| The BLLAST field experiment: boundary-layer late afternoon and sunset turbulence M Lothon, F Lohou, D Pino, F Couvreux, ER Pardyjak, J Reuder, ... Atmospheric chemistry and physics 14 (20), 10931-10960, 2014 | 212 | 2014 |
| The Perdigão: peering into microscale details of mountain winds HJS Fernando, J Mann, J Palma, JK Lundquist, RJ Barthelmie, ... Bulletin of the American Meteorological Society 100 (5), 799-819, 2019 | 164* | 2019 |
| ALADINA–an unmanned research aircraft for observing vertical and horizontal distributions of ultrafine particles within the atmospheric boundary layer B Altstädter, A Platis, B Wehner, A Scholtz, N Wildmann, M Hermann, ... Atmospheric Measurement Techniques 8 (4), 1627-1639, 2015 | 120 | 2015 |
| MASC–a small Remotely Piloted Aircraft (RPA) for wind energy research N Wildmann, M Hofsäß, F Weimer, A Joos, J Bange Advances in Science and Research 11 (1), 55-61, 2014 | 103 | 2014 |
| An observational case study on the influence of atmospheric boundary-layer dynamics on new particle formation A Platis, B Altstädter, B Wehner, N Wildmann, A Lampert, M Hermann, ... Boundary-Layer Meteorology 158, 67-92, 2016 | 92 | 2016 |
| Towards higher accuracy and better frequency response with standard multi-hole probes in turbulence measurement with remotely piloted aircraft (RPA) N Wildmann, S Ravi, J Bange Atmospheric Measurement Techniques 7 (4), 1027-1041, 2014 | 81 | 2014 |
| Estimating CH4, CO2, and CO emissions from coal mining and industrial activities in the Upper Silesian Coal Basin using an aircraft-based mass balance approach A Fiehn, J Kostinek, M Eckl, T Klausner, M Gałkowski, J Chen, C Gerbig, ... Atmospheric Chemistry and Physics Discussions 2020, 1-33, 2020 | 69 | 2020 |
| SOUTHTRAC-GW: An airborne field campaign to explore gravity wave dynamics at the world’s strongest hotspot M Rapp, B Kaifler, A Dörnbrack, S Gisinger, T Mixa, R Reichert, N Kaifler, ... Bulletin of the American Meteorological Society 102 (4), E871-E893, 2021 | 63* | 2021 |
| Reviewing wind measurement approaches for fixed-wing unmanned aircraft A Rautenberg, MS Graf, N Wildmann, A Platis, J Bange Atmosphere 9 (11), 422, 2018 | 63 | 2018 |
| Quantifying emissions from hard coal mines using mobile sun-viewing Fourier transform spectrometry A Luther, R Kleinschek, L Scheidweiler, S Defratyka, M Stanisavljevic, ... Atmospheric Measurement Techniques 12 (10), 5217-5230, 2019 | 55 | 2019 |
| Two fast temperature sensors for probing of the atmospheric boundary layer using small remotely piloted aircraft (RPA) N Wildmann, M Mauz, J Bange Atmospheric Measurement Techniques 6 (8), 2101-2113, 2013 | 53 | 2013 |
| Wind turbine wake measurements with automatically adjusting scanning trajectories in a multi-Doppler lidar setup N Wildmann, N Vasiljevic, T Gerz Atmospheric Measurement Techniques 11 (6), 3801-3814, 2018 | 48 | 2018 |
| Observations of the early morning boundary-layer transition with small remotely-piloted aircraft N Wildmann, GA Rau, J Bange Boundary-Layer Meteorology 157, 345-373, 2015 | 47 | 2015 |
| Measuring the local wind field at an escarpment using small remotely-piloted aircraft N Wildmann, S Bernard, J Bange Renewable Energy 103, 613-619, 2017 | 39 | 2017 |
| Long-term simulation of the boundary layer flow over the double-ridge site during the Perdigão 2017 field campaign J Wagner, T Gerz, N Wildmann, K Gramitzky Atmospheric Chemistry and Physics 19 (2), 1129-1146, 2019 | 34 | 2019 |
| Distributed wind measurements with multiple quadrotor unmanned aerial vehicles in the atmospheric boundary layer T Wetz, N Wildmann, F Beyrich Atmospheric Measurement Techniques 14 (5), 3795-3814, 2021 | 33 | 2021 |
| Coplanar lidar measurement of a single wind energy converter wake in distinct atmospheric stability regimes at the Perdigão 2017 experiment N Wildmann, S Kigle, T Gerz Journal of Physics: Conference Series 1037 (5), 052006, 2018 | 33 | 2018 |
| An inverse-modelling approach for frequency response correction of capacitive humidity sensors in ABL research with small remotely piloted aircraft (RPA) N Wildmann, F Kaufmann, J Bange Atmospheric Measurement Techniques 7 (9), 3059-3069, 2014 | 32 | 2014 |
| Estimation of turbulence dissipation rate from Doppler wind lidars and in situ instrumentation for the Perdigão 2017 campaign N Wildmann, N Bodini, JK Lundquist, L Bariteau, J Wagner Atmospheric Measurement Techniques 12 (12), 6401-6423, 2019 | 30* | 2019 |
| Estimating Upper Silesian coal mine methane emissions from airborne in situ observations and dispersion modeling J Kostinek, A Roiger, M Eckl, A Fiehn, A Luther, N Wildmann, T Klausner, ... Atmospheric Chemistry and Physics 21 (11), 8791-8807, 2021 | 25 | 2021 |
Sridhar Ravi在 fas.harvard.edu 的电子邮件经过验证
Sridhar Ravi在 fas.harvard.edu 的电子邮件经过验证
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