Photovoltaics are growing faster than expected in the global energy system

© mpieske/Pixabay

At HZB, science teams explore solar cells of the next generation. The picture shows the Helmholtz Innovation lab HySPRINT at HZB.

At HZB, science teams explore solar cells of the next generation. The picture shows the Helmholtz Innovation lab HySPRINT at HZB. © P. Dera/HZB

Dramatic cost reductions and the rapid expansion of production capacities make photovoltaics one of the most attractive technologies for a global energy turnaround. Not only the electricity sector, but also transport, heating, industry and chemical processes will in future be supplied primarily by solar power, because it is already the cheapest form of electricity generation in large parts of the world. This is where opportunities and challenges lie - at the level of the energy system as well as for research and industry. Leading international photovoltaic researchers from the Global Alliance for Solar Energy Research Institutes describe the cornerstones of future developments in an article published in the journal "Science" on 31 May.

The Global Alliance for Solar Energy Research Institutes GA-SERI consists of the Fraunhofer Institute for Solar Energy Systems ISE, the National Institute of Advanced Industrial Science and Technology AIST (Japan) and the National Renewable Energy Laboratory NREL (USA). Since 2016, this international group of experts, expanded by researchers from other groups and countries, has regularly discussed the challenges for the use of photovoltaics to achieve global climate goals. 

HZB Solar Energy Expertise:

Prof. Dr. Rutger Schlatmann, expert for photovoltaics and director of PVcomB as well as division spokesman for renewable energy at the Helmholtz-Zentrum Berlin, also contributed to this expertise. He emphasizes not only the great potential of photovoltaics for climate protection, but also the enormous opportunities for the economy associated with it. The traditionally strong photovoltaic research at HZB has been expanded in recent years on solar fuels as well as novel materials for batteries and catalysts for more energy-efficient chemical processes and thus fits perfectly with the vision described in the Science Paper.

Selected Results:

In a nutshell, you will find selected results from the expert report here. The long version can be found on the website of the Fraunhofer Institute for Solar Energy Systems or directly at Science.

PV capacity is increasing faster than expected

  • By 2018, 500 gigawatts of PV capacity had been installed worldwide.
  • In 2030, experts expect 10 terawatts of installed PV capacity worldwide.
  • By 2050, experts expect 30 to 70 terawatts of installed PV capacity worldwide.

PV will become one of the cheapest technologies

The learning curve for photovoltaics shows from 1976 to 2018: costs are reduced by 23 % per doubling of installed capacity. Experts believe it is likely that this cost reduction will continue.

In Germany, the kWh of solar power, at 4-10 € cents, has long been below the end customer price (>25 € ct/kWh), but now also below the prices for large-scale industry.

Higher efficiencies are in sight

With silicon PV, which covers 95 % of the world market, the trend is towards low-cost solar cells with passivated contacts that enable higher efficiencies. Technological advances in the field of thin-film technologies have raised efficiency levels above the 20 % mark, while the figure for multiple solar cells based on silicon is already over 35 %.

Outlook on sustainablility, networks, storage and sector coupling

For production in the terawatt range, issues of material supply (especially for rare elements such as silver), sustainability and recycling will come more into focus. Networks and power electronics, storage, sector coupling and power to gas can be further developed to absorb a high proportion of solar power. The technologies are already available.

To the publication:

Science, 31 May 2019: »Terawatt-scale photovoltaics: Transform global energy – Improving costs and scale reflect looming opportunities«

DOI: 10.1126/science.aaw1845

Authors: Nancy M. Haegel, Harry Atwater Jr., Teresa Barnes, Christian Breyer, Anthony Burrell, Yet-Ming Chiang, Stefaan De Wolf, Bernhard Dimmler, David Feldman, Stefan Glunz, Jan Christoph Goldschmidt, David Hochschild, Ruben Inzunza, Izumi Kaizuka, Ben Kroposki, Sarah Kurtz, Sylvere Leu, Robert Margolis, Koji Matsubara, Axel Metz, Wyatt K. Metzger, Mahesh Morjaria, Shigeru Niki, Stefan Nowak, Ian Marius Peters, Simon Philipps, Thomas Reindl, Andre Richter, Doug Rose, Keiichiro Sakurai, Rutger Schlatmann, Masahiro Shikano, Wim Sinke, Ron Sinton, B.J. Stanbery, Marko Topic, William Tumas, Yuzuru Ueda, Jao van de Lagemaat, Pierre Verlinden, Matthias Vetter, Emily Warren, Mary Werner, Masafumi Yamaguchi, Andreas W. Bett

HZB/ISE

  • Copy link

You might also be interested in

  • Green Deal Ukraїna at the Ukraine Recovery Conference
    News
    09.07.2026
    Green Deal Ukraїna at the Ukraine Recovery Conference
    End of June, the Ukraine Recovery Conference (UCR2026) took place in Gdańsk, Poland. Unlike previous editions, URC2026 introduced a dedicated Energy Platform, jointly organised by the Ministry of Energy of Ukraine and the Ministry of Climate and Environment of Poland, which brought together energy-related discussions, announcements, and side events in one place, increasing the visibility and coordination of key energy topics. Green Deal Ukraїna, an initiative coordinated by HZB, organised three events on the sidelines of URC on research and energy topics as part of the conference.
  • Perovskites: the future of PV? - The smarter-E Podcast
    News
    07.07.2026
    Perovskites: the future of PV? - The smarter-E Podcast
    Perovskites: The Race for the Future of PV?
  • Magnetic imaging: Micro-flowers increase the local magnetic field
    Science Highlight
    06.07.2026
    Magnetic imaging: Micro-flowers increase the local magnetic field
    Materials with magnetic nanostructures have many potential applications such as in spintronics. To explore such materials, nanoscale magnetic-sensitive imaging techniques are very useful, but up to now only weak magnetic fields could be applied during the imaging process. Now an international collaboration led by Dr. Sergio Valencia, HZB, has developed an approach that overcomes this limitation. The team designed tiny magnetic flux concentrators (MFCs), into which the sample is placed. The geometry of the MFCs resembles a flower with a number of petals which focus the applied magnetic field into its center. This greatly expands the magnetic field range available during imaging, and so the range of magnetic systems that can be investigated. The micro-flowers, enhancing magnetic fields locally, can find application in different nanometric magnetic microscopy techniques.