| Drop impact onto a dry surface: Role of the dynamic contact angle IV Roisman, L Opfer, C Tropea, M Raessi, J Mostaghimi, S Chandra Colloids and Surfaces A: Physicochemical and Engineering Aspects 322 (1-3 …, 2008 | 219 | 2008 |
| A computational framework for the analysis of rain-induced erosion in wind turbine blades, part I: Stochastic rain texture model and drop impact simulations B Amirzadeh, A Louhghalam, M Raessi, M Tootkaboni Journal of Wind Engineering and Industrial Aerodynamics 163, 33-43, 2017 | 141 | 2017 |
| Consistent mass and momentum transport for simulating incompressible interfacial flows with large density ratios using the level set method M Raessi, H Pitsch Computers & Fluids 63, 70-81, 2012 | 128 | 2012 |
| A computational framework for the analysis of rain-induced erosion in wind turbine blades, part II: Drop impact-induced stresses and blade coating fatigue life B Amirzadeh, A Louhghalam, M Raessi, M Tootkaboni Journal of Wind Engineering and Industrial Aerodynamics 163, 44-54, 2017 | 78 | 2017 |
| Producing molten metal droplets smaller than the nozzle diameter using a pneumatic drop-on-demand generator A Amirzadeh, M Raessi, S Chandra Experimental thermal and fluid science 47, 26-33, 2013 | 67 | 2013 |
| Advecting normal vectors: A new method for calculating interface normals and curvatures when modeling two-phase flows M Raessi, J Mostaghimi, M Bussmann Journal of Computational Physics 226 (1), 774-797, 2007 | 63 | 2007 |
| A 3D, fully Eulerian, VOF-based solver to study the interaction between two fluids and moving rigid bodies using the fictitious domain method A Pathak, M Raessi Journal of computational physics 311, 87-113, 2016 | 62 | 2016 |
| Computational simulation of the interactions between moving rigid bodies and incompressible two-fluid flows A Ghasemi, A Pathak, M Raessi Computers & Fluids 94, 1-13, 2014 | 59 | 2014 |
| A volume-of-fluid interfacial flow solver with advected normals M Raessi, J Mostaghimi, M Bussmann Computers & Fluids 39 (8), 1401-1410, 2010 | 58 | 2010 |
| A three-dimensional volume-of-fluid method for reconstructing and advecting three-material interfaces forming contact lines A Pathak, M Raessi Journal of Computational Physics 307, 550-573, 2016 | 56 | 2016 |
| A semi‐implicit finite volume implementation of the CSF method for treating surface tension in interfacial flows M Raessi, M Bussmann, J Mostaghimi International journal for numerical methods in fluids 59 (10), 1093-1110, 2009 | 54 | 2009 |
| Effect of surface roughness on splat shapes in the plasma spray coating process M Raessi, J Mostaghimi, M Bussmann Thin Solid Films 506, 133-135, 2006 | 53 | 2006 |
| Three-dimensional modelling of density variation due to phase change in complex free surface flows M Raessi, J Mostaghimi Numerical Heat Transfer, Part B: Fundamentals 47 (6), 507-531, 2005 | 48 | 2005 |
| Effect of substrate temperature on splashing of molten tin droplets NZ Mehdizadeh, M Raessi, S Chandra, J Mostaghimi Journal of heat transfer 126 (3), 445-452, 2004 | 45 | 2004 |
| Thermocapillary motion of deformable drops and bubbles M Herrmann, JM Lopez, P Brady, M Raessi Proceedings of the Summer program, 155, 2008 | 42 | 2008 |
| Study of solidification behavior and splat morphology of vacuum plasma sprayed Ti alloy by computational modeling and experimental results HR Salimijazi, M Raessi, J Mostaghimi, TW Coyle Surface and Coatings Technology 201 (18), 7924-7931, 2007 | 33 | 2007 |
| Toward predictive and computationally affordable Lagrangian–Eulerian modeling of spray–wall interaction R Torelli, R Scarcelli, S Som, X Zhu, SY Lee, J Naber, D Markt, M Raessi International Journal of Engine Research 21 (2), 263-280, 2020 | 31 | 2020 |
| Evaluation of diesel spray-wall interaction and morphology around impingement location L Zhao, R Torelli, X Zhu, J Naber, SY Lee, S Som, R Scarcelli, M Raessi SAE Technical Paper, 2018 | 30 | 2018 |
| Enhancing power extraction in bottom-hinged flap-type wave energy converters through advanced power take-off techniques K Senol, M Raessi Ocean Engineering 182, 248-258, 2019 | 26 | 2019 |
| The feasibility of Amazon's cloud computing platform for parallel, GPU-accelerated, multiphase-flow simulations C Freniere, A Pathak, M Raessi, G Khanna Computing in Science & Engineering 18 (5), 68-77, 2016 | 26 | 2016 |
