Google Scholar Page
Peer-Reviewed Journal Papers
(1 indicates my students, 2 indicates my post-docs)
[73] Z. Zhang1, F. Sotiropoulos, A. Khosronejad, (2024), “A deep-learning approach for 3D realization of mean wake flow of marine hydrokinetic turbine arrays,” Energy Reports, 12, 2621-2630.
[72] C. Santoni2, D. Zhang, Z. Zhang1, D. Samaras, F. Sotiropoulos, A. Khosronejad, (2024), “Toward ultra-efficient high-fidelity predictions of wind turbine wakes: Augmenting the accuracy of engineering models via LES-trained machine learning,” Physics of Fluids, 36, 065159.
[71] M. M. Aksen1, K. Flora2, H. Seyedzadeh1, M.G. Anjiraki1, A. Khosronejad, (2024), “On the impact of debris accumulation on power production of marine hydrokinetic turbines: Insights gained via LES,” Theoretical and Applied Mechanics Letters, 100524, https://doi.org/10.1016/j.taml.2024.100524
[70] H. Seyedzadeh1, J. Craig1, A. Khosronejad, (2024), “On the efficacy of facial masks to suppress the spreading of pathogen-carrying saliva particles during human respiratory events: Insights gained via high-fidelity numerical modeling,” Medical Research Archives, 12 (5), https://doi.org/10.18103/mra.v12i5.5441.
[69] K. Flora2, A. Khosronejad, (2024), “Uncertainty quantification of bank vegetation impacts on the flood flow field in the American River, California, using large-eddy simulations,” Earth Surface Processes and Landforms, 49 (3), 967-979.
[68] Thomas Gold, Kevin Reiterer, Dominik Worf1, Norbert Kaiblinger, Ali Khosronejad, Helmut Habersack, Christine Sindelar, (2024), “Dynamics of heavy subaqueous spherical pendulums,” Journal of Fluid Mechanics, 978, A19.
[67] C. Santoni2, F. Sotiropoulos, A. Khosronejad, (2024), “A Comparative Analysis of Actuator-Based Turbine Structure Parametrizations for High-Fidelity Modeling of Utility-Scale Wind Turbines under Neutral Atmospheric Conditions,” Energies, 17 (3), 753.
[66] Z. Zhang1, F. Sotiropoulos, A. Khosronejad, (2024), “Predicting turbulent wake flow of marine hydrokinetic turbine arrays in large-scale waterways via physics-enhanced convolutional neural networks,” Physics of Fluids, 36, 045156.
[65] Santoni2, Z. Zhang1, F. Sotiropoulos, A. Khosronejad, (2023), “A data-driven machine learning approach for yaw control applications of wind farms,” Theoretical and Applied Mechanics Letters, 13 (5), 100471.
[64] H. Seyedzadeh1, W. Oaks2, J. Craig1, M. Aksen1, M. S. Sanz, A. Khosronejad, (2023), “Lagrangian dynamics of particle transport in oral and nasal breathing,” Physics of Fluids, 35 (8), 081903.
[63] S. K. Kang, J. Lee, Y. Kim, A. Khosronejad, (2023), “Experimental and numerical study on the flow characteristics around spur dikes at different length-to-depth ratios,” Advances in Water Resources, 175, 104428.
[62] Z. Zhang1, X. Hao, C. Santoni2, L. Shen, F. Sotiropoulos, A. Khosronejad, (2023), “Toward prediction of turbulent atmospheric flows over propagating oceanic waves via machine-learning augmented large-eddy simulation,” Ocean Engineering, 280, 114759.
[61] Gold, T., Reiterer, K., Worf 1, D., Khosronejad, A., Habersack, H., & Sindelar, C., (2023), “Lagrangian particle tracking velocimetry investigation of vortex shedding topology for oscillating heavy spherical pendulums underwater,” Journal of Fluid Mechanics, 960, A14. doi:10.1017/jfm.2023.170.
[60] Khosronejad, A., Limaye, A. B., Zhang1, Z., Kang, S., Yang, X., & Sotiropoulos, F., (2023), On the morphodynamics of a wide class of large-scale meandering rivers: Insights gained by coupling LES with sediment dynamics, Journal of Advances in Modeling Earth Systems, 15, e2022MS003257, https://doi.org/10.1029/2022MS003257
[59] Santoni2, C., Khosronejad, A., Yang, X., Seiler, P. Sotiropolous, F., (2023), “Coupling turbulent flow with blade aeroelastics and control modules in large-eddy simulation of utility-scale wind turbines,” Physics of Fluids, 35, 015140 9 (Editor’s Pick).
