A reversal in global terrestrial stilling and its implications for wind energy production

Zhenzhong Zeng; Alan D. Ziegler; Timothy Searchinger; Long Yang; Anping Chen; Kunlu Ju; Shilong Piao; Laurent Z.X. Li; Philippe Ciais; Deliang Chen; Junguo Liu; Cesar Azorin-Molina; Adrian Chappell; David Medvigy; Eric F. Wood

doi:10.1038/s41558-019-0622-6

A reversal in global terrestrial stilling and its implications for wind energy production

Zhenzhong Zeng
, Alan D. Ziegler
, Timothy Searchinger
, Long Yang
, Anping Chen
, Kunlu Ju
, Shilong Piao
, Laurent Z.X. Li
, Philippe Ciais
, Deliang Chen
, Junguo Liu
, Cesar Azorin-Molina
, Adrian Chappell
, David Medvigy
, Eric F. Wood

the Southern University of Science and Technology
Princeton University
National University of Singapore
Princeton University
Nanjing University
Colorado State University
Tsinghua University School of Economics and Management
Tsinghua University
CNRS
Gothenburg University
Montcada
Cardiff University
University of Notre Dame

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

Wind power, a rapidly growing alternative energy source, has been threatened by reductions in global average surface wind speed, which have been occurring over land since the 1980s, a phenomenon known as global terrestrial stilling. Here, we use wind data from in situ stations worldwide to show that the stilling reversed around 2010 and that global wind speeds over land have recovered. We illustrate that decadal-scale variations of near-surface wind are probably determined by internal decadal ocean–atmosphere oscillations, rather than by vegetation growth and/or urbanization as hypothesized previously. The strengthening has increased potential wind energy by 17 ± 2% for 2010 to 2017, boosting the US wind power capacity factor by ~2.5% and explains half the increase in the US wind capacity factor since 2010. In the longer term, the use of ocean–atmosphere oscillations to anticipate future wind speeds could allow optimization of turbines for expected speeds during their productive life spans.

langue originale	Anglais
Pages (de - à)	979-985
Nombre de pages	7
journal	Nature Climate Change
Volume	9
Numéro de publication	12
Les DOIs	https://doi.org/10.1038/s41558-019-0622-6
état	Publié - 1 déc. 2019

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title = "A reversal in global terrestrial stilling and its implications for wind energy production",

abstract = "Wind power, a rapidly growing alternative energy source, has been threatened by reductions in global average surface wind speed, which have been occurring over land since the 1980s, a phenomenon known as global terrestrial stilling. Here, we use wind data from in situ stations worldwide to show that the stilling reversed around 2010 and that global wind speeds over land have recovered. We illustrate that decadal-scale variations of near-surface wind are probably determined by internal decadal ocean–atmosphere oscillations, rather than by vegetation growth and/or urbanization as hypothesized previously. The strengthening has increased potential wind energy by 17 ± 2\% for 2010 to 2017, boosting the US wind power capacity factor by \textasciitilde{}2.5\% and explains half the increase in the US wind capacity factor since 2010. In the longer term, the use of ocean–atmosphere oscillations to anticipate future wind speeds could allow optimization of turbines for expected speeds during their productive life spans.",

author = "Zhenzhong Zeng and Ziegler, \{Alan D.\} and Timothy Searchinger and Long Yang and Anping Chen and Kunlu Ju and Shilong Piao and Li, \{Laurent Z.X.\} and Philippe Ciais and Deliang Chen and Junguo Liu and Cesar Azorin-Molina and Adrian Chappell and David Medvigy and Wood, \{Eric F.\}",

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T1 - A reversal in global terrestrial stilling and its implications for wind energy production

AU - Zeng, Zhenzhong

AU - Ziegler, Alan D.

AU - Searchinger, Timothy

AU - Yang, Long

AU - Chen, Anping

AU - Ju, Kunlu

AU - Piao, Shilong

AU - Li, Laurent Z.X.

AU - Ciais, Philippe

AU - Chen, Deliang

AU - Liu, Junguo

AU - Azorin-Molina, Cesar

AU - Chappell, Adrian

AU - Medvigy, David

AU - Wood, Eric F.

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Wind power, a rapidly growing alternative energy source, has been threatened by reductions in global average surface wind speed, which have been occurring over land since the 1980s, a phenomenon known as global terrestrial stilling. Here, we use wind data from in situ stations worldwide to show that the stilling reversed around 2010 and that global wind speeds over land have recovered. We illustrate that decadal-scale variations of near-surface wind are probably determined by internal decadal ocean–atmosphere oscillations, rather than by vegetation growth and/or urbanization as hypothesized previously. The strengthening has increased potential wind energy by 17 ± 2% for 2010 to 2017, boosting the US wind power capacity factor by ~2.5% and explains half the increase in the US wind capacity factor since 2010. In the longer term, the use of ocean–atmosphere oscillations to anticipate future wind speeds could allow optimization of turbines for expected speeds during their productive life spans.

AB - Wind power, a rapidly growing alternative energy source, has been threatened by reductions in global average surface wind speed, which have been occurring over land since the 1980s, a phenomenon known as global terrestrial stilling. Here, we use wind data from in situ stations worldwide to show that the stilling reversed around 2010 and that global wind speeds over land have recovered. We illustrate that decadal-scale variations of near-surface wind are probably determined by internal decadal ocean–atmosphere oscillations, rather than by vegetation growth and/or urbanization as hypothesized previously. The strengthening has increased potential wind energy by 17 ± 2% for 2010 to 2017, boosting the US wind power capacity factor by ~2.5% and explains half the increase in the US wind capacity factor since 2010. In the longer term, the use of ocean–atmosphere oscillations to anticipate future wind speeds could allow optimization of turbines for expected speeds during their productive life spans.

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JO - Nature Climate Change

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ER -

A reversal in global terrestrial stilling and its implications for wind energy production

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