{"id":1762,"date":"2025-02-03T00:05:18","date_gmt":"2025-02-03T00:05:18","guid":{"rendered":"https:\/\/clusterdem.ubi.pt\/?page_id=1762"},"modified":"2026-04-15T14:45:03","modified_gmt":"2026-04-15T14:45:03","slug":"international-journal-articles","status":"publish","type":"page","link":"https:\/\/clusterdem.ubi.pt\/?page_id=1762","title":{"rendered":"International Journal Articles"},"content":{"rendered":"\t\t<div data-elementor-type=\"wp-page\" data-elementor-id=\"1762\" class=\"elementor elementor-1762\">\n\t\t\t\t\t\t\t\t\t<section class=\"has_eae_slider elementor-section elementor-top-section elementor-element elementor-element-b97cbbb elementor-section-boxed elementor-section-height-default elementor-section-height-default\" data-id=\"b97cbbb\" data-element_type=\"section\">\n\t\t\t\t\t\t<div class=\"elementor-container elementor-column-gap-default\">\n\t\t\t\t\t<div class=\"has_eae_slider elementor-column elementor-col-100 elementor-top-column elementor-element elementor-element-974ba8c\" data-id=\"974ba8c\" data-element_type=\"column\">\n\t\t\t<div class=\"elementor-widget-wrap elementor-element-populated\">\n\t\t\t\t\t\t\t\t<div class=\"elementor-element elementor-element-a7831c8 elementor-widget elementor-widget-text-editor\" data-id=\"a7831c8\" data-element_type=\"widget\" data-widget_type=\"text-editor.default\">\n\t\t\t\t<div class=\"elementor-widget-container\">\n\t\t\t\t\t\t\t<p style=\"font-weight: 400;\"><script type=\"text\/javascript\" src=\"\/\/cdn.plu.mx\/widget-details.js\"><\/script><\/p>\n<p style=\"font-weight: 400;\"><strong>\n\n<a name=\"_Toc452327661\"><\/a>\nJournal Articles (<span id=\"pub-count\">48<\/span>)\n<\/strong><\/p>\n\n<ol id=\"pub-list\">\n<li>Moghadam, H. A., Dolati, F., Bagherighajari, F., &#038; Taromsari, M. M. (2026). Parametric investigation of a solid-porous fin design for microchannel thermal performance improvement. International Journal of Heat and Fluid Flow, 118, 110210.<\/li>\n<li>Gerdroodbary, M. B., &#038; Pascoa, J. C. (2026). Predictive Surrogate Model for estimation of the fuel mixing of transient transverse hydrogen jet at supersonic flow. Acta Astronautica.<\/li>\n\n<li>Teixeira, O., &#038; P\u00e1scoa, J. (2026). Sensitivity of Hypersonic MHD Flow Control to the Surface Catalytic Properties of a Reentry Body. Journal of Aerospace Engineering, 39(1), 04025108.<\/li>\n\n<li>Bagherighajari, F., Abdollahzadehsangroudi, M., &#038; Pascoa, J. C. (2026). Surface dielectric barrier discharge plasma actuators for flame stabilization and combustion control: mechanisms, design trends, and future directions. Fuel, 424, 139348.<\/li>\n\n<li>Khodkameh, M., Amanifard, N., Dolati, F., &#038; Abdollahzadehsangroudi, M. (2026). Optimization of Sweeping Jet Cooling via Fluidic Oscillator: A Parametric Study. European Journal of Mechanics-B\/Fluids, 204513.<\/li>\n\n<li>Farreamini, F., Mahmoudimehr, J., Abdollahzadehsangroudi, M., &#038; Dolati, F. (2025). Numerical investigation of performance of an interdigitated polymer electrolyte membrane fuel cell with a porous rib. Proceedings of the Institution of Mechanical Engineers, Part A: Journal of Power and Energy, 09576509261418828.<\/li>\n\n<li>Martinho, D. L., Abdollahzadehsangroudi, M., Araya, S. S., &#038; Berning, T. (2025). Eulerian-Eulerian CFD Modeling of Multiphase Flow and Heat Transfer in Alkaline Electrolysis Cells. Journal of The Electrochemical Society, 172(6), 064501.<\/li>\n\n<li>Mbanguine, L., Rodrigues, F., &#038; P\u00e1scoa, J. (2025). Experimental analysis of dielectric thickness influence on novel electro-active polymer plasma actuators (EAP-PA) for flow control and ice removal systems. Sensors and Actuators A: Physical, 392, 116706.<\/li>\n\n<li>Gomes, D., Esp\u00edrito Santo, A., &#038; P\u00e1scoa, J. C. (2025). A sparse and decoupled supervision framework for multi-field reconstruction in turbulent flows using physics-informed neural networks. Physics of Fluids, 37(7), 075113.<\/li>\n\n \t<li>Shvydyuk, K. O., Rodrigues, F. F., Nunes-Pereira, J., P\u00e1scoa, J. C., &amp; Silva, A. P. (2025, March). Thermal Characterization of Ceramic Composites for Optimized Surface Dielectric Barrier Discharge Plasma Actuators. In Actuators (Vol. 14, No. 3, p. 127). MDPI.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fact14030127\" data-site=\"plum\" data-hide-when-empty=\"true\">Thermal Characterization of Ceramic Composites for Optimized Surface Dielectric Barrier Discharge Plasma Actuators<\/a><\/li>\n \t<li>Nunes, G., Moreira, M., Rodrigues, F., &amp; P\u00e1scoa, J. (2025, March). Experimental Analysis of Electrohydrodynamic Jet Actuation Modes Based on the Phase Doppler Technique. In Actuators (Vol. 14, No. 3, p. 141). MDPI.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fact14030141\" data-site=\"plum\" data-hide-when-empty=\"true\">Experimental Analysis of Electrohydrodynamic Jet Actuation Modes Based on the Phase Doppler Technique<\/a><\/li>\n \t<li>Pendar, M. R., C\u00e2ndido, S., P\u00e1scoa, J. C., &amp; Lima, R. (2025). Enhancing Automotive Paint Curing Process Efficiency: Integration of Computational Fluid Dynamics and Variational Auto-Encoder Techniques. Sustainability, 17(7), 3091.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fsu17073091\" data-site=\"plum\" data-hide-when-empty=\"true\">Enhancing Automotive Paint Curing Process Efficiency: Integration of Computational Fluid Dynamics and Variational Auto-Encoder Techniques<\/a><\/li>\n \t<li>Teixeira, O., P\u00e1scoa, J., &#038; Purpura, C. (2025). Numerical model validation and aerodynamic MHD performance assessment with novel designs of contoured nozzles for hypersonic plasma wind tunnel testing. Aerospace Science and Technology, 164, 110439.<\/li>\n \t<li>Teixeira, O., &amp; P\u00e1scoa, J. (2025). Numerical Analysis of a Hypersonic Body Under Thermochemical Non-Equilibrium and Different Catalytic Surface Conditions. Actuators, 14(2), 102. https:\/\/doi.org\/10.3390\/act14020102<\/li>\n \t<li>Moreira, M., Rodrigues, F., &amp; P\u00e1scoa, J. (2025). An experimental study on the use of dielectric barrier discharge plasma actuators for electrospray dynamics enhancement. Physics of Fluids, 37(2).\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0248754\" data-site=\"plum\" data-hide-when-empty=\"true\">An experimental study on the use of dielectric barrier discharge plasma actuators for electrospray dynamics enhancement<\/a><\/li>\n \t<li>Mbanguine, L., Rodrigues, F., &amp; P\u00e1scoa, J. (2025). New Electro-Active Polymers-Based Plasma Actuators for Simultaneous Flow Control and Ice Protection. Journal of Fluids Engineering, 1-31.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4067786\" data-site=\"plum\" data-hide-when-empty=\"true\">New Electro-Active Polymers-Based Plasma Actuators for Simultaneous Flow Control and Ice Protection<\/a><\/li>\n \t<li>Benmoussa, A., Pendar, M. R., &amp; P\u00e1scoa, J. C. (2025). Enhancing electrostatic spray-painting efficiency with modified high-voltage conductors: A numerical study on pulsed electric fields. Journal of Aerosol Science, 184, 106491.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.jaerosci.2024.106491\" data-site=\"plum\" data-hide-when-empty=\"true\">Enhancing electrostatic spray-painting efficiency with modified high-voltage conductors: A numerical study on pulsed electric fields<\/a><\/li>\n \t<li>Trancossi, M., &amp; Pascoa, J. (2025). Energy and exergy analysis based design of a series hybrid electric vehicle (No. 2025-01-8596). SAE Technical Paper.<\/li>\n \t<li>Bagherighajari, F.,Abdollahzadehsangroudi, M., P\u00e1scoa, J.C. (2025) &#8220;Methane\/Air Flame Control in Non-Premixed Bluff Body Burners Using Ring-Type Plasma Actuators&#8221;, Actuators 14 (2), 47\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fact14020047\" data-site=\"plum\" data-hide-when-empty=\"true\">Methane\/Air Flame Control in Non-Premixed Bluff Body Burners Using Ring-Type Plasma Actuators<\/a><\/li>\n \t<li>Chekifi, T., Boukraa, M., &amp; Benmoussa, A. (2024). Artificial Intelligence for thermal energy storage enhancement: A Comprehensive Review. Journal of Energy Resources Technology.