[58] Santoni2, C., Khosronejad, A., Seiler, P. Sotiropolous, F., (2023), “Toward control co-design of utility-scale wind turbines: Collective vs. individual blade pitch control,” Energy Reports, 9, 793-806.
[57] K. Flora1, and A. Khosronejad, (2022), “Uncertainty quantification of large-eddy simulation results of riverine flows: a field and numerical study,” Environmental Fluid Mechanics, 22, pages1135–1159.
[56] Z. Zhang1, A. B., Limaye, and A. Khosronejad, (2022), “Three-dimensional realizations of flood flow in large-scale rivers using the neural fuzzy-based machine-learning algorithms,” Computers & Fluids, 246, 105611.
[50] Z. Zhang1, K. Flora 2, S. Kang, A. B. Limaye, A. Khosronejad, (2022), Data-driven prediction of turbulent flow statistics past bridge piers in large-scale rivers using convolutional neural networks, Water Resources Research, 58, e2021WR030163.
[49] Z. Zhang 1, C. Santoni 2, T. Herges, F. Sotiropoulos, A. Khosronejad, (2021), Time-averaged wind turbine wake flow field prediction using autoencoder convolutional neural networks, Energies, 15(1), 41.
[48] Khosronejad, A., Kang, S., Wermelinger, F., Koumoutsakos, P., Sotiropoulos, F., (2021), A computational study of expiratory particle transport and vortex dynamics during breathing with and without face masks, Physics of Fluids, 33(5), 066605 (Editor’s Pick) (Journal Cover Paper)
[47] W. R. Oaks1, K. Flora1, and A., Khosronejad, (2021), Eulerian numerical modeling of contaminant transport in Lower Manhattan, New York City, from a point-source release under the dominant wind condition: Insights gained via LES, Atmospheric Environments, 262, 118621, doi: 10.1016/j.atmosenv.2021.118621.
[46] Khosronejad, A., Herb. W., Sotiropoulos, F., Kang, S., Yang, X., (2021), Assessment of Parshall flumes for discharge measurement of open-channel flows: a comparative numerical and field study, Measurements, 167, 108292.
[45] Flora, K.1, & Khosronejad, A. (2021). On the impact of bed-bathymetry resolution and bank vegetation on the flood flow field of the American River, California: Insights gained using data-driven large-eddy simulation. Journal of Irrigation and Drainage Engineering, 147(9), 04021036.
[44] Flora, K. 1, Santoni, C. 2, & Khosronejad, A. (2021). Numerical study on the effect of bank vegetation on the hydrodynamics of the American River under flood conditions. Journal of Hydraulic Engineering, 147(9), 05021006.
[43] S. K., Kang, A. Khosronejad, X., Yang, (2021), Turbulent flow characteristics around a non-submerged rectangular obstacle on the side of an open channel, Physics of Fluids, 33 (4), 045106.
[42] Khosronejad, A., Santoni, C.2, K., Flora1, Z., Zhang1, S., Kang, S., Payabvash, Sotiropoulos, F., (2020), Fluid dynamics simulations show that facial masks can suppress the spread of COVID-19 in indoor environments, AIP Advances, 10 (12), 125109.
[41] Khosronejad, A., M. Ghazian A., D. Angelidis2, E. Bagherzadeh1, K. Flora1, A. Farhadzadeh, (2020), A comparative study of rigid-lid and Level-set methods for LES of open-channel flows: Morphodynamics, Environmental Fluid Mechanics, 20, 145-164.
[40] Khosronejad, A., Diplas, P., Angelidis2, D., Zhang, Z.1, Heydari, N., and Sotiropoulos, F., (2020), Scour depth prediction at the base of longitudinal structures: A combined field, experimental and numerical study, Environmental Fluid Mechanics, 20, 459-478.
[39] Khosronejad, A., Kang, S., Farhadzadeh, A., and Sotiropoulos, F., (2020), On the genesis and evolution of barchan dunes: Hydrodynamics, Physics of Fluid, 32, 086602, (Editor’s Pick).
[38] Bagherizadeh, E.1, Zhang, Z. 1, Aarabi, M., Farhazadeh, A., Khosronejad, A., (2020), A level-set sharp-interface method for resolving solitary waves and fluid-solid interactions: Model development and validation, Journal of Hydraulic Research, DOI: 10.1080/00221686.2020.1818303.
[37] Khosronejad, A. and Sotiropoulos, F., (2020), A short note on the simulation of turbulent stratified flow and mobile bed interaction using the continuum coupled flow and morphodynamics model, Environmental Fluid Mechanics, DOI: 10.1007/s10652-020-09752-8.
