| Experimental study of the horizontally averaged flow structure in a model wind-turbine array boundary layer RB Cal, J Lebrón, L Castillo, HS Kang, C Meneveau Journal of renewable and sustainable energy 2 (1), 013106, 2010 | 344 | 2010 |
| Statistical analysis of kinetic energy entrainment in a model wind turbine array boundary layer N Hamilton, H Suk Kang, C Meneveau, RB Cal Journal of renewable and sustainable energy 4 (6), 063105, 2012 | 87 | 2012 |
| Experimental study on influence of pitch motion on the wake of a floating wind turbine model S Rockel, E Camp, J Schmidt, J Peinke, RB Cal, M Hölling Energies 7 (4), 1954-1985, 2014 | 73 | 2014 |
| Pathways for mitigating thermal losses in solar photovoltaics R Vaillon, O Dupré, RB Cal, M Calaf Scientific reports 8 (1), 13163, 2018 | 67 | 2018 |
| Inner and outer scalings in rough surface zero pressure gradient turbulent boundary layers B Brzek, RB Cal, G Johansson, L Castillo Physics of fluids 19 (6), 065101, 2007 | 57 | 2007 |
| Mean kinetic energy transport and event classification in a model wind turbine array versus an array of porous disks: Energy budget and octant analysis EH Camp, RB Cal Physical Review Fluids 1 (4), 044404, 2016 | 53 | 2016 |
| Wake to wake interaction of floating wind turbine models in free pitch motion: An eddy viscosity and mixing length approach S Rockel, J Peinke, M Hölling, RB Cal Renewable Energy 85, 666-676, 2016 | 50 | 2016 |
| Transitionally rough zero pressure gradient turbulent boundary layers BG Brzek, RB Cal, G Johansson, L Castillo Experiments in fluids 44, 115-124, 2008 | 46 | 2008 |
| Distribution of mean kinetic energy around an isolated wind turbine and a characteristic wind turbine of a very large wind farm G Cortina, M Calaf, RB Cal Physical Review Fluids 1 (7), 074402, 2016 | 41 | 2016 |
| Dynamic stall of an experimental wind turbine blade M Melius, RB Cal, K Mulleners Physics of Fluids 28 (3), 034103, 2016 | 39 | 2016 |
| Low-order representations of the canonical wind turbine array boundary layer via double proper orthogonal decomposition N Hamilton, M Tutkun, RB Cal Physics of Fluids 28 (2), 025103, 2016 | 39 | 2016 |
| Wind turbine boundary layer arrays for Cartesian and staggered configurations: Part II, low‐dimensional representations via the proper orthogonal decomposition N Hamilton, M Tutkun, RB Cal Wind Energy 18 (2), 297-315, 2015 | 38 | 2015 |
| Wind turbine boundary layer arrays for Cartesian and staggered configurations‐Part I, flow field and power measurements N Hamilton, M Melius, RB Cal Wind Energy 18 (2), 277-295, 2015 | 38 | 2015 |
| Anisotropy of the Reynolds stress tensor in the wakes of wind turbine arrays in Cartesian arrangements with counter-rotating rotors N Hamilton, RB Cal Physics of Fluids 27 (1), 015102, 2015 | 38 | 2015 |
| The rough favourable pressure gradient turbulent boundary layer RB Cal, B Brzek, TG Johansson, L Castillo Journal of fluid mechanics 641, 129-155, 2009 | 37 | 2009 |
| Effects of free-stream turbulence on rough surface turbulent boundary layers B Brzek, S Torres-Nieves, J Lebrón, R Cal, C Meneveau, L Castillo Journal of fluid mechanics 635, 207-243, 2009 | 36 | 2009 |
| Interaction between a wind turbine array and a turbulent boundary layer J Lebron, L Castillo, HS Kang, C Meneveau, R Cal 48th AIAA aerospace sciences meeting including the new horizons forum and …, 2010 | 35 | 2010 |
| Similarity analysis of favorable pressure gradient turbulent boundary layers with eventual quasilaminarization RB Cal, L Castillo Physics of Fluids 20 (10), 105106, 2008 | 32 | 2008 |
| Dynamic wake development of a floating wind turbine in free pitch motion subjected to turbulent inflow generated with an active grid S Rockel, J Peinke, M Hölling, RB Cal Renewable Energy 112, 1-16, 2017 | 30 | 2017 |
| A generalized framework for reduced‐order modeling of a wind turbine wake N Hamilton, B Viggiano, M Calaf, M Tutkun, RB Cal Wind Energy 21 (6), 373-390, 2018 | 27 | 2018 |
