was the 2016 demonstration program of 20 commercial-scale projects. China sought to increase and demonstrate capacities for domestic CSP technology development and deployment. At the end of the 13th five-year period, we take stock of the demonstrated progress of the Chinese CSP industry towards delivering internationally competitive CSP projects. We find that in January 2021, eight commercial-scale projects, in total 500 MW, have been completed and three others were under construction in China. In addition, Chinese EPC's have participated in three international CSP projects, although proprietary Chinese CSP designs have not been applied outside China. The largest progress has been made in molten-salt tower technology, with several projects by different companies completed and operating successfully: here, the aims were met, and Chinese companies are now at the global forefront of this segment. Further efforts for large-scale demonstration are needed, however, for other CSP technologies, including parabolic trough - with additional demonstration hindered by a lack of further deployment policies. In the near future, Chinese companies seek to employ the demonstrated capabilities in the tower segment abroad and are developing projects using Chinese technology, financing, and components in several overseas markets. If successful, this will likely lead to increasing competition and further cost reductions for the global CSP sector.}, language = {en} } @article{ThonigLilliestam2023, author = {Thonig, Richard and Lilliestam, Johan}, title = {Concentrating solar technology policy should encourage high temperatures and modularity to enable spillovers}, series = {AIP conference proceedings}, journal = {AIP conference proceedings}, number = {1}, publisher = {American Institute of Physics}, address = {Melville}, issn = {1551-7616}, doi = {10.1063/5.0149423}, pages = {1 -- 11}, year = {2023}, abstract = {Thermal energy from concentrating solar thermal technologies (CST) may contribute to decarbonizing applications from heating and cooling, desalination, and power generation to commodities such as aluminium, hydrogen, ammonia or sustainable aviation fuels (SAF). So far, successful commercial-scale CST projects are restricted to solar industrial process heat (SIPH) and concentrating solar power (CSP) generation and, at least for the latter, depend on support from public policies that have been stagnating for years. As they are technologically similar, spillovers between SIPH or CSP and other emerging CST could accelerate commercialization across use cases while maximizing the impact of scarce support. Here, we review the technical potential for cross-fertilization between different CST applications and the ability of the current policy regime to enable this potential. Using working temperature as the key variable, we identify different clusters of current and emerging CST technologies. Low-temperature CST (<400℃) applications for heating, cooling and desalination already profit from the significant progress made in line-focussing CSP over the last 15 years. A newly emerging cluster of high temperature CST (>600℃) for solar chemistry and high-grade process heat has significant leverage for spillovers with point-focussing solar tower third-generation CSP currently under development. For these spillovers to happen, however, CSP policy designs would need to prioritize innovation for high working temperature and encourage modular plant design, by adequately remunerating hybridized plants with heat and power in and outputs that include energy sources beyond CST solar fields. This would enable synergies across applications and scales by incentivizing compatibility of modular CST components in multiple sectors and use cases.}, language = {en} }