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4065197\" data-site=\"plum\" data-hide-when-empty=\"true\">Artificial Intelligence for Thermal Energy Storage Enhancement: A Comprehensive Review<\/a><\/li>\n \t<li>Chekifi, T., Benmoussa, A., &amp; Boukraa, M. (2024). Desalination Powered by Renewables: A Challenge and an AI Opportunity. Water Resources Management, 1-43.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1007%2Fs11269-024-03935-4\" data-site=\"plum\" data-hide-when-empty=\"true\">Desalination Powered by Renewables: A Challenge and an AI Opportunity<\/a><\/li>\n \t<li>Teixeira, O., &amp; Pascoa, J. (2024). Computational Modelling of Hypersonic Nozzles: The Influence of Enthalpy on the Flow Thermochemistry (No. 2024-01-1935). SAE Technical Paper.<\/li>\n \t<li>C\u00e2ndido, S., &amp; P\u00e1scoa, J. C. (2024). Data-driven surrogate modelling of multistage Taylor cone\u2013jet dynamics. Physics of Fluids, 36(5).<\/li>\n \t<li>Trancossi, M., Pascoa, J., &amp; Catellani, T. (2024). Guidelines Toward an Expansive Exergy-Based Fiscal System That Encourages Energy Transition and Societal Wellness. International Journal of Sustainable Development &amp; Planning, 19(11).<\/li>\n \t<li>Barzegar Gerdroodbary, M., Shiryanpoor, I., Salavatidezfouli, S., Abazari, A. M., &amp; Pascoa, J. C. (2024). Optimizing aerodynamic stability in compressible flow around a vibrating cylinder with deep reinforcement learning. Physics of Fluids, 36(12).<\/li>\n \t<li>Benmoussa, A., &amp; P\u00e1scoa, J. C. (2024). A Chamfered Anchor Impeller Design for Enhanced Efficiency in Agitating Viscoplastic Fluids. Fluids, 9(12), 288.<\/li>\n \t<li>Loureiro Martinho, D., Abdollahzadehsangroudi, M., Berning, T. (2024) &#8220;Computational Fluid Dynamics Analysis of Gas Crossover in an Alkaline Electrolyzer Using a Multifluid Model&#8221;, ECS Transactions 114 (5), 727\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1149%2F11405.0727ecst\" data-site=\"plum\" data-hide-when-empty=\"true\">Computational Fluid Dynamics Analysis of Gas Crossover in an Alkaline Electrolyzer Using a Multifluid Model<\/a><\/li>\n \t<li>Rodrigues, F., Moreira, M., &amp; P\u00e1scoa, J. (2024). Characterization of Plasma-Induced Flow Thermal Effects for Wind Turbine Icing Mitigation. Energies, 17(16), 3974.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fen17163974\" data-site=\"plum\" data-hide-when-empty=\"true\">Characterization of Plasma-Induced Flow Thermal Effects for Wind Turbine Icing Mitigation<\/a><\/li>\n \t<li>Shvydyuk, K. O., Nunes-Pereira, J., Rodrigues, F. F., P\u00e1scoa, J. C., Lanceros-Mendez, S., &amp; Silva, A. P. (2024). Holistic Characterization of MgO-Al2O3, MgO-CaZrO3, and Y2O3-ZrO2 Ceramic Composites for Aerospace Propulsion Systems. Ceramics, 7(1), 364-384\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fceramics7010023\" data-site=\"plum\" data-hide-when-empty=\"true\">Holistic Characterization of MgO-AlO, MgO-CaZrO, and YO-ZrO Ceramic Composites for Aerospace Propulsion Systems<\/a><\/li>\n \t<li>Rodrigues, F. F., Shvydyuk, K. O., Nunes-Pereira, J., P\u00e1scoa, J. C., &amp; Silva, A. P. (2024). Plasma Actuators Based on Alumina Ceramics for Active Flow Control Applications. Ceramics, 7(1), 192-207\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fceramics7010012\" data-site=\"plum\" data-hide-when-empty=\"true\">Plasma Actuators Based on Alumina Ceramics for Active Flow Control Applications<\/a><\/li>\n \t<li>Periyadurai, K., Pascoa, J. C. , Abdollahzadehsangroudi, M. , Oliveira, P. J. (2024), Numerical modeling of magnetohydrodynamic non-Newtonian flow in a cross-slot,Polym Eng Sci; 64(5): 2157-2177\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Fpen.26683\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical modeling of magnetohydrodynamic non-Newtonian flow in a cross-slot<\/a><\/li>\n \t<li>Sheibani, M.,\u00a0 Malek Jafarian, S.M.,\u00a0 Abdollahzadehsangroudi, M. (2024) &#8220;Impact of annular nanosecond plasma actuators on drag reduction in transonic flow&#8221;, Physics of Fluids 36, 116121\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0237182\" data-site=\"plum\" data-hide-when-empty=\"false\">Impact of annular nanosecond plasma actuators on drag reduction in transonic flow<\/a><\/li>\n \t<li>Abdollahzadehsangroudi, M. , Francisco, M., Lopes, R., Dolati, F., Pascoa, J.C., Rodrigues, F. (2024) &#8220;Insight into porous fin microchannel heat sinks with improved thermo-hydraulic performance&#8221;, Physics of Fluids 36, 042015\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0198294\" data-site=\"plum\" data-hide-when-empty=\"true\">Insight into porous fin microchannel heat sinks with improved thermo-hydraulic performance<\/a><\/li>\n \t<li>Benmoussa, A. (2023). Agitation of Viscoplastic Fluid in a Rotating Vessel Using Close Clearance Agitators. Eng, 4(4), 2525-2541.\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Feng4040144\" data-site=\"plum\" data-hide-when-empty=\"true\">Agitation of Viscoplastic Fluid in a Rotating Vessel Using Close Clearance Agitators<\/a><\/li>\n \t<li>Shvydyuk, K. O., Nunes-Pereira, J., Rodrigues, F. F., &amp; Silva, A. P. (2023). Review of ceramic composites in aeronautics and aerospace: A multifunctional approach for TPS, TBC and DBD applications. Ceramics, 6(1), 195-230.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fceramics6010012\" data-site=\"plum\" data-hide-when-empty=\"true\">Review of Ceramic Composites in Aeronautics and Aerospace: A Multifunctional Approach for TPS, TBC and DBD Applications<\/a><\/li>\n \t<li>Mohammadi, A., Dolati, F., Hassani, F., P\u00e1scoa, J.C., Abdollahzadehsangroudi, M. (2023), Numerical Analysis and Optimization of Heat Transfer Enhancement on a Flat Plate by an EHD Jet,International Journal of Heat and Mass Transfer 217, 124707\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatmasstransfer.2023.124707\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical analysis and optimization of heat transfer enhancement on a flat plate by an EHD jet<\/a><\/li>\n \t<li>Diogo Loureiro Martinho, Torsten Berning, Mohammadmahdi Abdollahzadehsangroudi, Anders R\u00f8nne Rasmussen, Jakob H\u00e6rvig and Samuel Simon Araya (2023), A Three-Dimensional, Multiphysics Model of An Alkaline Electrolyzer,ECS Trans. 112 433\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1149%2F11204.0433ecst\" data-site=\"plum\" data-hide-when-empty=\"true\">A Three-Dimensional, Multiphysics Model of An Alkaline Electrolyzer<\/a><\/li>\n \t<li>Benmoussa, A., Rodrigues, F.F., P\u00e1scoa, J.C. (2023) &#8220;Plasma Actuators for Cycloidal Rotor Thrust Vectoring Enhancement in Airships&#8221;, Actuators, 12(12),436\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fact12120436\" data-site=\"plum\" data-hide-when-empty=\"true\">Plasma Actuators for Cycloidal Rotor Thrust Vectoring Enhancement in Airships<\/a><\/li>\n \t<li>C\u00e2ndido, S., P\u00e1scoa, J.C. (2023) &#8220;On modal decomposition as surrogate for charge-conservative EHD modelling of Taylor Cone jets&#8221;, International Journal of Engineering Science, 193,103947\n\n<a class=\"plumx-details plum-bigben-theme\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijengsci.2023.103947\" data-site=\"plum\" data-hide-when-empty=\"true\">On modal decomposition as surrogate for charge-conservative EHD modelling of Taylor Cone jets<\/a><\/li>\n \t<li>Khasare, S., Bagherighajari, F., Dolati, F., (&#8230;), Pascoa, J.C., Abdollahzadeh, M. (2023) &#8220;Control of the flame and flow characteristics of a non-premixed bluff body burner using dielectric barrier discharge plasma actuators&#8221;, Applied Thermal Engineering 235,121432\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.applthermaleng.2023.121432\" data-site=\"plum\" data-hide-when-empty=\"true\">Control of the flame and flow characteristics of a non-premixed bluff body burner using dielectric barrier discharge plasma actuators<\/a><\/li>\n \t<li>Shvydyuk, K.O., Rodrigues, F.F., Nunes-Pereira, J., (&#8230;), Lanceros-Mendez, S., Silva, A.P. (2023) &#8220;Long-lasting ceramic composites for surface dielectric barrier discharge plasma actuators&#8221;, Journal of the European Ceramic Society 43(14), pp. 