| Literature DB >> 31601706 |
Paul Veers1, Katherine Dykes2, Eric Lantz1, Stephan Barth3, Carlo L Bottasso4, Ola Carlson5, Andrew Clifton6, Johney Green7, Peter Green7, Hannele Holttinen8, Daniel Laird7, Ville Lehtomäki9, Julie K Lundquist7,10, James Manwell11, Melinda Marquis12, Charles Meneveau13, Patrick Moriarty7, Xabier Munduate14, Michael Muskulus15, Jonathan Naughton16, Lucy Pao17, Joshua Paquette18, Joachim Peinke3,19, Amy Robertson7, Javier Sanz Rodrigo14, Anna Maria Sempreviva20, J Charles Smith21, Aidan Tuohy22, Ryan Wiser23.
Abstract
Harvested by advanced technical systems honed over decades of research and development, wind energy has become a mainstream energy resource. However, continued innovation is needed to realize the potential of wind to serve the global demand for clean energy. Here, we outline three interdependent, cross-disciplinary grand challenges underpinning this research endeavor. The first is the need for a deeper understanding of the physics of atmospheric flow in the critical zone of plant operation. The second involves science and engineering of the largest dynamic, rotating machines in the world. The third encompasses optimization and control of fleets of wind plants working synergistically within the electricity grid. Addressing these challenges could enable wind power to provide as much as half of our global electricity needs and perhaps beyond.Year: 2019 PMID: 31601706 DOI: 10.1126/science.aau2027
Source DB: PubMed Journal: Science ISSN: 0036-8075 Impact factor: 47.728