[36] Kang, S., Khosronejad, A., Hill, C., and Sotiropoulos, F., (2020), Mean flow and turbulence characteristics around single-arm instream structures, Journal of Hydraulic Research, DOI: 10.1080/00221686.2020.1780494.
[35] Khosronejad, A., Mendelson, L., Techet, A., Kang, S., Angelidis, A., Sotiropoulos, F., (2020), Water exit dynamics of jumping fish: Integrating two-phase flow large-eddy simulation with experimental measurements, Physics of Fluids, 32, 011904 (Featured Article).
[34] Kang, S., Khosronejad A., and Sotiropoulos. S., (2020), Mean flow and turbulence characteristics around multiple-arm instream strictures and comparison with single-arm structures, Journal of Hydraulic Engineering, 146(5), 04020030.
[33] Khosronejad, A., Flora, K. 1, Zhang, Z. 1, and Kang, S., (2020), Large-eddy simulation of flash flood propagation and sediment transport in a dry-bed desert stream, Int. J. Sed. Res., 35(6), 576-586.
[32] Khosronejad A., Flora, K.1, and Kang, S., (2020), Effect of inlet turbulent boundary conditions on scour predictions of coupled LES & morphodynamics in a field-scale river: bankfull flow conditions, Journal of Hydraulic Engineering, 146(4), 04020020.
[31] Lee, J., Kang, S., Kim, Y., and Khosronejad, A., (2020), Experimental study of the wake characteristics of an axial flow hydrokinetic turbine at different tip speed ratios, Ocean Engineering, 196, 106777.
[30] Khosronejad A., Kang. S., and Flora, K. 1, (2019), Fully coupled free-surface flow and sediment transport modelling of flash floods in a desert stream in the Mojave Desert, California; Hydrol. Process., 33(21), 2772-2791.
[29] Khosronejad, A., Ghazian, M., Angelidis, D. 2, Bagherzadeh, E. 1, Flora, K. 1, Farhadzadeh, A. (2019), Comparative hydrodynamic study of rigid-lid and Level-set methods for LES of open- channel flow, Journal of Hydraulic Engineering, 145(1), 04018077.
[28] M. Ghazian Arabi, D. Velioglu Sogut, A. Khosronejad, A., Yalciner, and A. Farhadzadeh, (2019), A numerical and experimental study of formation and evolution of coherent structure due to solitary wave interactions with an impervious obstacle, Coastal Engineering. 147, 43-62.
[27] Khosronejad, A., & Sotiropoulos, F., (2018), Reply to comment by Sookhak Lari, K. and Davis, G. B. on “Large-eddy simulation of turbulence and solute transport in a forested headwater stream”. Journal of Geophysical Research: Earth Surface, 123, 1610-1612, https://doi.org/10.1029/2018JF004663.
[26] Le, T., Khosronejad, A., Bartelt, N., Woldeamlak, S., Peterson, B., DeWall, P., and Sotiropoulos, F., (2019), Large-eddy simulation of the Mississippi River under the base-flow condition: hydrodynamics of a natural diffluence-confluence region. Journal of Hydraulic Research, 57 (6), 836-851.
[25] Khosronejad, A., Kozarek, L. J., Diplas, P., Hill, C., Jha, R., Chatanantavet, P., Heydari, N., and Sotiropoulos, F., (2018), Simulation-based approach for in-stream structure design: Rock–vanes. Environmental Fluid Mechanics. https://doi.org/10.1007/s10652-018-9579-7.
[24] Chawdhary, S., Khosronejad, A., Christodoulou, G., and Sotiropoulos, F., (2018), Large-eddy simulation of density current on sloping beds. Int. Journal of Heat and Mass Transfer, 120, 1374-1385.
[23] Yang, X., Khosronejad, A., & Sotiropoulos, F., (2017), Large-eddy simulation of a hydrokinetic turbine mounted on an erodible bed. Journal of Renewable Energy, 113, 1419-1433.
[22] Khosronejad, A., C. Feist, J. Marr, & Sotiropoulos, F., (2017), Experimental and computational study of a high-Reynolds confined jet. Canadian Journal of Civil Engineering, 44(7), 569-578.
[21] Khosronejad, A. and Sotiropoulos, F., (2017), On the genesis and evolution of barchan dunes: morphodynamics, Journal of Fluid Mechanics, 815, 117-148.
[20] Khosronejad, A., Le, T., Bartelt, N., Woldeamlak, S., Peterson, B., DeWall, P., Yang, X., and Sotiropoulos, F., (2016), High-fidelity numerical modeling of Upper Mississippi River under extreme flood condition. Adv. in Water Resour., 98, 97-113.