6112-6121\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.jeurceramsoc.2023.05.040\" data-site=\"plum\" data-hide-when-empty=\"true\">Long-lasting ceramic composites for surface dielectric barrier discharge plasma actuators<\/a><\/li>\n \t<li>Bagherighajari, F., Moradi Bilondi, A., Abdollahzadehsangroudi, M., Hamrang, A., P\u00e1scoa, J.C. (2023) &#8220;A parametric numerical study on the performance of polymer electrolyte membrane fuel cell with intermediate-blocked interdigitated flow field designs&#8221;, Fuel Cells 23(4), pp. 304-322\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Ffuce.202200188\" data-site=\"plum\" data-hide-when-empty=\"true\">A parametric numerical study on the performance of polymer electrolyte membrane fuel cell with intermediate-blocked interdigitated flow field designs<\/a><\/li>\n \t<li>Khasare, S., Bagherighajari, F., Dolati, F., (&#8230;), P\u00e1scoa, J., Abdollahzadehsangroudi, M. (2023) &#8220;The effect of the dielectric barrier discharge plasma actuator in the control of non-reactive flow in a non-premixed bluff body burner&#8221;, Physics of Fluids 35(7),075135\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0157976\" data-site=\"plum\" data-hide-when-empty=\"true\">The effect of the dielectric barrier discharge plasma actuator in the control of non-reactive flow in a non-premixed bluff body burner<\/a><\/li>\n \t<li>Pendar, M.-R., C\u00e2ndido, S., P\u00e1scoa, J.C. (2023) &#8220;Optimization of painting efficiency applying unique techniques of high-voltage conductors and nitrotherm spray: Developing deep learning models using computational fluid dynamics dataset&#8221;, Physics of Fluids 35(7),075119\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0156571\" data-site=\"plum\" data-hide-when-empty=\"true\">Optimization of painting efficiency applying unique techniques of high-voltage conductors and nitrotherm spray: Developing deep learning models using computational fluid dynamics dataset<\/a><\/li>\n \t<li>C\u00e2ndido, S., P\u00e1scoa, J.C. (2023) &#8220;Dynamics of three-dimensional electrohydrodynamic instabilities on Taylor cone jets using a numerical approach&#8221;, Physics of Fluids 35(5),052110\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0151109\" data-site=\"plum\" data-hide-when-empty=\"true\">Dynamics of three-dimensional electrohydrodynamic instabilities on Taylor cone jets using a numerical approach<\/a><\/li>\n \t<li>Hamrang, A., Abdollahzadeh, M., Bilondi, A.M., (&#8230;), Rahgoshay, S.M., Pascoa, J.C. (2023) &#8220;Comparison of PEMFC performance with parallel serpentine and parallel serpentine-baffled flow fields under various operating and geometrical conditions; a parametric study&#8221;, International Journal of Hydrogen Energy 48(20), pp. 7442-7459\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijhydene.2022.11.122\" data-site=\"plum\" data-hide-when-empty=\"true\">Comparison of PEMFC performance with parallel serpentine and parallel serpentine-baffled flow fields under various operating and geometrical conditions; a parametric study<\/a><\/li>\n \t<li>Teixeira, O., P\u00e1scoa, J. (2023) &#8221; Catalytic wall effects for hypersonic nozzle flow in thermochemical non-equilibrium&#8221;, Acta Astronautica, 203, pp. 48-59\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.actaastro.2022.11.031\" data-site=\"plum\" data-hide-when-empty=\"true\">Catalytic wall effects for hypersonic nozzle flow in thermochemical non-equilibrium<\/a><\/li>\n \t<li>Benmoussa, A., P\u00e1scoa, J.C. (2023) &#8220;Enhancement of a cycloidal self-pitch vertical axis wind turbine performance through DBD plasma actuators at low tip speed ratio&#8221;, International Journal of Thermofluids, 17,100258\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijft.2022.100258\" data-site=\"plum\" data-hide-when-empty=\"true\">Enhancement of a cycloidal self-pitch vertical axis wind turbine performance through DBD plasma actuators at low tip speed ratio<\/a><\/li>\n \t<li>Rodrigues, F., Abdollahzadehsangroudi, M., Nunes-Pereira, J., P\u00e1scoa, J. (2023) &#8220;Recent Developments on Dielectric Barrier Discharge (DBD) Plasma Actuators for Icing Mitigation&#8221;, Actuators 12(1),5\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fact12010005\" data-site=\"plum\" data-hide-when-empty=\"true\">Recent Developments on Dielectric Barrier Discharge (DBD) Plasma Actuators for Icing Mitigation<\/a><\/li>\n \t<li>Moreira, M., Rodrigues, F., C\u00e2ndido, S., Santos, G., P\u00e1scoa, J. \u00a0(2023) &#8220;Development of a Background-Oriented Schlieren (BOS) System for Thermal Characterization of Flow Induced by Plasma Actuators&#8221;, Energies 16(1),540\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.3390%2Fen16010540\" data-site=\"plum\" data-hide-when-empty=\"true\">Development of a Background-Oriented Schlieren (BOS) System for Thermal Characterization of Flow Induced by Plasma Actuators<\/a><\/li>\n \t<li>Moradi Bilondi, A., Bagherighajari, F., Abdollahzadehsangroudi, M., Kermani, M.J., P\u00e1scoa, J.C. (2022) &#8220;The Role of Porous Carbon Inserts on the Performance of Polymer Electrolyte Membrane Fuel Cells: A Parametric Numerical Study&#8221;, Energy Technology 10(12),2200966\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Fente.202200966\" data-site=\"plum\" data-hide-when-empty=\"true\">The Role of Porous Carbon Inserts on the Performance of Polymer Electrolyte Membrane Fuel Cells: A Parametric Numerical Study<\/a><\/li>\n \t<li>Hamrang, A., Abdollahzadeh, M., Kermani, M. J., &amp; Rahgoshay, S. M. (2022). Numerical simulation of the PEM fuel cell performance enhancement by various blockage arrangement of the cathode serpentine gas flow channel outlets\/inlets. International Journal of Heat and Mass Transfer, 186, 122475.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatmasstransfer.2021.122475\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical simulation of the PEM fuel cell performance enhancement by various blockage arrangement of the cathode serpentine gas flow channel outlets\/inlets<\/a><\/li>\n \t<li>Bagherighajari, F., Abdollahzadehsangroudi, M., Esmaeilpour, M., Dolati, F., P\u00e1scoa, J. (2022) &#8220;Novel converging-diverging microchannel heat sink with porous fins for combined thermo-hydraulic performance&#8221;, Physics of Fluids 34(11),0118700\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0118700\" data-site=\"plum\" data-hide-when-empty=\"true\">Novel converging-diverging microchannel heat sink with porous fins for combined thermo-hydraulic performance<\/a><\/li>\n \t<li>Pendar, M.-R., Rodrigues, F., P\u00e1scoa, J.C., Lima, R. (2022) &#8220;Review of coating and curing processes: Evaluation in automotive industry&#8221;, Physics of Fluids, 34(10),101301.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0109376\" data-site=\"plum\" data-hide-when-empty=\"true\">Review of coating and curing processes: Evaluation in automotive industry<\/a><\/li>\n \t<li>Bagherighajari, F.; Ramiar, A.; Abdollahzadehsangroud, M.; Pascoa, J.; Oliveira, P. (2022) &#8220;Numerical simulation of the polymer electrolyte membrane fuel cells with intermediate blocked interdigitated flow fields&#8221;, International Journal of Energy Research, pp. 23.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Fer.8233\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical simulation of the polymer electrolyte membrane fuel cells with intermediate blocked interdigitated flow fields<\/a><\/li>\n \t<li>Pendar, R., P\u00e1scoa, J. (2022) &#8220;Numerical Investigation of Plasma Actuator Effects on Flow Control Over a Three-Dimensional Airfoil With a Sinusoidal Leading Edge&#8221;, Journal of Fluids Engineering, 144(8): 081208.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4053847\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical Investigation of Plasma Actuator Effects on Flow Control Over a Three-Dimensional Airfoil With a Sinusoidal Leading Edge<\/a><\/li>\n \t<li>M. Abdollahzadeh, F. Rodrigues, J. Nunes-Pereira, J.Pascoa, L. Pires (2022) &#8220;Parametric optimization of surface dielectric barrier discharge actuators for ice sensing application&#8221;, Sensors and Actuators: A. Physical, pp. 1-25.