Perdigão 2017

Conference

[1]	Stephan Kigle, Norman Wildmann, Martin Hagen, and Thomas Gerz. Characterizing a wind energy converter’s wake in distinct abl conditions by means of long-range lidar measurements in the context of the perdigão 2017 experiment. In 2017 AGU Fall Meeting, New Orleans, Louisiana, 2017-12-11/2017-12-15 2017. American Geophysical Union. [ bib \| http ]
[2]	Margarida Belo-Pereira, Jose Laginha Palma, Laura Sandra Leo, Joe Fernando, Norman Wildmann, Thomas Gerz, Carlos Veiga Rodrigues, Alexandre Silva Lopes, and Joao Correia Lopes. Design of a data catalogue for perdigão-2017 field experiment: Establishing the relevant parameters, post-processing techniques and users access. In 2017 AGU Fall Meeting, New Orleans, Louisiana, 2017-12-11/2017-12-15 2017. American Geophysical Union. [ bib \| http ]
[3]	Thomas Gerz, Johannes Wagner, and Antonia Englberger. Numerical simulation of low-level jets during the perdigão field campaign. In 2017 AGU Fall Meeting, New Orleans, Louisiana, 2017-12-11/2017-12-15 2017. American Geophysical Union. [ bib \| http ]
[4]	Norman Wildmann, Stephan Kigle, Thomas Gerz, Tyler Bell, and Petra Maria Klein. Measurement of the flow over two parallel mountain ridges in the nighttime stable boundary layer with scanning lidar systems at the perdigão 2017 experiment. In 2017 AGU Fall Meeting, New Orleans, Louisiana, 2017-12-11/2017-12-15 2017. American Geophysical Union. [ bib \| http ]
[5]	John J. Salvadore, Laura Sandra Leo, Margarida Belo-Pereira, Robert Menke, Sandra Gomes, Raghavendra Krishnamurthy, William O J Brown, Edward Creegan, Petra Maria Klein, Norman Wildmann, Steven Oncley, Joe Fernando, and Jakob Mann. Boundary layer characterization during perdigão field campaign 2017. In 2017 AGU Fall Meeting, New Orleans, Louisiana, 2017-12-11/2017-12-15 2017. American Geophysical Union. [ bib \| http ]
[6]	Rebecca J Barthelmie, Sara C Pryor, Norman Wildmann, and Robert Menke. An integrated analysis of wind turbine wakes at perdigao based on three doppler lidar datasets. In EGU General Assembly 2018, Vienna, Austria, 2018-04-08/2018-04-13 2018. European Geosciences Union. [ bib \| .pdf ]
[7]	Norman Wildmann, Nikola Vasiljevic, and Thomas Gerz. Multi-doppler lidar measurements of a wind turbine wake with adaptive scanning trajectories. In EGU General Assembly 2018, Vienna, Austria, 2018-04-08/2018-04-13 2018. European Geosciences Union. [ bib \| .pdf ]
[8]	Antonia Englberger and Andreas Dörnbrack. Wind-turbine wakes responding to diurnal cycle-driven boundary-layer flow over homogeneous and complex terrain: A numerical modelling study. In EGU General Assembly 2018, Vienna, Austria, 2018-04-08/2018-04-13 2018. European Geosciences Union. [ bib \| .pdf ]
[9]	Arthur Schady and Thomas Gerz. Detecting and monitoring sound from a wind turbine in complex terrain. In EGU General Assembly 2018, Vienna, Austria, 2018-04-08/2018-04-13 2018. European Geosciences Union. [ bib \| .pdf ]