[19] Sotiropoulos, F. & Khosronejad, A., (2016), Multi-scale sand waves in environmental flows: Insights gained by coupling large-eddy simulation with morphodynamics. Physics of Fluids, 28, 021301.
[17] Khosronejad, A., Hansen, A.T., Kozarek, J.L., Guentzel, K., Hondzo, M., Guala, M., Wilcock, P., Finlay, J., & Sotiropoulos, F., (2016), Large-eddy simulation of turbulence and solute transport in a forested headwater stream. Journal of Geophysical Research: Earth Surface, 121(1), 146-167.
[16] Khosronejad, A., Diplas, P., & Sotiropoulos, F., (2016), Simulation-based approach for in-stream structures design: Bendway weirs. Environmental Fluid Mechanics, 17(1), 79-109.
[15] Khosronejad, A., Kozarek, L. J., Diplas, P., & Sotiropoulos, F., (2015), Simulation-based approach for in-stream structure design: J-hook vane structures. Journal of Hydraulic Research, 53(5), 588-608.
[14] Khosronejad, A., Kozarek, J. L., Palmsten, M. L., & Sotiropoulos, F., (2015), Numerical simulation of large dunes in meandering streams and rivers with in-stream structures. Advances in Water Resources, 81, 45-61.
[13] Khosronejad, A. & Sotiropoulos, F., (2014), Numerical simulation of sand waves in a turbulent open channel flow. Journal of Fluid Mechanics, 753, 150-216.
[12] Khosronejad, A., Kozarek, J. L., & Sotiropoulos, F., (2014), Simulation-based approach for stream restoration structure design: model development and validation. Journal of Hydraulic Engineering, 140(9), 04014042.
[11] Khosronejad, A., Hill, C., Kang, S., & Sotiropoulos, F., (2013), Experimental and computational investigation of scour past laboratory models of in-stream restoration structures. Advances in Water Resources, 57, 191-207.
[10] Khosronejad, A., Kang, S., and Sotiropoulos, F., (2012), Experimental and computational investigation of local scour around bridge piers. Adv. Water Resour., 37, 73-85, doi:10.1016/j.advwatres.2011.09.013.
[9] Khosronejad, A., Kang, S., Borazjani, I., and Sotiropoulos, F., (2011), Curvilinear immersed boundary method for simulating coupled flow and bed morphodynamic interactions due to sediment transport phenomena. Adv. Water Resour., 34(7), 829-843, doi:10.1016/j.advwatres.2011.02.017.
[8] Khosronejad, A., (2010), CFD Application in 3D flow filed modeling of a large dam reservoir, Journal of Water Sciences Research, 2(1), 57-63
[7] Khosronejad, A. and Rennie, C., (2010), Three-dimensional numerical modeling of unconfined and confined wall-jet flow with two different turbulence models, Canadian Journal of Civil Engineering, 37(4), 576-587.
[6] Khosronejad, A. (2009), Optimization of the Sefid-Roud Dam desiltation process using a sophisticated one-dimensional numerical model, Int. Journal of Sediment Research, 24(2), 189-200.
[5] Khosronejad, A., C. Rennie, A. A. Salehi, I. Gholami, (2008), Three-dimensional numerical molding of reservoir sediment release, Taylor & Francis, IAHR, Journal of Hydraulic Research, 46(2), 209-223.
[4] Khosronejad, A., (2008), Numerical Simulation of Pressure Flushing Process in Sefid-Roud Dam, Journal of Hydraulics, 3(1), 71-77.
[3] Khosronejad, A., C. Rennie, A.A. Salehi Neishabouri, R. Townsend (2007), 3D numerical modeling of flow and sediment transport in 90o and 135o laboratory bends, Journal of Hydraulic Engineering, 133(10), 1-12.
[2] Khosronejad, A., Salehi Neyshabouri, A., (2006), 2D numerical simulation of sediment release from reservoirs, Int. Journal of Sediment Research, 21(1), 74-88.
[1] Khosronejad, A., G. Montazer, M. Ghodsian, (2003), Estimation of scour hole properties around vertical pile group using ANN’s, Int. Journal of Sediment Research, 18(4), 290-300.
Selected Peer-Reviewed Conference Proceedings and Abstracts
[14] Khosronejad, A., and Flora, F., (2021), high-fidelity modeling of coupled flow and bed morphodynamics to investigate scour damaged structures in California, International Conference on Scour and Erosion (ICSE-10), October 17-20, Virginia, United States.