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.sna.2022.113391\" data-site=\"plum\" data-hide-when-empty=\"true\">Parametric optimization of surface dielectric barrier discharge actuators for ice sensing application<\/a><\/li>\n \t<li>Trancossi, M., Pascoa, J.C., Sharma, S. (2022) &#8220;Response to Comment on: A Critical Review on Heat and Mass Transfer Modelling of Viral Infection and Virion Evolution the Case of SARS-COV2&#8221;, Thermal Science, 26(2), pp. 1219-1228.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.2298%2Ftsci211227356t\" data-site=\"plum\" data-hide-when-empty=\"true\">Response to Comment on: A Critical Review on Heat and Mass Transfer Modelling of Viral Infection and Virion Evolution the Case of SARS-COV2<\/a><\/li>\n \t<li>J. Nunes-Pereira, F. Rodrigues, M. Abdollahzadeh, S. Lanceros-Mendez, J. P\u00e1scoa (2021) &#8220;Improved performance of polyimide Cirlex-based dielectric barrier discharge plasma actuators for flow control&#8221;,\u00a0 Polymers for Advanced Technologies, pp. 1-13.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Fpat.5600\" data-site=\"plum\" data-hide-when-empty=\"true\">Improved performance of polyimide Cirlex-based dielectric barrier discharge plasma actuators for flow control<\/a><\/li>\n \t<li>Pendar, R., P\u00e1scoa, J. (2021) &#8220;Numerical analysis of charged droplets size distribution in the electrostatic coating process: Effect of different operational conditions&#8221;,\u00a0 Physics of Fluids, 33, 033317-24.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0041021\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical analysis of charged droplets size distribution in the electrostatic coating process: Effect of different operational conditions<\/a><\/li>\n \t<li>M Rami, J P\u00e1scoa (2021) &#8220;Active control assessments towards optimizing the performance of a cycloidal rotor at hover&#8221;,\u00a0 Aerospace Science and Technology, 119, pp. 107141-16.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2021.107141\" data-site=\"plum\" data-hide-when-empty=\"true\">Active control assessments towards optimizing the performance of a cycloidal rotor at hover<\/a><\/li>\n \t<li>Trancossi M., Pascoa J., Mazzacurati S. (2021) &#8220;Sociotechnical design a review and future interdisciplinary perspectives involving thermodynamics in today societal contest&#8221;,\u00a0 International Communications in Heat and Mass Transfer, 128, pp. 105622-13.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.icheatmasstransfer.2021.105622\" data-site=\"plum\" data-hide-when-empty=\"true\">Sociotechnical design a review and future interdisciplinary perspectives involving thermodynamics in today societal contest<\/a><\/li>\n \t<li>M Rami, J P\u00e1scoa (2021) &#8220;Coupled Active Control Technique for Oscillating Blades in a Cycloidal Rotor Using CFD and ANN Analysis by Including 3D End Wall Effects&#8221;,\u00a0 ASCE&#8217;s Journal of Aerospace Engineering, 34(6), pp. 17.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1061%2F(asce)as.1943-5525.0001332\" data-site=\"plum\" data-hide-when-empty=\"true\">Coupled Active Control Technique for Oscillating Blades in a Cycloidal Rotor Using CFD and ANN Analysis by including 3D End Wall Effects<\/a><\/li>\n \t<li>A Benmoussa, J P\u00e1scoa (2021) &#8220;Performance improvement and start-up characteristics of a cyclorotor using multiple plasma actuators&#8221;, Meccanica, pp. 24\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1007%2Fs11012-021-01413-4\" data-site=\"plum\" data-hide-when-empty=\"true\">Performance improvement and start-up characteristics of a cyclorotor using multiple plasma actuators<\/a><\/li>\n \t<li>A Benmoussa, J P\u00e1scoa (2021) &#8220;Cycloidal rotor coupled with DBD plasma actuators for performance improvement&#8221;, Aerospace Science and Technology, pp. 14\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2020.106468\" data-site=\"plum\" data-hide-when-empty=\"true\">Cycloidal rotor coupled with DBD plasma actuators for performance improvement<\/a><\/li>\n \t<li>M. Trancossi, C. Carli, G. Cannistraro, J. P\u00e1scoa, S. Sharma (2021) &#8220;Could thermodynamics and heat and mass transfer research produce a fundamental step advance toward and significant reduction of SARS-COV-2 spread?&#8221;, International Journal of Heat and Mass Transfer, pp. 16 (<em>in press<\/em>)\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatmasstransfer.2021.120983\" data-site=\"plum\" data-hide-when-empty=\"true\">Could thermodynamics and heat and mass transfer research produce a fundamental step advance toward and significant reduction of SARS-COV-2 spread?<\/a><\/li>\n \t<li>M Rami, J P\u00e1scoa (2021) &#8220;Performance Optimization of Forward-Flight and Lift-Up Phases in a Cycloidal rotor Using an Active Control Mechanism&#8221;,\u00a0 ASCE&#8217;s Journal of Aerospace Engineering, 34(4), pp. 18.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1061%2F(asce)as.1943-5525.0001275\" data-site=\"plum\" data-hide-when-empty=\"true\">Performance Optimization of Forward-Flight and Lift-Up Phases in a Cycloidal Rotor Using an Active Control Mechanism<\/a><\/li>\n \t<li>Rodrigues, F., Abdollahzadeh, M., Pascoa, J., Oliveira, P. (2021) &#8220;An experimental study on segmented-encapsulated electrode dielectric-barrier-discharge plasma actuator for mapping ice formation on a surface: A conceptual analysis&#8221;, ASME Journal of Heat Transfer, 143(1): 011701, pp. 14.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4048252\" data-site=\"plum\" data-hide-when-empty=\"true\">An Experimental Study on Segmented-Encapsulated Electrode Dielectric-Barrier-Discharge Plasma Actuator for Mapping Ice Formation on a Surface: A Conceptual Analysis<\/a><\/li>\n \t<li>Abdollahzadeh, M., Rodrigues, F., Pascoa, J.\u00a0 (2020) &#8220;Simultaneous Ice Detection and Removal Based on Dielectric Barrier Discharge Actuators&#8221; Sensors and Actuators: A. Physical, 315, 112361\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.sna.2020.112361\" data-site=\"plum\" data-hide-when-empty=\"true\">Simultaneous ice detection and removal based on dielectric barrier discharge actuators<\/a><\/li>\n \t<li>Trancossi, M., Cannistraro, G., Pascoa, J. (2020) &#8220;Comments on \u201cNew insight into the definitions of the Bejan number\u201d&#8221;, International Communications in Heat and Mass Transfer, 10\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.icheatmasstransfer.2020.104997\" data-site=\"plum\" data-hide-when-empty=\"true\">Comments on \u201cNew insight into the definitions of the Bejan number\u201d<\/a><\/li>\n \t<li>Pendar, R., P\u00e1scoa, J. (2020) &#8220;Numerical modeling of the distribution of virus carrying saliva droplets during sneeze and cough&#8221;, Physics of Fluids, 32, pp. 083305.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F5.0018432\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical modeling of the distribution of virus carrying saliva droplets during sneeze and cough<\/a><\/li>\n \t<li>Pendar, R., P\u00e1scoa, J. (2020) &#8220;Atomization and Spray Characteristics around an ERBS Using Various Operational Models and Conditions: Numerical Investigation&#8221;, International Journal of Heat and Mass Transfer, 161, pp. 120243.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatmasstransfer.2020.120243\" data-site=\"plum\" data-hide-when-empty=\"true\">Atomization and spray characteristics around an ERBS using various operational models and conditions: numerical investigation<\/a><\/li>\n \t<li>Amanifard, N., Abdollahzadeh, M, Moayedi, H., Pascoa, J. (2020) &#8220;An explicit CFD model for the DBD plasma actuators using wall-jet similarity Approach&#8221;, Journal of Electrostatics 107, pp. 103497.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.elstat.2020.103497\" data-site=\"plum\" data-hide-when-empty=\"true\">An explicit CFD model for the DBD plasma actuators using wall-jet similarity approach<\/a><\/li>\n \t<li>Trancossi, M., Cannistraro, G., Pascoa, J. (2020) &#8220;Thermoelectric and solar heat pump use toward self sufficient buildings: The case of a container house&#8221; Thermal Science and Engineering Progress, vol. 18, pp. 100509.