Citations (52)
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Xiang Lu, Evangelos Tsotsas & Abdolreza Kharaghani. (2023) Scale transition: Pore network study of how pore structure affects the macroscopic parameters of the continuum model for drying. Drying Technology 41:6, pages 948-967.
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Debashis Panda, Supriya Bhaskaran, Shubhani Paliwal, Abdolreza Kharaghani, Evangelos Tsotsas & Vikranth Kumar Surasani. (2022) Pore-scale physics of drying porous media revealed by Lattice Boltzmann simulations. Drying Technology 40:6, pages 1114-1129.
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Zhenyu Xu & Krishna M. Pillai. (2022) Influence of pore-network microstructure on the isothermal-drying performance of porous media. Drying Technology 40:4, pages 767-780.
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Jianlin Zhao, Feifei Qin, Qinjun Kang, Dominique Derome & Jan Carmeliet. (2022) Pore-scale simulation of drying in porous media using a hybrid lattice Boltzmann: pore network model. Drying Technology 40:4, pages 719-734.
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Zhenyu Xu & Krishna M. Pillai. (2021) A pore-network study on the factors influencing the isothermal drying of single- and dual-scale porous media. Drying Technology 39:10, pages 1294-1313.
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Roberto Pisano, Andrea Arsiccio, Kyuya Nakagawa & Antonello A. Barresi. (2019) Tuning, measurement and prediction of the impact of freezing on product morphology: A step toward improved design of freeze-drying cycles. Drying Technology 37:5, pages 579-599.
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Thomas Metzger. (2019) A personal view on pore network models in drying technology. Drying Technology 37:5, pages 497-512.
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N. Vorhauer, E. Tsotsas & M. Prat. (2018) Drying of thin porous disks from pore network simulations. Drying Technology 36:6, pages 651-663.
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Kieu Hiep Le, Abdolreza Kharaghani, Christoph Kirsch & Evangelos Tsotsas. (2017) Discrete pore network modeling of superheated steam drying. Drying Technology 35:13, pages 1584-1601.
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Zhenyu Xu & Krishina M. Pillai. (2017) Modeling drying in thin porous media after coupling pore-level drying dynamics with external flow field. Drying Technology 35:7, pages 785-801.
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M. Börnhorst, P. Walzel, A. Rahimi, A. Kharaghani, E. Tsotsas, N. Nestle, A. Besser, F. Kleine Jäger & T. Metzger. (2016) Influence of pore structure and impregnation–drying conditions on the solid distribution in porous support materials. Drying Technology 34:16, pages 1964-1978.
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Zhenyu Xu & Krishna M. Pillai. (2016) Analyzing slow drying in a porous medium placed adjacent to laminar airflow using a pore-network model. Numerical Heat Transfer, Part A: Applications 70:11, pages 1213-1231.
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Arman Rahimi, Thomas Metzger, Abdolreza Kharaghani & Evangelos Tsotsas. (2016) Interaction of droplets with porous structures: Pore network simulation of wetting and drying. Drying Technology 34:9, pages 1129-1140.
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Gorazd Berčič. (2015) Through Control of Wetting and Drying Conditions of Monolithic Supports Toward a Uniform Catalyst Distribution. Drying Technology 33:1, pages 72-82.
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N. Vorhauer, Q.T. Tran, T. Metzger, E. Tsotsas & M. Prat. (2013) Experimental Investigation of Drying in a Model Porous Medium: Influence of Thermal Gradients. Drying Technology 31:8, pages 920-929.
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Yujing Wang, Abdolreza Kharaghani, Thomas Metzger & Evangelos Tsotsas. (2012) Pore Network Drying Model for Particle Aggregates: Assessment by X-Ray Microtomography. Drying Technology 30:15, pages 1800-1809.
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FranciscoA. SanMartin, JoãoB. Laurindo & LuisA. Segura. (2011) Pore-Scale Simulation of Drying of a Porous Media Saturated with a Sucrose Solution. Drying Technology 29:8, pages 873-887.
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N. Vorhauer, T. Metzger & E. Tsotsas. (2010) Empirical Macroscopic Model for Drying of Porous Media Based on Pore Networks and Scaling Theory. Drying Technology 28:8, pages 991-1000.
