Wind speed distribution selection–A review of recent development and progress C Jung, D Schindler Renewable and Sustainable Energy Reviews 114, 109290, 2019 | 137 | 2019 |
Global comparison of the goodness-of-fit of wind speed distributions C Jung, D Schindler Energy Conversion and Management 133, 216-234, 2017 | 113 | 2017 |
National and global wind resource assessment under six wind turbine installation scenarios C Jung, D Schindler, J Laible Energy conversion and management 156, 403-415, 2018 | 79 | 2018 |
The temporal variability of global wind energy–Long-term trends and inter-annual variability C Jung, D Taubert, D Schindler Energy Conversion and Management 188, 462-472, 2019 | 78 | 2019 |
Introducing a system of wind speed distributions for modeling properties of wind speed regimes around the world C Jung, D Schindler, J Laible, A Buchholz Energy Conversion and Management 144, 181-192, 2017 | 78 | 2017 |
On the spatiotemporal variability and potential of complementarity of wind and solar resources D Schindler, HD Behr, C Jung Energy Conversion and Management 218, 113016, 2020 | 76 | 2020 |
The role of air density in wind energy assessment–A case study from Germany C Jung, D Schindler Energy 171, 385-392, 2019 | 71 | 2019 |
The role of the power law exponent in wind energy assessment: A global analysis C Jung, D Schindler International Journal of Energy Research 45 (6), 8484-8496, 2021 | 60 | 2021 |
Changing wind speed distributions under future global climate C Jung, D Schindler Energy Conversion and Management 198, 111841, 2019 | 54 | 2019 |
On the influence of wind speed model resolution on the global technical wind energy potential C Jung, D Schindler Renewable and Sustainable Energy Reviews 156, 112001, 2022 | 47 | 2022 |
On the inter-annual variability of wind energy generation–A case study from Germany C Jung, D Schindler Applied Energy 230, 845-854, 2018 | 46 | 2018 |
Introducing a new approach for wind energy potential assessment under climate change at the wind turbine scale C Jung, D Schindler Energy Conversion and Management 225, 113425, 2020 | 44 | 2020 |
Achieving Germany’s wind energy expansion target with an improved wind turbine siting approach C Jung, D Schindler, L Grau Energy conversion and management 173, 383-398, 2018 | 43 | 2018 |
Development of onshore wind turbine fleet counteracts climate change-induced reduction in global capacity factor C Jung, D Schindler Nature Energy 7 (7), 608-619, 2022 | 42 | 2022 |
Development of a statistical bivariate wind speed-wind shear model (WSWS) to quantify the height-dependent wind resource C Jung, D Schindler Energy Conversion and Management 149, 303-317, 2017 | 40 | 2017 |
3D statistical mapping of Germany’s wind resource using WSWS C Jung, D Schindler Energy Conversion and Management 159, 96-108, 2018 | 38 | 2018 |
Using highly resolved maximum gust speed as predictor for forest storm damage caused by the high‐impact winter storm Lothar in Southwest Germany D Schindler, C Jung, A Buchholz Atmospheric Science Letters 17 (8), 462-469, 2016 | 36 | 2016 |
A review of recent studies on wind resource projections under climate change C Jung, D Schindler Renewable and Sustainable Energy Reviews 165, 112596, 2022 | 35 | 2022 |
Integration of small-scale surface properties in a new high resolution global wind speed model C Jung, D Schindler Energy Conversion and Management 210, 112733, 2020 | 34 | 2020 |
Sensitivity analysis of the system of wind speed distributions C Jung, D Schindler Energy Conversion and Management 177, 376-384, 2018 | 34 | 2018 |