[13] Khosronejad, A., Flora, K., and Kang, S., (2020), High-fidelity three-phase flow simulation of flash and riverine floods in real-life waterways, River Flow 2020, 1st Edition, CRC Press, pp: 1310-1318, DOI: 10.1201/b22619-182, The Netherlands.
[12] Apsilidis, N., Khosronejad, A., Sotiropoulos, F., Dancey, C. L., Diplas, P., (2012), Physical and numerical modeling of the turbulent flow field upstream of a bridge pier, International Conference on Scour and Erosion, Vol. 6, Paris, France.
[11] Khosronejad, A., Ashrafzadeh, A., and Vazifedoust, M., (2009), Numerical Modeling of Flushing Process in Dez Dam Reservoir by HR Wallingford Method, World Environmental and Water Resources Congress: Great Rivers, May 17-21, Kansas City, Missouri, United States.
[10] Khosronejad, A., Rennie, C., (2009), Mathematical modeling of a real jet flow, 3rd International conference on modeling, simulation and applied optimization, January 20-22, American University of Sharjah, UAE.
[9] Hajhosseini, M., A. A. Salehi Neyshabouri, and Khosronejad, A., (2009), Three-Dimensional modeling of flushing process”, 3rd International conference on modeling, simulation and applied optimization, January 20-22, American University of Sharjah, UAE.
[8] Khosronejad, A., (2008), Three-Dimensional numerical simulation of flow filed in the Dez Dam Reservoir, 2nd International Junior Researcher and Engineer Workshop on Hydraulic Structures, University of Pisa, Pisa, Italy.
[7] Khosronejad, A., (2008), Reservoir flushing optimization using a sophisticated 1D numerical model, Junior Researcher and Engineer Workshop on Hydraulic Structures, University of Pisa, Pisa, Italy.
[6] Khosronejad, A., Moghimi, S., (2008), Qualitative analysis of sediment entering power tunnels using a sophisticated 3D numerical model; case study: Dez dam, 8th International Conference on Hydro-Science and Engineering (ICHE- 2008), September 8-12, Nagoya, Japan.
[5] Moghimi, S., Guenther, H., Khosronejad, A., (2008), Effects of the presence of wave on shallow estuaries hydrodynamics, 8th International Conference on Hydro-Science and Engineering (ICHE-2008), September 8-12, Nagoya, Japan.
[4] Khosronejad, A., Rennie, C., Moghimi, S., (2007), 3D numerical modeling of the flow field and sediment transport in a laboratory model of the reservoir flushing process, Proceedings of Congress of IAHR, the International Association of Hydraulic Engineering & Research, Vol. 1, July 1-6, Venice, Italy.
[3] Moghimi, S., Shafieefar, M., Khosronejad, A. et al., (2007), Evaluation of the effects of Causeway construction on Urmia Lake freshwater circulation, Proceedings of Congress of IAHR, the International Association of Hydraulic Engineering & Research, Vol. 1, July 1-6, Venice, Italy.
[2] Khosronejad, A., Rennie, C., (2007), Sediment transport modeling in a laboratory 90o bend using a sophisticated morphodynamic model, 2nd International Conference on Managing Rivers in the 21st Century: Solutions Towards Sustainable River Basins, Kuching, Sarawak, Malaysia.
[1] Khosronejad, A., Ghodsian, M., Alihemmati, R., (2004), Prediction of Scour Depth Around Pile Group Using ANN, Proceedings of 2nd International Conference on Scour and Erosion (ICSE-2). November 14-17., Singapore.
Books and Book Chapters
[5] Khosronejad, A., Rennie, C.D., Moghimi, S., (2019), Application of Intelligent system of Artificial Neural Networks to predict the scour process in coastal engineering, River, Coastal and Estuaries Morphodynamics, Taylor and Francis, CRC Press, 1139-1144.
[4] Khosronejad, A. (2018). Mathematical modeling of sediment transport and deposition in reservoirs, International Committee of Large Dams (ICOLD).
[3] Khosronejad, A., Parvaresh, A. (2013). Mechanics of sediment transport. Noavar Publication. ISBN 9786001681349.
[2] Sotiropoulos, F., Diplas, P., Khosronejad, A. (2012). Scour around hydraulic structures. Handbook of Environmental Fluid Dynamics (Edited by H. J. S. Fernando), Taylor and Francis, CRC Press.
[1] Kang, S., Khosronejad, A., and Sotiropoulos, F. (2012). Numerical simulation of turbulent flow and sediment transport processes in arbitrarily complex waterways. Environmental Fluid Mechanics: Memorial Volume in honor of the late Professor Gerhard H. Jirka (Eds: Rodi, W. and Uhlmann, M.), IAHR Monograph, CRC Press.