[10]	Johannes Wagner, Thomas Gerz, Norman Wildmann, Robert Menke, and Jakob Mann. Numerical simulation of low-level jets during the perdigão field campaign 2017. In EGU General Assembly 2018, Vienna, Austria, 2018-04-08/2018-04-13 2018. European Geosciences Union. [ bib \| .pdf ]
[11]	Arthur Schady. Sound propagation from a wind turbine in complex terrain. In 17th International Symposium on Long Range Sound Propagation, Lyon, France, 2018-06-12/2018-06-13 2018. National Center for Physical Acoustics. [ bib \| .pdf ]
[12]	Tyler Bell, Petra Klein, Norman Wildmann, and Robert Menke. Analysis of flow in complex terrain using innovative multi-doppler lidar retrievals. In 23rd Symposium on Boundary Layers and Turbulence, Oklahoma City, OK, USA, 2018-06-11/2018-06-15 2018. AMS. [ bib \| http ]
[13]	Rebecca Barthelmie, Sara C. Pryor, Norman Wildmann, and Robert Menke. Wind turbine wake characterization in complex terrain via integrated doppler lidar datasets from the perdigão experiment. In The Science of Making Torque From Wind 2018, Milano, Italy, 2018-06-20/2018-06-22 2018. EAWE. [ bib \| http ]
[14]	Norman Wildmann, Stephan Kigle, and Thomas Gerz. Coplanar lidar measurements of a single wind energy converter wake in distinct atmospheric stability regimes at the perdigão 2017 experiment. In The Science of Making Torque From Wind 2018, Milano, Italy, 2018-06-20/2018-06-22 2018. EAWE. [ bib \| http ]
[15]	Arthur Schady, Thomas Gerz, Martin Hagen, Johannes Wagner, and Norman Wildmann. Einfluss der meteorologie in komplexem gelände auf den nachlauf und die akustik einer windenergieanlage (wea. In METTOOLS X, Braunschweig, DE, 2018-09-25/2018-09-27 2018. DMG. [ bib \| .pdf ]
[16]	Norman Wildmann. Kombinierte messungen mit drei scannenden, gepulsten doppler-windlidaren in unterschiedlichen anwendungsbereichen der grenzschichtmeteorologie. In METTOOLS X, Braunschweig, DE, 2018-09-25/2018-09-27 2018. DMG. [ bib \| .pdf ]
[17]	Norman Wildmann, Nicola Bodini, Julie K. Lundquist, Christian Mallaun, and Anke Roiger. Turbulenzmessung mit scannenden, gepulsten doppler-windlidar im rahmen der kampagnen perdigão 2017 und comet 1.0. In DACH2019, Garmisch-Partenkirchen, DE, 2019-03-18/2019-03-22 2019. DMG/ÖMG/SGM. [ bib \| .pdf ]
[18]	Kira Gramitzky, Johannes Wagner, Norman Wildmann, and Thomas Gerz. Untersuchung von low-level jets während der perdigão 2017 messkampagne hinsichtlich der relevanz für windenergie. In DACH2019, Garmisch-Partenkirchen, DE, 2019-03-18/2019-03-22 2019. DMG/ÖMG/SGM. [ bib \| .pdf ]
[19]	Johannes Wagner, Thomas Gerz, Norman Wildmann, and Annekatrin Metz-Marconcini. Einfluss verbesserter landnutzungsdaten auf die simulation von grenzschichtströmungen. In DACH2019, Garmisch-Partenkirchen, DE, 2019-03-18/2019-03-22 2019. DMG/ÖMG/SGM. [ bib \| .pdf ]
[20]	Norman Wildmann, Thomas Gerz, and Julie K. Lundquist. Long-range doppler lidar measurements of wind turbine wakes and their interaction with turbulent atmospheric boundary-layer flow at perdigão 2017. In The Science of Making Torque From Wind 2020, Delft, NL, online, 2020-09-28/2020-10-02 2020. EAWE. [ bib ]