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.tsep.2020.100509\" data-site=\"plum\" data-hide-when-empty=\"true\">Thermoelectric and solar heat pump use toward self sufficient buildings: The case of a container house<\/a><\/li>\n \t<li>Rodrigues, F., P\u00e1scoa, J. (2020) &#8220;Implementation of stair-shaped\u00a0 dielectric layers in micro and macro plasma actuators for increased efficiency and lifetime&#8221;, Journal of Fluids Engineering (doi.org\/10.1115\/1.4047800)\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4047800\" data-site=\"plum\" data-hide-when-empty=\"true\">Implementation of Stair-Shaped Dielectric Layers in Micro and Macro Plasma Actuators for Increased Efficiency and Lifetime<\/a><\/li>\n \t<li>Pendar, M. and Pascoa, J. (2020) &#8220;Numerical Investigation of Electrostatic Spray Painting Transfer Processes for Vehicle Coating,&#8221; SAE International Journal Advances &amp; Current Practice in Mobility 2(2):747-754.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.4271%2F2019-01-1856\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical Investigation of Electrostatic Spray Painting Transfer Processes for Vehicle Coating<\/a><\/li>\n \t<li>Rami, M., Pascoa, J. (2020) &#8220;Numerical Analysis of a Cycloidal Rotor under Diverse Operating Conditions and Altitudes,&#8221; SAE International Journal Advances &amp; Current Practice in Mobility 2(2):792-802.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.4271%2F2019-01-1872\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical Analysis of a Cycloidal Rotor under Diverse Operating Conditions and Altitudes<\/a><\/li>\n \t<li>Teixeira, O.\u00a0 Pascoa, J. (2020) &#8220;Hypersonic Flow Simulation towards Space Propulsion Geometries,&#8221; SAE International Journal Advances &amp; Current Practice in Mobility 2(2):803-810.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.4271%2F2019-01-1873\" data-site=\"plum\" data-hide-when-empty=\"true\">Hypersonic Flow Simulation towards Space Propulsion Geometries<\/a><\/li>\n \t<li>Trancossi, M., Pascoa, J. (2019) &#8220;Diffusive Bejan number and second law of thermodynamics toward a new dimensionless formulation of fluid dynamics laws&#8221;, Thermal Science, 23 (6) Part B, 4005-4022.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.2298%2Ftsci190726340t\" data-site=\"plum\" data-hide-when-empty=\"true\">Diffusive bejan number and second law of thermodynamics toward a new dimensionless formulation of fluid dynamics laws<\/a><\/li>\n \t<li>Pendar, M.-R., P\u00e1scoa, J.C. (2019) &#8220;Numerical modeling of electrostatic spray painting transfer processes in rotary bell cup for automotive painting&#8221;\u00a0 International Journal of Heat and Fluid Flow, 80, 108499\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatfluidflow.2019.108499\" data-site=\"plum\">Numerical modeling of electrostatic spray painting transfer processes in rotary bell cup for automotive painting<\/a><\/li>\n \t<li>Trancossi, M., Pascoa, J.\u00a0 (2019) &#8220;The influence of convective exchanges on coand\u00e3 effect&#8221;, INCAS Bulletin, 11(4), pp. 191-202.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.13111%2F2066-8201.2019.11.4.17\" data-site=\"plum\">The influence of convective exchanges on coand\u00e3 effect<\/a><\/li>\n \t<li>Habibnia, M., Pascoa, J. (2019) &#8220;ANN assisted flow modeling and analysis for a cyclorotor in ground effect&#8221;, Aerospace Science and Technology, Vol 95, pp. 1-13.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2019.105495\" data-site=\"plum\">ANN assisted flow modeling and analysis for a cyclorotor in ground effect<\/a><\/li>\n \t<li>Trancossi, M., Pascoa, J. (2019) &#8220;Modeling fluid dynamics and aerodynamics by second law and Bejan number (Part 1 &#8211; theory)&#8221;, INCAS Bulletin, 11(3), pp. 169-180.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.13111%2F2066-8201.2019.11.3.15\" data-site=\"plum\">Modeling fluid dynamics and aerodynamics by second law and Bejan number (Part 1 &#8211; theory)<\/a><\/li>\n \t<li>Rodrigues, F., Mushyam, A., Pascoa, J.C., Trancossi, M. (2019) &#8220;A new plasma actuator configuration for improved efficiency: The stair shaped dielectric barrier discharge (SSDBD) actuator,&#8221;Journal of Physics D: Applied Physics, DOI: 10.1088\/1361-6463\/ab2584.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1088%2F1361-6463%2Fab2584\" data-site=\"plum\">A new plasma actuator configuration for improved efficiency: The stair shaped dielectric barrier discharge (SSDBD) actuator<\/a><\/li>\n \t<li>Mushyam, A., Rodrigues, F., Pascoa, J.C. (2019) &#8220;A plasma-fluid model for EHD flow in DBD actuators and experimental validation,&#8221; International Journal for Numerical Methods in Fluids, DOI: 10.1002\/fld.4714.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Ffld.4714\">A plasma-fluid model for EHD flow in DBD actuators and experimental validation<\/a><\/li>\n \t<li>K. Singh and J. C. P\u00e1scoa (2019) &#8220;Numerical Modeling of Stall and Poststall Events of a Single Pitching Blade of a Cycloidal Rotor,&#8221; Journal of Fluids Engineering, vol. 141, no. 1, pp. 011103-011103-16.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4040302\">Numerical Modeling of Stall and Poststall Events of a Single Pitching Blade of a Cycloidal Rotor<\/a><\/li>\n \t<li>Abdollahzadeh, M., Sedighi, A. A., &amp; Esmailpour, M. (2018). Stagnation point flow of nanofluids towards stretching sheet through a porous medium with heat generation. Journal of Nanofluids, 7(1), 149-155.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1166%2Fjon.2018.1431\" data-site=\"plum\" data-hide-when-empty=\"true\">Stagnation point flow of nanofluids towards stretching sheet through a porous medium with heat generation<\/a><\/li>\n \t<li>Abdollahzadeh, M., Sedighi, A. A., &amp; Esmaeilpour, M. (2018). Boundary layer and heat transfer analysis in liquid film of nanofluid over an unsteady stretching sheet. Journal of Nanofluids, 7(2), 371-377.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1166%2Fjon.2018.1442\" data-site=\"plum\" data-hide-when-empty=\"true\">Boundary layer and heat transfer analysis in liquid film of nanofluid over an unsteady stretching sheet<\/a><\/li>\n \t<li>Sangtabi, A. R., Ramiar, A., Ranjbar, A. A., Abdollahzadeh, M., &amp; Kianifar, A. (2018). Influence of repetitive laser pulse energy depositions on supersonic flow over a sphere, cone and oblate spheroid. Aerospace Science and Technology, 76, 72-81.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2018.02.005\" data-site=\"plum\" data-hide-when-empty=\"true\">Influence of repetitive laser pulse energy depositions on supersonic flow over a sphere, cone and oblate spheroid<\/a><\/li>\n \t<li>Havaej, P., Kermani, M. J., Abdollahzadeh, M., Heidary, H., &amp; Moradi, A. (2018). A numerical modeling study on the influence of catalyst loading distribution on the performance of Polymer Electrolyte Membrane Fuel Cell. International journal of hydrogen energy, 43(21), 10031-10047\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijhydene.2018.04.063\" data-site=\"plum\" data-hide-when-empty=\"true\">A numerical modeling study on the influence of catalyst loading distribution on the performance of Polymer Electrolyte Membrane Fuel Cell<\/a><\/li>\n \t<li>A. Ghanbarian, M.J. Kermani, J. Scholta, M. Abdollahzadeh (2018), Polymer electrolyte membrane fuel cell flow field design criteria \u2013 Application to parallel serpentine flow patterns,Energy conversion and management 166 ,281-296\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.enconman.2018.04.018\" data-site=\"plum\" data-hide-when-empty=\"true\">Polymer electrolyte membrane fuel cell flow field design criteria \u2013 Application to parallel serpentine flow patterns<\/a><\/li>\n \t<li>A. Moradi Bilondi, M. Abdollahzadeh, M.J. Kermani, H. Heidary, P. Havaej (2018), Numerical study of anode side CO contamination effects on PEM fuel cell performance; and mitigation methods,Energy conversion and management 177, 519-534.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.enconman.2018.09.076\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical study of anode side CO contamination effects on PEM fuel cell performance; and mitigation methods<\/a><\/li>\n \t<li>Trancossi, M., Cannistraro, M., Pascoa, J.