Concentrated solar power (CSP) technologies produce electricity by concentrating the sun’s rays to heat a medium (usually a liquid or gas) that is then used in a heat engine process (steam or gas turbine) to drive an electricity generator. >>

Bioenergy is produced by means of several chains of technologies from the production of biomass in a sustainable manner – meaning cultivation, harvesting, transportation, storage and eventually pre-treatment – to its use in a conversion process to produce the final form of energy requested: electricity, heat, CHP or biofuel for transport. >>

Biofuels are transportation fuels derived from agriculture, forestry or other organic feedstocks. Bio-ethanol and biodiesel are the most common biofuels used in transport, although other biofuels are also in use, such as pure vegetable oil and biogas. >>

Carbon Capture and Storage (CCS) technologies can be applied to energy production wherever carbon dioxide is produced in large quantities. This includes, but is not limited to, power generation and promises near zero emission electricity from fossil fuels. >>

Fuel cells convert the chemical energy stored in fuels into electricity and heat. They can be fed by fuels that are readily available as well as by waste-streams from industrial processes, thus reducing reliance on foreign oil and on an electricity grid that is ageing and increasingly pushed beyond capacity. >>

The most important use of cement is in the production of concrete. It acts as the binder that ‘glues’ the other key ingredients of concrete – sand and gravel. Cement typically makes up about 12% of the concrete mix. >>

Hydrogen and fuel-cells seem to attract the largest R&D investments among the non-nuclear energy technologies considered in this report: around €616 million are dedicated to this technology. This elevated investment may be explained by the fact that, unlike for most other technologies assessed, the category ‘hydrogen and fuel cells’ comprises an entire fuel chain from production to consumption with a broad range of transportation, stationary and portable applications, thus attracting a large number of different private and public actors. >>

Research investments into CCS amounted to €296 million in 2007. Both public and corporate R&D investments largely concentrate on relatively few Member States and companies with headquarters in these countries, namely Germany, France, and the UK (as well as Sweden and Denmark with regard to corporate investments). Together with biofuels, CCS-related research showed the by far lowest amount of public funding with a share of 19%. >>

Transport biofuels have become a priority in the EU policy over the past years with a rapidly growing market. This is reflected by an important research budget of €347 million in 2007. This figure is not restricted to research into 2nd generation biofuel production pathways that are a priority within the SET-Plan, but comprises all transport biofuel technologies. >>

CSP-related research spending (approx. €86 million) was relatively limited in 2007 compared with other SET-Plan priority technologies, reflecting the fact that interest in this field has started growing again only relatively recently. The potential locations of CSP plants are focused in the countries around the Mediterranean and as such, it is not surprising that public R&D support is dominated by Italy and Spain, accounting for more than three quarters of the aggregated EU Member States funds. >>

The aggregated research investments in photovoltaic technologies (PV) are estimated to have been €384 million in 2007. The data indicate that public funds account for a substantial share (42%), and even so may not yet fully reflect all PV-related spending in large national institutes which partially is not included in the data collected in the IEA RD&D statistics (see section 2.3.2). Compared to the year 2006 public national funds increased by almost 15%. >>

Europe is leading in wind energy, holding a 61% share of the globally installed wind energy capacity in 2007 and accounting for 7 of the top 10 wind suppliers in 2006 (EUROBSERV’ER, 2008a). Given the high global investments in this technology (around US$50 billion in 2007; Boyle et al., 2008) and Europe’s strong position in this market, it is not surprising that research investments in the EU reached €383 million in 2007. >>

What is SETIS? What does SETIS do? Download the SETIS 8-page informational brochure on the Strategic energy technologies information system, SETIS. >>

Cos’è SETIS? Che attività svolge SETIS? >>

Wat is SETIS? Wat doet SETIS? >>

The Materials Roadmap aims at contributing to strategic decisions on materials research funding at European and Member State levels and is aligned with the priorities of the SET-Plan. It is meant to serve as a guide for developing specific research and development activities in the field of materials for energy applications over the next 10 years. >>

The Institute for Energy and Transport of the Joint Research Centre (JRC) of the European Commission has conducted a study to assess whether there could be any potential bottlenecks to the deployment of low-carbon energy technologies in the EU due to the shortage of certain metals. The study examined the use of metals in the six low-carbon energy technologies of SET-Plan, namely: nuclear, solar, wind, bioenergy, carbon capture and storage and the electricity grid. >>

Presentation outlines EU activities on storage development, large-scale applications in support of RES, and market and regulatory drivers and barriers. >>