- Info
2021
Originalarbeiten in wissenschaftlichen Fachzeitschriften
- Behr HD, Jung C, Trentmann J, Schindler D, 2021: Using satellite data for assessing spatiotemporal variability and complementarity of solar resources – a case study from Germany. Meteorologische Zeitschrift, 30: 515-532.
- Everard KA, Katul GG, Lawrence GA, Christen A, Parlange MB, 2021: Sweeping effects modify Taylor’s frozen turbulence hypothesis for scalars in the roughness sublayer. Geophysical Research Letters. 48: e2021GL093746.
- Fenner D, Bechtel B, Demuzere M, Kittner J, Meier F, 2021: CrowdQC+ - A Quality-Control for Crowdsourced Air-Temperature Observations Enabling World-Wide Urban Climate Applications. Frontiers in Environmental Science, 9, 720747.
- Gangwisch M, Fröhlich D, Christen A, Matzarakis A, 2021: Geometrical Assessment of Sunlit and Shaded Area of Urban Trees Based on Aligned Orthographic Views. Atmosphere. 12 (8), 968.
- Grau L, Jung C, Schindler D, 2021: Sounding out the repowering potential of wind energy – a scenario-based assessment from Germany. Journal of Cleaner Production, 293: 126094.
- Gubler M, Christen A, Remund J, Brönnimann S. 2021: Evaluation and application of a low-cost measurement network to study intra-urban temperature differences during summer 2018 in Bern, Switzerland. Urban Climate, 37: 100817.
- Jackson TD, Sethi S, Dellwik E, Angelou N, Bunce A, van Emmerik T, Duperat M, Ruel J-C, Wellpott A, Van Bloem S, Achim A, Kane B, Ciruzzi DM, Loheide II SP, James K, Burcham D, Moore J, Schindler D, Kolbe S, Wiegmann K, Rudnicki M, Lieffers VJ, Selker J, Gougherty AV, Newson T, Koeser A, Miesbauer J, Samelson R, Wagner J, Coomes D, Gardiner B, 2021: The motion of trees in the wind: a data synthesis. Biogeosciences, 18: 4049-4072.
- Jin L, Schubert S, Fenner D, Meier F, Schneider C, 2021: Integration of a building energy model in an urban climate model and its application. Boundary-Layer Meteorology, 178, 249-281.
- Jung C, Schindler D, 2021: Does the winter storm-related wind gust intensity in Germany increase under warming climate? – A high-resolution assessment. Weather and Climate Extremes, 33: 100360.
- Jung C, Schindler D, 2021: Distance to power grids and consideration criteria reduce global wind energy potential the most. Journal of Cleaner Production, 317: 128472.
- Jung C, Schindler D, 2021: A global wind farm potential index to increase energy yields and accessibility. Energy, 231: 120923.
- Jung C, Schindler D, 2021: The role of the power law exponent in wind energy assessment – A global analysis. International Journal of Energy Research, 1-13.
- Jung C, Schindler D, 2021: Modeling wind turbine-related greenhouse gas payback times in Europe at high spatial resolution. Energy Conversion and Management, 243: 114334.
- Kolbe S, Schindler D, 2021: TreeMMoSys: A low cost sensor network to measure wind-induced tree response. HardwareX, 9: e00180.
- Lee H, Mayer H, 2021: Solar elevation impact on the heat stress mitigation of pedestrians on tree-lined sidewalks of E-W street canyons – Analysis under Central European heat wave conditions. Urban Forestry & Urban Greening 58: 126905.
- Lee S-C, Christen A, Black TA, Jassal RS, Briegel F, Nesic Z, 2021: Combining flux variance similarity partitioning with artificial neural networks to gap-fill measurements of net ecosystem production of a Pacific Northwest Douglas-fir stand. Agricultural and Forest Meteorology, 303: 108382.
- Matzarakis A., 2021: Comments about Urban Bioclimate Aspects for Consideration in Urban Climate and Planning Issues in the Era of Climate Change, Atmosphere, 12: 546.
- Rustler P, Schindler D, Voll RE, Kollert F, 2021: Acute sarcoidosis clusters in cold season and is associated with ambient air pollution: a retrospective clinical-meteorological study. Annals of the American Thoracic Society, 18: 1415-1417.
- Sander L, Jung C, Schindler D, 2021: Greenhouse gas savings potential under repowering of onshore wind turbines and climate change: a case study from Germany. Wind, 1: 1-19.
- Schindler D, Schmidt-Rohr S, Jung C, 2021: On the spatiotemporal complementarity of the European onshore wind resource. Energy Conversion and Management, 237: 114098.
- Unnewehr JF, Jalbout E, Jung C, Schindler D, Weidlich A, 2021: Getting more with less? Why repowering onshore wind farms does not always lead to more wind power generation - A German case study. Renewable Energy, 180: 245-257.
- Varentsov M, Fenner D, Meier F, Samsonov T, Demuzere M, 2021: Quantifying Local and Mesoscale Drivers of the Urban Heat Island of Moscow with Reference and Crowdsourced Observations. Frontiers in Environmental Science, 9, 716968.
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