Selected Conference Abstracts and Presentations
Flora1, K., and Khosronejad, A., (2019), LES of a large-scale river with arbitrarily complex bathymetry and wall-mounted structures, American Physical Society, 72nd Annual Meeting of the APS Division of Fluid Dynamics Abstracts, C38. 007.
Khosronejad, A., and Flora1, K., (2019), Three-phase flow LES of flash floods in a real-life desert stream, American Physical Society, 72nd Annual Meeting of the APS Division of Fluid Dynamics Abstracts, C38. 009.
Khosronejad, A., (2018), Large-eddy simulation of multi-scale subaqueous sediment dynamics: From large-scale natural rivers to laboratory-scale sedimentary flows, 12th European Fluid Mechanics Conference, 09-13 September, Vienna, Austria.
Khosronejad, A., and Flora1, K., (2018), LES-and RANS-based Modeling of Coupled Flow & Mobile bed Evolution in a Natural River Under Various Flood-induced Turbulent Boundary Layers, American Physical Society, 71st Annual Meeting of the APS Division of Fluid Dynamics Abstracts, Bulletin of the American Physical Society 63.
Bagherizadeh1, E., and Khosronejad, A., (2018), Large-eddy simulation of solitary wave and bridge pier interaction: Model development and validation, American Physical Society, 71st Annual Meeting of the APS Division of Fluid Dynamics Abstracts, Bulletin of the American Physical Society 63.
Khosronejad, A., (2018), Fully Coupled Hydro-and Morpho-dynamics Modeling of a Field-scale River Under Various Flood-induced Turbulent Boundary Layers at the Inlet Using LES and unsteady RANS, American Geophysical Union (AGU) Fall Meeting Abstracts, EP53B-21.
Khosronejad, A., Bagherizadeh1, E., Flora1, K., (2018) One the effects of rigid-lid assumption on LES results of high-Re flows, 8th International Symposium on Environmental Hydraulics, June 4-7, University of Notre Dame, South Bend, Indiana.
Khosronejad, A., and Farhadzadeh, A., (2017), How do rigid-lid assumption affect LES simulation results at high Reynolds flows? American Physical Society, 70th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, F31. 004.
Khosronejad, A., and Sotiropoulos, F., (2016), Coupled large-eddy simulation and morphodynamics of a large-scale river under extreme flood conditions, American Physical Society, 69th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, A13. 001.
Khosronejad, A., (2016), Tackling some of the most intricate geophysical challenges via high-performance computing, American Geophysical Union (AGU) Fall Meeting Abstracts, EP51C-05 (Invited Talk).
Le, T., Khosronejad, A., N., Bartelt, S., Woldeamlak, B., Peterson, P., DeWall, etc., (2015), Flow dynamics at a river confluence on Mississippi River: field measurement and large eddy simulation, American Physical Society, 68th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, G30. 006.
Khosronejad, A., and Sotiropoulos, F., (2015), Large-eddy simulation of sand dune morphodynamics, American Physical Society, 68th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, R29. 011.
Chawdhary, S., X. Yang, C. Hill, A. Khosronejad, M. Guala, F. Sotiropoulos, (2015), Wake structure of axial-flow hydrokinetic turbines in tri-frame arrangement, American Physical Society, 68th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, R1. 007.
Khosronejad, A., J. Kozarek, A. Hansen, K. Guentzel, M. Hondzo, P. Wilcock, etc., (2014), Data-driven LES of turbulence and solute transport in a natural stream, American Physical Society, 67th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, R23. 009.
Palmsten, M.L., J.L., Kozarek, A., Khosronejad, J., Calantoni, (2014), Bedform Morphodynamics in a Meandering Stream, American Geophysical Union (AGU) Fall Meeting Abstracts, EP43C-3579.
Sotiropoulos, F., S Chawdhary, X Yang, A Khosronejad, D Angelidis, (2014), Simulation-Based Approach for Site-Specific Optimization of Hydrokinetic Turbine Arrays, American Geophysical Union (AGU) Fall Meeting Abstracts, OS21F-03.
Yang,X, Khosronejad, A., Sotiropoulos, F., (2013), Large-eddy simulation of the flow over a hydrokinetic turbine mounted on an erodible bed, American Physical Society, 66th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, E13. 003.
Chawdhary, S., Khosronejad, A., G Christodoulou, Sotiropoulos, F., (2013), Large-eddy simulation of density currents on inclined beds. American Physical Society, 66th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, R1. 003.