<span style=\"font-size: 1rem;\">\u00a0(2018) &#8220;Can constructal law and exergy analysis produce a robust design method that couples with industry 4.0 paradigms? The case of a container house<\/span><span style=\"font-size: 1rem;\">&#8220;, Mathematical Modelling of Engineering Problems, 5(4), pp. 303-312.<\/span>\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.18280%2Fmmep.050405\">Can constructal law and exergy analysis produce a robust design method that couples with industry 4.0 paradigms? The case of a container house<\/a><\/li>\n \t<li>\u00a0M. Trancossi, J. C. P\u00e1scoa (2018) &#8220;A new dimensionless approach to general fluid dynamics problems that accounts both the first and the second law of thermodynamics, Mathematical Modelling of Engineering Problems, 5(4), pp. 331-340\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.18280%2Fmmep.050409\">A new dimensionless approach to general fluid dynamics problems that accounts both the first and the second law of thermodynamics<\/a><\/li>\n \t<li>M. Trancossi, J. C. P\u00e1scoa (2018) &#8220;Design of ventilated cross flow heat sinks, Modelling, Measurement and Control C, 79(3), pp. 90-97\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.18280%2Fmmc-c.790305\">Design of ventilated cross flow heat sinks<\/a><\/li>\n \t<li>F. Rodrigues, JC P\u00e1scoa, M. Trancossi (2018) &#8220;Experimental analysis of DBD plasma actuators thermal characteristics under external flow influence<span style=\"font-size: 1rem;\">&#8220;,\u00a0<\/span><em>Journal of Heat Transfer<\/em>, ASME, Vol 140 (10), pp 20\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4040152\">Experimental Analysis of Dielectric Barrier Discharge Plasma Actuators Thermal Characteristics under External Flow Influence<\/a><\/li>\n \t<li>M Abdollahzadeh, JC P\u00e1scoa, P Oliveira (2018) &#8220;Comparison of DBD Plasma Actuators Flow Control Authority in Different Modes of Actuation&#8221;,\u00a0Aerospace Science and Technology, Elsevier, doi: pp 20\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2018.04.013\">Comparison of DBD plasma actuators flow control authority in different modes of actuation<\/a><\/li>\n \t<li>L Gagnon, M Morandini, G Quaranta, P Masarati, C Xisto, J P\u00e1scoa (2018) &#8220;Aeroelastic Analysis of a Cycloidal Rotor Under Various Operating Conditions&#8221;, <em>Journal of Aircraft<\/em>, AIAA, doi:10.2514\/1.C034005\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.2514%2F1.c034005\">Aeroelastic analysis of a cycloidal rotor under various operating conditions<\/a><\/li>\n \t<li>Zehtabiyan-Rezaie, N., Arefian, A., Kermani, M. J., Noughabi, A. K., &amp; Abdollahzadeh, M. (2017). Effect of flow field with converging and diverging channels on proton exchange membrane fuel cell performance. Energy Conversion and Management, 152, 31-44.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.enconman.2017.09.009\" data-site=\"plum\" data-hide-when-empty=\"true\">Effect of flow field with converging and diverging channels on proton exchange membrane fuel cell performance<\/a><\/li>\n \t<li>F Rodrigues, J P\u00e1scoa, M Trancossi (2017) &#8220;Heat Generation Mechanisms of DBD Plasma Actuators&#8221;, Experimental Thermal and Fluid Science, 12.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.expthermflusci.2017.09.005\">Heat generation mechanisms of DBD plasma actuators<\/a><\/li>\n \t<li>M Abdollahzadeh, M Esmaeilpour, R Vizinho, A Younesi, J Pascoa (2017) &#8220;Assessment of RANS turbulence models for numerical study of laminar-turbulent transition in convection heat transfer&#8221;, <em>International Journal of Heat and Mass Transfer<\/em> 115.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatmasstransfer.2017.08.114\">Assessment of RANS turbulence models for numerical study of laminar-turbulent transition in convection heat transfer<\/a><\/li>\n \t<li>Ramiar, A., Mahmoudi, A. H., Esmaili, Q., &amp; Abdollahzadeh, M. (2016). Influence of cathode flow pulsation on performance of proton exchange membrane fuel cell with interdigitated gas distributors. Energy, 94, 206-217.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.energy.2015.10.110\" data-site=\"plum\" data-hide-when-empty=\"true\">Influence of cathode flow pulsation on performance of proton exchange membrane fuel cell with interdigitated gas distributors<\/a><\/li>\n \t<li>M.\u00a0Abdollahzadeh, Jos\u00e9 P\u00e1scoa, Paulo Jorge Oliveira (2016) &#8220;Implementation of the Classical Plasma-Fluid Model for Simulation of the Dielectric Barrier Discharge (DBD) Actuators in\u00a0OpenFOAM&#8221;, Volume 128,\u00a0<em>Computers and Fluids<\/em>, pp. 77\u201390.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.compfluid.2016.01.012\">Implementation of the classical plasma\u2013fluid model for simulation of dielectric barrier discharge (DBD) actuators in OpenFOAM<\/a><\/li>\n \t<li>Leger J. A., P\u00e1scoa J. C.,\u00a0Xisto C. M., (2016) \u201cAerodynamic optimization\u00a0of cyclorotors\u201d\u00a0<em>Aircraft Engineering and Aerospace Technology<\/em>, Vol. 88, No. 2, pp.232 &#8211; 245.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1108%2Faeat-02-2015-0051\">Aerodynamic optimization of cyclorotors<\/a><\/li>\n \t<li>Trancossi, M., Mohammedalamin, O., Pascoa, JC., Rodrigues, F. (2016) \u201cThermodynamic Analysis and Preliminary Design of the Cooling System of a Pulsejet for Aeronautic Propulsion\u201d,\u00a0<em>International Journal of Heat and Technology<\/em>, Vol. 34, pp. 528-534.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.18280%2Fijht.34s247\">Thermodynamic analysis and preliminary design of the cooling system of a pulsejet for aeronautic propulsion<\/a><\/li>\n \t<li>Trancossi, M., Pascoa, JC., Xisto, CM. (2016) \u201cDesign of an Innovative Off Road Hybrid Vehicle by Energy Efficiency Criteria\u201d <em>International Journal of Heat and Technology<\/em>, Vol. 34, pp. 387-395.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.18280%2Fijht.34s228\">Design of an innovative off road hybrid vehicle by energy efficiency criteria<\/a><\/li>\n \t<li>Xisto C. M., P\u00e1scoa J. C.,\u00a0Trancossi M., (2016) \u201cGeometrical Parameters Influencing the Aerodynamic Efficiency of a Small-Scale Self-Pitch High-Solidity VAWT\u201d\u00a0<em>Journal of Solar Energy Engineering: Including Wind Energy and Building Energy Conservation<\/em>, Vol. 138, No. 3, pp. 8.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4032794\">Geometrical Parameters Influencing the Aerodynamic Efficiency of a Small-Scale Self-Pitch High-Solidity VAWT<\/a><\/li>\n \t<li>Morgado, J.,\u00a0Vizinho R., Silvestre, M. A. R. and P\u00e1scoa, J. C. (2016) \u201cXFOIL vs CFD performance predictions for high lift low Reynolds number airfoils\u201d\u00a0<em>Aerospace Science and Technology<\/em>, Vol. 52, pp. 207-214.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2016.02.031\">XFOIL vs CFD performance predictions for high lift low Reynolds number airfoils<\/a><\/li>\n \t<li>Trancossi M., Stewart J., Dumas A.,\u00a0Madonia M.,\u00a0Pascoa J. (2016) \u201cConstructal Design of an Entropic Wall With Circulating Water Inside\u201d\u00a0<em>Journal of Heat Transfer<\/em>, Vol. 138 (8), pp. 9.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1115%2F1.4033346\">Constructal Design of an Entropic Wall with Circulating Water Inside<\/a><\/li>\n \t<li>Xisto C.,\u00a0Leger J., P\u00e1scoa J.\u00a0et al. (2016) &#8220;Parametric Analysis of a Large-scale Cycloidal Rotor in Hovering Conditions&#8221;.\u00a0<em>ASCEs<\/em>\u00a0Journal of Aerospace Engineering, in press, DOI: 10.1061\/(ASCE)AS.1943-5525.0000658.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1061%2F(asce)as.1943-5525.0000658\">Parametric Analysis of a Large-Scale Cycloidal Rotor in Hovering Conditions<\/a><\/li>\n \t<li>Trancossi M,\u00a0Madonia M., Dumas A.,\u00a0Angeli D., Bingham C., Das S.,\u00a0Grimaccia F., P\u00e1scoa, J. C. et al (2016) \u201cA new aircraft architecture based on the ACHEON\u00a0Coanda effect nozzle: flight model and energy evaluation\u201d\u00a0<em>European Transport Research Review<\/em>, Vol. 8, pp. 1-21.