Poster

Kigle, AGU 2017	Gramitzky, DACH 2019	Wagner, DACH 2019
Wagner, AGU 2017	Wildmann, TORQUE 2020

Journal

Conference

Poster

Student thesis

[1]	H. J. S. Fernando, J. Mann, J. M. L. M. Palma, J. K. Lundquist, R. J. Barthelmie, M. Belo-Pereira, W. O. J. Brown, F. K. Chow, T. Gerz, C. M. Hocut, P. M. Klein, L. S. Leo, J. C. Matos, S. P. Oncley, S. C. Pryor, L. Bariteau, T. M. Bell, N. Bodini, M. B. Carney, M. S. Courtney, E. D. Creegan, R. Dimitrova, S. Gomes, M. Hagen, J. O. Hyde, S. Kigle, R. Krishnamurthy, J. C. Lopes, L. Mazzaro, J. M. T. Neher, R. Menke, P. Murphy, L. Oswald, S. Otarola-Bustos, A. K. Pattantyus, C. Veiga Rodrigues, A. Schady, N. Sirin, S. Spuler, E. Svensson, J. Tomaszewski, D. D. Turner, L. van Veen, N. Vasiljevic, D. Vassallo, S. Voss, N. Wildmann, and Y. Wang. The perdigão: Peering into microscale details of mountain winds. Bulletin of the American Meteorological Society, 100(5):799--819, 2019. [ bib \| DOI ]
[2]	N. Wildmann, N. Vasiljevic, and T. Gerz. Wind turbine wake measurements with automatically adjusting scanning trajectories in a multi-doppler lidar setup. Atmospheric Measurement Techniques, 11(6):3801--3814, 2018. [ bib \| DOI \| http ]
[3]	N. Wildmann, S. Kigle, and T. Gerz. Coplanar lidar measurement of a single wind energy converter wake in distinct atmospheric stability regimes at the perdigão 2017 experiment. Journal of Physics: Conference Series, 1037(5):052006, 2018. [ bib \| DOI ]
[4]	R.J. Barthelmie, S.C. Pryor, N. Wildmann, and R. Menke. Wind turbine wake characterization in complex terrain via integrated doppler lidar data from the perdigão experiment. Journal of Physics: Conference Series, 1037(5):052022, 2018. [ bib \| DOI ]
[5]	J. Wagner, T. Gerz, N. Wildmann, and K. Gramitzky. Long-term simulation of the boundary layer flow over the double-ridge site during the perdigão 2017 field campaign. Atmospheric Chemistry and Physics, 19(2):1129--1146, 2019. [ bib \| DOI \| http ]
[6]	T. M. Bell, P. Klein, N. Wildmann, and R. Menke. Analysis of flow in complex terrain using multi-doppler lidar retrievals. Atmospheric Measurement Techniques, 13(3):1357--1371, 2020. [ bib \| DOI \| http ]
[7]	N. Wildmann, N. Bodini, J. K. Lundquist, L. Bariteau, and J. Wagner. Estimation of turbulence dissipation rate from doppler wind lidars and in situ instrumentation for the perdigão 2017 campaign. Atmospheric Measurement Techniques, 12(12):6401--6423, 2019. [ bib \| DOI \| http ]
[8]	Norman Wildmann, Thomas Gerz, and Julie K. Lundquist. Long-range doppler lidar measurements of wind turbine wakes and their interaction with turbulent atmospheric boundary-layer flow at perdigao 2017. Journal of Physics: Conference Series, 1618:032034, sep 2020. [ bib \| DOI ]
[9]	Arthur Schady and Katharina Elsen. On the detectability of a wind turbines noise under different meteorological conditions. Proceedings of Meetings on Acoustics, 41(1):040002, 2020. [ bib \| DOI ]
[10]	Katharina Maria Elsen and Arthur Schady. Influence of meteorological conditions on sound propagation of a wind turbine in complex terrain. Proceedings of Meetings on Acoustics, 41(1):032001, 2020. [ bib \| DOI ]
[11]	J. Quimbayo-Duarte, J. Wagner, N. Wildmann, T. Gerz, and J. Schmidli. Evaluation of a forest parameterization to improve boundary layer flow simulations over complex terrain. a case study using wrf-les v4.0.1. Geoscientific Model Development, 15(13):5195-5209, 2022. [ bib \| DOI ]

[1]	Stephan Kigle. Wake identification and characterization of a full scale wind energy converter in complex terrain with scanning doppler wind lidar systems, 2017. [ bib \| .pdf ]
[2]	Andreas Rauchöcker. Bestimmung von temperaturprofilen mittels fernerkundung - vergleich zweier verfahren, 2018. [ bib \| .pdf ]
[3]	Kira Lilith Gramitzky. Low-Level Jets - Enstehungsmechanismen und Potential für die Windenergie, 2019. [ bib \| .pdf ]