Khosronejad, A., and Sotiropoulos, F., (2013), Large-eddy simulation of coupled turbulence, free surface, and sand wave evolution in an open channel, American Physical Society, 66th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, R1. 004.
Yang, X., Khosronejad, A., Sotiropoulos, F., (2013), Numerical investigation of bed morphodynamics due to a hydrokinetic turbine, American Geophysical Union (AGU) Fall Meeting Abstracts, OS13E-06.
Sotiropoulos, F., and Khosronejad, A., (2012), Numerical simulation of bed morphodynamics in natural waterways: From ripples to dunes, American Geophysical Union (AGU) Fall Meeting Abstracts, EP53G-08.
Kozarek, J., M.L., Palmsten, J. Calantoni, A. Khosronejad, F. Sotiropoulos, (2012), Three-Dimensional Flow Fields and Bedform Migration in a Field-Scale Meandering Channel, American Geophysical Union (AGU) Fall Meeting Abstracts, EP53B-1033.
Khosronejad, A., Kozarek, J., C., Hill, S., Kang, R. Plott, P., Diplas, Sotiropoulos, F., (2012), Designing stream restoration structures using 3D hydro-morphodynamic numerical modeling, American Geophysical Union (AGU) Fall Meeting Abstracts, EP23D-0862.
Khosronejad, A., Sotiropoulos, F., (2012), Numerical simulation of turbulence and sand-bed morphodynamics in natural waterways under live bed conditions, American Physical Society, 65th Annual Meeting of the APS Division of Fluid Dynamics Abstracts, G13. 004.
Khosronejad, A., and Sotiropoulos, F., (2012), Numerical simulation of meander-bend morphodynamics: Investigating the efficiency of rock-vanes in bank protection, 3rd International Symposium on Shallow Flows (ISSF), June 4-6, University of Iowa, Iowa City, Iowa.
Apsilidis, N., Khosronejad, A, Diplas, P., Sotiropoulos, F., Dancey, D., (2012), Vortical flow structure around a cylindrical bridge pier: flows in high curvature meander bends Experimental and computational investigation, 3rd International Symposium on Shallow Flows (ISSF), June 4-6, University of Iowa, Iowa City, Iowa.
Khosronejad, A., S. O. Erwin, J. Kozarek, P. Wilcock, Sotiropoulos, F., (2011), Three-dimensional numerical simulation of point bar growth in a field-scale experimental meander bend, American Geophysical Union (AGU) Fall Meeting Abstracts, EP21B-0682.
Khosronejad, A., Sotiropoulos, F., (2011), Numerical Simulation of turbulent flow and sediment transport around real-life stream restoration structures, American Physical Society, 64th Annual Meeting of the APS Division of Fluid Dynamics Abstracts 64, S1. 002.
Kozarek, J., Hill, C., Kang, S., Khosronejad, A., Hajit, M., Guentzel, M., Hondzo, M., Sotiropoulos, F., (2011), Ecogeomorphic response to stream restoration practices in an experimental meandering stream channel, The Geological Society of America (GSA) Annual Meeting, Minneapolis, Minnesota.
Khosronejad, A., S., Kang, I., Borazjani, Sotiropoulos, F., (2010), Application of Curvilinear Immersed Boundary Method to Simulate Sediment Transport Phenomena in Bend Flows, American Geophysical Union (AGU) Fall Meeting Abstracts, EP51C-0567.
Hill, C., Kang, S., Khosronejad, A., Sotiropoulos, F., Diplas, P., (2010), Turbulent structures and scour development produced during small-scale stream restoration structure experiments, American Geophysical Union (AGU) Fall Meeting Abstracts, EP51C-0570.
Halliday1, C., Khosronejad, A., (2010), Prediction of Scour Around Bridge Piers Using Artificial Neural Networks Trained with Experimental Data, American Geophysical Union (AGU) Fall Meeting Abstracts, EP51C-0572.
Khosronejad, A., Kang, S., Borazjani, I., and Sotiropoulos, F. (2010). Curvilinear Immersed Boundary Method for Simulating Sediment Transport and Scour in Open Channel Flows. In American Physical Society, 63rd Annual Meeting of the APS Division of Fluid Dynamics, November 21-23, Long Beach, California.
Khosronejad, A., (2009), On the effects of Schmidt number and particle settling velocity on the calculated sediment concentration profile, American Physical Society, 62nd Annual Meeting of the APS Division of Fluid Dynamics, November 22-24, abstract id. L1.008, Minneapolis, Minnesota.