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1007%2Fs12544-016-0198-4\">A new aircraft architecture based on the ACHEON Coanda effect nozzle: flight model and energy evaluation<\/a><\/li>\n \t<li>Morgado, J., Silvestre, M. A. R. and P\u00e1scoa, J. C. (2016) \u201cA Comparison of Post-Stall Models Extended for Propeller Performance Prediction\u201d\u00a0<em>Aircraft Engineering and Aerospace Technology<\/em>, Vol. 88, No. 4, pp. 12.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1108%2Faeat-07-2014-0119\">A comparison of post-stall models extended for propeller performance prediction<\/a><\/li>\n \t<li>Shyam S. Das, Jose C. P\u00e1scoa, M.\u00a0Trancossi, A. Dumas (2016) \u201cCFD study on a Novel Propulsion System: ACHEON and Its Integration with an Unmanned aerial Vehicle (UAV)\u201d,\u00a0<em>ASCEs Journal of Aerospace Engineering<\/em>, Vol. 29, No. 1, 04015015-1 &#8211; 04015015-16.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1061%2F(asce)as.1943-5525.0000498\">Computational fluid dynamic study on a novel propulsive system: ACHEON and its integration with an Unmanned Aerial Vehicle (UAV)<\/a><\/li>\n \t<li>A\u00a0Baptista, F Santos, J P\u00e1scoa, N\u00a0S\u00e4ndig (2016) \u201cProject Management Methodologies as Main Tool for Current Challenges in Global Economy Driving Historical Changes\u201d,\u00a0<em>Journal of Advanced Management Science<\/em>, Vol 4 (2) pp. 1-7.<\/li>\n \t<li>Abdollahzadeh, M., &amp; Esmaeilpour, M. (2015). Enhancement of phase change material (PCM) based latent heat storage system with nano fluid and wavy surface. International journal of heat and mass transfer, 80, 376-385.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ijheatmasstransfer.2014.09.007\" data-site=\"plum\" data-hide-when-empty=\"true\">Enhancement of phase change material (PCM) based latent heat storage system with nano fluid and wavy surface<\/a><\/li>\n \t<li>Vizinho, R., P\u00e1scoa, J., Silvestre, M. (2015) \u201cTurbulent transition modeling through mechanical considerations\u201d,\u00a0<em>Applied Mathematics and Computation<\/em>, Vol 269, pp. 308-325.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.amc.2015.07.080\">Turbulent transition modeling through mechanical considerations<\/a><\/li>\n \t<li>Vizinho, R.,\u00a0Morgado, J., P\u00e1scoa, J., Silvestre, M. (2015) \u201cAnalysis of transitional flow in 3D geometries using a novel phenomenological model\u201d,\u00a0<em>Aerospace Science and Technology<\/em>, Vol. 45, pp. 431-441.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2015.06.018\">Analysis of transitional flow in 3D geometries using a novel phenomenological model<\/a><\/li>\n \t<li>Baptistaa, AA,\u00a0Charrua-Santos, F, P\u00e1scoa, JC (2015) \u201cPrevention and Risk Management in RTD European Projects Developed by University-Company&#8217;s Consortiums\u201d,\u00a0<em>Procedia Computer Science<\/em>, Vol. 64, pp. 403-408.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.procs.2015.08.527\">Prevention and Risk Management in RTD European Projects Developed by University-Company&#8217;s Consortiums<\/a><\/li>\n \t<li>Morgado, J.,\u00a0Abdollahzadeh, M., Silvestre, M.A.R., P\u00e1scoa, J.C (2015) \u201cHigh altitude propeller design and analysis\u201d,\u00a0<em>Aerospace Science and Technology<\/em>, Vol. 45, pp. 398-407.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1108%2Faeat-07-2014-0119.r1\">High altitude propeller design and analysis<\/a><\/li>\n \t<li>Xisto, C.M., P\u00e1scoa, J.C., Oliveira, P.J (2015) \u201cNumerical analysis of real gas MHD flow on two-dimensional self-field MPD thrusters\u201d,\u00a0<em>Acta Astronautica<\/em>, Vol. 112, pp. 89-101.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.actaastro.2015.03.009\">Numerical analysis of real gas MHD flow on two-dimensional self-field MPD thrusters<\/a><\/li>\n \t<li>Silvestre, M.A.R.,\u00a0Morgado, J., Alves, P., Santos, P.,\u00a0Gamboa, P., P\u00e1scoa, J.C. (2015) \u201cPropeller performance measurements at low Reynolds numbers\u201d,\u00a0<em>International Journal of Mechanics<\/em>, Vol 9, pp. 154-166.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?elsevier_id=2-s2.0-84926504778\">Propeller performance measurements at low Reynolds numbers<\/a><\/li>\n \t<li>Ilieva, G., P\u00e1scoa, J., Dumas, A.,\u00a0Trancossi, M. (2015) Unsteady interaction effects between an airship and its air-jet propulsion system,\u00a0<em>Advanced Structured Materials<\/em>, Vol. 44, pp. 127-143.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?elsevier_id=2-s2.0-84914680307\">Unsteady interaction effects between an airship and its air-jet propulsion system<\/a><\/li>\n \t<li>Leger J. A., P\u00e1scoa J. C.,\u00a0Xisto C. M., (2015) &#8220;Analytical Modeling of a\u00a0Cyclorotor in Hovering State&#8221;,\u00a0<em>Proceedings of the Institution of Mechanical Engineers Part G: Journal of Aerospace Engineering<\/em>, Vol. 229, No. 12, pp. 2163-2177.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1177%2F0954410015569285\">Analytical modeling of a cyclorotor in hovering state<\/a><\/li>\n \t<li>M.\u00a0Abdollahzadeh, Jos\u00e9 P\u00e1scoa, Paulo Jorge Oliveira, F. Rodrigues (2015) &#8220;Numerical Design and Analysis of a Multi-DBD Actuator Configuration for the Experimental Testing of ACHEON Nozzle Model&#8221;,\u00a0<em>Aerospace Science and Technology<\/em>, Vol. 41, pp. 259\u2013273.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1063%2F1.3580332\">Numerical design and analysis of a multi-DBD actuator configuration for the experimental testing of ACHEON nozzle model<\/a><\/li>\n \t<li>J.\u00a0Morgado, M. A R. Silvestre, J. C. P\u00e1scoa (2015), &#8220;Validation of new formulations for propeller analysis&#8221;, AIAA\u00a0<em>Journal of Propulsion and Power<\/em>, Vol. 31 (1), pp. 467-477.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.2514%2F1.b35240\">Validation of new formulations for propeller analysis<\/a><\/li>\n \t<li>AAR\u00a0Baptista, MJM Silva, CM\u00a0Cabrita, FB Santos, JC\u00a0Pascoa (2014) \u201cTechnology Transfer as a Driver of Cooperation and Communication in a New Knowledge Management Methodology\u201d,\u00a0<em>Lecture Notes on Information Theory,<\/em>\u00a0Vol 2 (3), pp. 259-265.<\/li>\n \t<li>Xisto, C.M., P\u00e1scoa, J.C., Oliveira, P.J. (2014) &#8220;A pressure-based high resolution numerical method for resistive MHD&#8221;\u00a0<em>Journal of Computational Physics<\/em>, 275, pp. 323-345.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.jcp.2014.07.009\">A pressure-based high resolution numerical method for resistive MHD<\/a><\/li>\n \t<li>Das, S.,\u00a0Abdollahzadeh, M.,\u00a0Pascoa, J., Dumas, A.,\u00a0Trancossi, M. (2014) &#8220;Numerical modeling of\u00a0coanda effect in a novel propulsive system&#8221;,\u00a0<em>International Journal of Multiphysics<\/em>, 8 (2), pp. 181-201.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1260%2F1750-9548.8.2.181\">Numerical modeling of coanda effect in a novel propulsive system<\/a><\/li>\n \t<li>M\u00a0Trancossi, A Dumas, SS Das, J\u00a0Pascoa (2014) \u201cDesign methods of\u00a0Coanda effect nozzle with two streams\u201d,\u00a0<em>INCAS Bulletin<\/em>, Vol. 6 (1), pp.\u00a0\u00a083-95.<\/li>\n \t<li>A Dumas, M\u00a0Subhash, M\u00a0Trancossi, J P\u00e1scoa Marques (2014) \u201cThe Influence of Surface Temperature on\u00a0Coanda Effect\u201d,\u00a0<em>Energy Procedia<\/em>, Vol. 45, pp. 626-634.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.egypro.2014.01.067\">The Influence of Surface Temperature on Coanda Effect<\/a><\/li>\n \t<li>Abdollahzadeh, M.,\u00a0Pascoa, J.C.,\u00a0Ranjbar, A.A.,\u00a0Esmaili, Q. (2014) &#8220;Analysis of PEM (Polymer Electrolyte Membrane) fuel cell cathode two-dimensional modeling&#8221;,\u00a0<em>Energy<\/em>, Vol. 68, pp. 478-494.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.energy.2014.01.075\">Analysis of PEM (Polymer Electrolyte Membrane) fuel cell cathode two-dimensional modeling<\/a><\/li>\n \t<li>Abdollahzadeh, M., P\u00e1scoa, J.C., Oliveira, P.J. (2014) &#8220;Two-dimensional numerical modeling of interaction of micro-shock wave generated by nanosecond plasma actuators and transonic flow&#8221;\u00a0<em>Journal of Computational and Applied Mathematics<\/em>, Vol. 270, pp. 401-416.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.cam.2013.12.030\">Two-dimensional numerical modeling of interaction of micro-shock wave generated by nanosecond plasma actuators and transonic flow<\/a><\/li>\n \t<li>Abdollahzadeh, M., P\u00e1scoa, J.C., Oliveira, P.J. (2014) &#8220;Modified split-potential model for modeling the effect of DBD plasma actuators in high altitude flow control&#8221;,\u00a0<em>Current Applied Physics<\/em>, Vol. 14 (8), pp. 1160-1170.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.cap.2014.05.016\">Modified split-potential model for modeling the effect of DBD plasma actuators in high altitude flow control<\/a><\/li>\n \t<li>Ilieva, G., P\u00e1scoa, J., Dumas, A.,\u00a0Trancossi, M. (2014) &#8220;MAAT &#8211; Promising innovative design and green propulsive concept for future airship&#8217;s transport&#8221;,\u00a0<em>Aerospace Science and Technology<\/em>, Vol. 35 (1), pp. 1-14.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.ast.2014.01.014\">MAAT \u2013 Promising innovative design and green propulsive concept for future airship&#8217;s transport<\/a><\/li>\n \t<li>Vizinho, R.,\u00a0Pascoa, J., and Silvestre, M., (2013) &#8220;High Altitude Transitional Flow Computation for a Propulsion System Nacelle of MAAT Airship,&#8221;\u00a0<em>SAE International Journal Aerospace<\/em>, Vol. 6, No. 2, pp.714-720.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.4271%2F2013-01-2268\">High Altitude Transitional Flow Computation for a Propulsion System Nacelle of MAAT Airship<\/a><\/li>\n \t<li>Esmaili, Q., Ranjbar, A. A., &amp; Abdollahzadeh, M. (2013). Numerical simulation of a direct methanol fuel cell through a 1D+ 1D approach. International journal of green energy, 10(2), 190-204.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1080%2F15435075.2011.647165\" data-site=\"plum\" data-hide-when-empty=\"true\">Numerical simulation of a direct methanol fuel cell through a 1D+1D approach<\/a><\/li>\n \t<li>Xisto C.M., P\u00e1scoa J. C. , Oliveira P.J. (2013), &#8220;A pressure-based method with AUSM-type fluxes for MHD flows at arbitrary Mach numbers&#8221;,\u00a0<em>International Journal for Numerical Methods in Fluids<\/em>, Vol. 72, No. 11, pp. 1165\u20131182.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Ffld.3781\">A pressure-based method with AUSM-type fluxes for MHD flows at arbitrary Mach numbers<\/a><\/li>\n \t<li>Trancossi M., Dumas A.,\u00a0Madonia M., P\u00e1scoa J.,\u00a0Vucinic D. (2012), \u201cFire-safe airship system design\u201d,\u00a0<em>SAE International Journal of Aerospace<\/em>, Vol. 5, No. 1: pp. 11-21.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.4271%2F2012-01-1512\">Fire-safe Airship System Design<\/a><\/li>\n \t<li>P\u00e1scoa J. C., Mendes N. M.,\u00a0Br\u00f3jo F. M., Santos F. S.,\u00a0Fael P. O. (2012) &#8220;An innovative experimental on-road testing method and its demonstration on a prototype vehicle&#8221;,\u00a0<em>Journal of Mechanical Science and Technology<\/em>, Vol. 26, No. 6, pp 1663-1670.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1007%2Fs12206-012-0413-8\">An innovative experimental on-road testing method and its demonstration on a prototype vehicle<\/a><\/li>\n \t<li>P\u00e1scoa J. C., Silva F. J.,\u00a0Pinheiro J. S., Martins D. J. (2012), &#8220;A new approach for predicting PAT-pumps operating point from direct pumping mode characteristics&#8221;,\u00a0<em>Journal of Scientific &amp; Industrial Research<\/em>, Vol. 71, pp. 144-148.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?elsevier_id=2-s2.0-84856761351\">A new approach for predicting PAT-pumps operating point from direct pumping mode characteristics<\/a><\/li>\n \t<li>Ilieva G., P\u00e1scoa J.C., Dumas A.,\u00a0Trancossi M. (2012), \u201cA critical review of propulsion concepts for modern airships\u201d,\u00a0<em>Central European Journal of Engineering<\/em>, Vol. 2, No. 2, pp 189-200.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.2478%2Fs13531-011-0070-1\">A critical review of propulsion concepts for modern airships<\/a><\/li>\n \t<li>Xisto C.M., P\u00e1scoa J. C. , Oliveira P.J.,\u00a0Nicolini D.A. (2011), &#8220;An hybrid pressure-density based algorithm for the Euler equations at all Mach number regimes&#8221;,\u00a0<em>International Journal for Numerical Methods in Fluids,<\/em>\u00a0Vol. 70, No. 8, pp. 961\u2013976.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1002%2Ffld.2722\">A hybrid pressure-density-based algorithm for the Euler equations at all Mach number regimes<\/a><\/li>\n \t<li>P\u00e1scoa J. C. (2011) &#8220;Benchmark test cases for CFD in mechanical engineering&#8221;,\u00a0<em>Central European Journal of Engineering<\/em>, Vol 1(4), pp. 333. (Editorial).\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.2478%2Fs13531-011-0046-1\">Benchmark test cases for CFD in mechanical engineering<\/a><\/li>\n \t<li>P\u00e1scoa J. C., Silva F. J.,\u00a0Pinheiro J. S., Martins D. J. (2010), &#8220;Accuracy details in realistic CFD modeling of an industrial centrifugal pump in direct and reverse modes&#8221;,\u00a0<em>Journal of Thermal Science<\/em>, Vol. 19, No. 6, pp. 491-499.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1007%2Fs11630-010-0414-9\">Accuracy details in realistic CFD modeling of an industrial centrifugal pump in direct and reverse modes<\/a><\/li>\n \t<li>P\u00e1scoa J. C.,\u00a0Xisto C. M.,\u00a0G\u00f6ttlich E. (2010), &#8220;Performance assessment limits in transonic 3D turbine stage blade rows using a mixing-plane approach&#8221;,\u00a0<em>Journal of Mechanical Science and Technology<\/em>, Vol. 24, No. 10, pp. 2035-2042.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1007%2Fs12206-010-0713-9\">Performance assessment limits in transonic 3D turbine stage blade rows using a mixing-plane approach<\/a><\/li>\n \t<li>P\u00e1scoa J. C., Mendes A. C.,\u00a0Gato L.M.C. (2009), &#8220;A fast iterative inverse method for turbomachinery blade design&#8221;,\u00a0<em>Mechanics Research Communications<\/em>, Vol. 36, No. 5, pp. 537-546.\n\n<a class=\"plumx-details\" href=\"https:\/\/plu.mx\/plum\/a\/?doi=10.1016%2Fj.mechrescom.2009.01.008\">A fast iterative inverse method for turbomachinery blade design<\/a><\/li>\n \t<li>P\u00e1scoa J. C., Luff J. K.,\u00a0McGuirk J. J., Mendes A. C., (2006), \u201cOn Accurate Numerical Modeling of 3D Turbulent Flow Through a DCA Compressor Cascade and its Experimental Validation\u201d,\u00a0<em>International Journal of Dynamics of Fluids<\/em>, Vol. 2(1), pp. 1\u201318.<\/li>\n \t<li>P\u00e1scoa J. C., Mendes A. C.,\u00a0Gato L.M.C., Elder R., (2004), \u201cAerodynamic Design of Turbomachinery Cascades Using an Enhanced Time-marching Finite Volume Method\u201d,\u00a0<em>Journal of Computer Modeling in Engineering &amp; Sciences<\/em>, Vol. 6(6), pp. 537\u2013546.<\/li>\n \t<li>P\u00e1scoa J. C., Mendes A. C.,\u00a0Gato L. C., (2004), \u201cAn Inverse Method for Turbomachinery Cascades of Blades \u2013 Investigation of the existence and uniqueness of solution\u201d,\u00a0<em>WIT Transactions on Engineering Sciences<\/em>, Vol. 40, pp. 312-322.<\/li>\n \t<li>P\u00e1scoa J. C., Mendes A. C.,\u00a0Gato L. C., (2002), \u201cAn Efficient Finite Volume Scheme with Improved Artificial Viscosity Suitable for Transonic flow Calculations\u201d,\u00a0<em>WIT Transactions on Engineering Sciences<\/em>, Vol. 32, pp. 505-514.<\/li>\n \t<li>Mendes A. C., P\u00e1scoa J. C.,\u00a0Kolodziej J. A., (1998), \u201cAn Alternative Approach to Integral Equation Method Based on\u00a0Trefftz Solution for Inviscid Incompressible Flow\u201d,\u00a0<em>WIT Transactions on Engineering Sciences<\/em>, Vol. 18, pp. 57-68.<\/li>\n \t<li><!-- Repeat similar structure for each publication --><\/li>\n<\/ol>\n<script>\n  document.getElementById(\"pub-count\").innerText = document.querySelectorAll(\"#pub-list li\").length;\n<\/script>\t\t\t\t\t\t<\/div>\n\t\t\t\t<\/div>\n\t\t\t\t\t<\/div>\n\t\t<\/div>\n\t\t\t\t\t\t\t<\/div>\n\t\t<\/section>\n\t\t\t\t\t\t\t<\/div>\n\t\t","protected":false},"excerpt":{"rendered":"<p>Journal Articles (48) Moghadam, H. A., Dolati, F., Bagherighajari, F., &#038; Taromsari, M. M. (2026). 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