Nikolaos Apsilidis, Sam Raben, Panayiotis Diplas, Clinton Dancey, Pavlos Vlachos, Ali Khosronejad, Fotis Sotiropoulos, (2009), Reynolds number effects on the dynamics of the turbulent horseshoe vortex: High-resolution experiments and numerical simulations, American Physical Society, 62nd Annual Meeting of the APS Division of Fluid Dynamics, November 22-24, abstract id. GT.010, Minneapolis, Minnesota.
Khosronejad, A., K. Ghazanfari, M. A. Mirzaei, (2007), Numerical modeling of Sefid Roud Dam’s reservoir flushing, ICOLD Annual Conf., St Petersburg, Russia.
Khosronejad, A., K. Ghazanfari, M. Mirzaei, (2007), Study on a new low-level sediment venting system for Dez Dam, Hydro 2007 Conf., ICOLD, Granada, Spain.
Khosronejad, A., Colin Rennie, S. Moghimi, (2007), Application of Intelligent System of Artificial Neural Network to Predict the Scour Process in Coastal Engineering, Int. Conf. of RCEM 2007, Univ. of Twenty, The Netherlands.
Khosronejad, A., C. Rennie, (2006), Experimental study of flow and sediment transport in flow around abutments, 3rd Int. Conf. of Scour and Erosion, Amsterdam, the Nether lands.
Khosronejad, A., C. Rennie, (2006), 3D numerical modeling of flow and sediment transport in channel bend”, 7th International Conference on Hydro-informatics, HIC 2006, Nice, France.
Invited Talks
Khosronejad, A., (2022), CFD studies concerning COVID-19 and saliva transport, January 13, Department of Mechanical, Aerospace and Civil Engineering, School of Engineering, University of Manchester, UK.
Khosronejad, A., (2021), Physics-based data-driven high-fidelity models for extreme flood prediction: A coupled flow and sediment dynamics approach, March 5, National Oceanic and Atmospheric Administration, Washington DC.
Khosronejad, A., (2021), Physics-based data-driven high-fidelity models for extreme flood prediction: Numerical algorithms, April 27, National Oceanic and Atmospheric Administration, Washington DC.
Khosronejad, A., (2021), High-fidelity numerical simulation of turbulent fluid flow in arbitrarily complex domains, April 27, The Einstein Chair Mathematics Seminar, New York City, New York.
Khosronejad, A., (2021), Saliva Particle Transport during Cough & Breathing: Insights on Effective Social Distancing & Face Wearing Gained by LES, February 5, Department of Aerospace & Mechanical Engineering, University of Southern California, California.
Khosronejad, A., (2020), High-fidelity numerical simulation of turbulent flows and bed morphodynamics in small- to large-scale environments, February 5, School of Engineering and Applied Sciences, University of Exeter, Exeter, United Kingdom.
Khosronejad, A., (2020), High-fidelity numerical simulation of turbulent flows and bed morphodynamics in small- to large-scale environments, February 5, School of Engineering and Applied Sciences, University of Exeter, Exeter, United Kingdom.
Khosronejad, A., (2018), High-fidelity numerical simulation of turbulent flows and bed morphodynamics, Federal Highway Administration, US Department of Transportation, April, Washington DC.
Khosronejad, A., (2017), High-fidelity modeling of two-phase flow problems, October 10, Seminar Series of Civil Engineering Department, College of Engineering and Applied Sciences, Stony Brook University. Stony Brook, New York.
Khosronejad, A., (2016), Tackling Environmental Fluid Mechanics Challenges via High-Performance Computing, Two-Phase Continuum Models for Geophysical Particle-Fluid Flows, GeoFlow 16, March 14-18, Max Planck Institute for the Physics of Complex Systems Dresden, Germany.
Khosronejad, A., (2016), Tackling some of the most intricate geophysical challenges via high-performance computing, American Geophysical Union (AGU) Fall Meeting, December 6-12, San Francisco, California.
Khosronejad, A., (2016), Fully coupled flow and morphodynamics numerical simulations in field-scale rivers: Rio Madre de Grande, June 21, the National University of Engineering of Peru, Universidad Nacional de Ingeniería Peru, Lima, Peru.
Khosronejad, A., (2016), Large-eddy simulation for fluid dynamics discoveries, June 18, National University of San Marcos, Universidad Nacional Mayor de San Marcos, Lima, Peru.
Recognitions & Media Coverage
- The Times Beacon Record Newspapers: Stony Brook University scientists receive award for wind farm research, https://tbrnewsmedia.com/?s=khosronejad
- Featured Researcher, Civil Engineering Department, Stony Brook University, https://www.stonybrook.edu/commcms/civileng/featured_researcher/Khosronjed.php