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A. G. Yiotis, I. N. Tsimpanogiannis & A. K. Stubos. (2010) Fractal Characteristics and Scaling of the Drying Front in Porous Media: A Pore Network Study. Drying Technology 28:8, pages 981-990.
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C. A. Oyarzun & L. A. Segura. (2009) Design and Construction of Glass Micromodels for the Study of Moisture Transport in Softwoods. Drying Technology 27:1, pages 14-29.
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Hiromichi Shibata & Yumiko Hirohashi. (2008) Mechanism of the First Falling Rate Period: An Alternative Approach by Image Analysis. Drying Technology 26:6, pages 675-684.
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Suherman, M. Peglow & E. Tsotsas. (2007) On the Applicability of Normalization for Drying Kinetics. Drying Technology 26:1, pages 90-96.
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LuisA. Segura. (2007) Modeling at Pore-Scale Isothermal Drying of Porous Materials: Liquid and Vapor Diffusivity. Drying Technology 25:10, pages 1677-1686.
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Articles from other publishers (29)
Thilo Heckmann, Jochen C. Eser, Andreas Altvater, Johannes Dörr, Hannah Lepère, Philip Scharfer & Wilhelm Schabel. (2023) Mass Transport in the Stefan–Knudsen Transition Region during Vacuum Drying at Different Pressures in a Porous Structure Resembling Battery Electrodes. Langmuir 39:7, pages 2859-2869.
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Ercan Aydoğmuş, Ahmet B. Demirpolat & Hasan Arslanoğlu. (2021) Isothermal and non-isothermal drying behavior for grape (Vitis vinifera) by new improved system: exergy analysis, RSM, and modeling. Biomass Conversion and Biorefinery 12:2, pages 527-536.
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Timo Koch, Kilian Weishaupt, Johannes Müller, Bernhard Weigand & Rainer Helmig. (2021) A (Dual) Network Model for Heat Transfer in Porous Media. Transport in Porous Media 140:1, pages 107-141.
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Jana Kumberg, Michael Baunach, Jochen C. Eser, Andreas Altvater, Philip Scharfer & Wilhelm Schabel. (2021) Influence of Layer Thickness on the Drying of Lithium‐Ion Battery Electrodes—Simulation and Experimental Validation. Energy Technology 9:5, pages 2100013.
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Xiang Lu, Evangelos Tsotsas & Abdolreza Kharaghani. (2021) Insights into evaporation from the surface of capillary porous media gained by discrete pore network simulations. International Journal of Heat and Mass Transfer 168, pages 120877.
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Otman Maalal, Marc Prat & Didier Lasseux. (2021) Pore network model of drying with Kelvin effect. Physics of Fluids 33:2.
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Debashis Panda, Shubhani Paliwal, Dasika Prabhat Sourya, Abdolreza Kharaghani, Evangelos Tsotsas & Vikranth Kumar Surasani. (2020) Influence of thermal gradients on the invasion patterns during drying of porous media: A lattice Boltzmann method. Physics of Fluids 32:12.
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Xiang Lu, Abdolreza Kharaghani & Evangelos Tsotsas. (2020) Transport parameters of macroscopic continuum model determined from discrete pore network simulations of drying porous media: Throat-node vs. throat-pore configurations. Chemical Engineering Science 223, pages 115723.
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Debashis Panda, B. Supriya, Abdolreza Kharaghani, Evangelos Tsotsas & Vikranth Kumar Surasani. (2020) Lattice Boltzmann simulations for micro-macro interactions during isothermal drying of bundle of capillaries. Chemical Engineering Science 220, pages 115634.
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Hong Thai Vu & Evangelos Tsotsas. (2019) A Framework and Numerical Solution of the Drying Process in Porous Media by Using a Continuous Model. International Journal of Chemical Engineering 2019, pages 1-16.
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Vahid Mashayekhizadeh & Mohammad Reza Rasaei. (2019) Pore network modelling of molecular diffusion in a single-block model during lean gas injection, a comparative study on calculation approaches. The Canadian Journal of Chemical Engineering 97:3, pages 808-820.
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N. Vorhauer, E. Tsotsas & M. Prat. (2018) Temperature gradient induced double stabilization of the evaporation front within a drying porous medium. Physical Review Fluids 3:11.
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Alireza Attari Moghaddam, Abdolreza Kharaghani, Evangelos Tsotsas & Marc Prat. (2018) A pore network study of evaporation from the surface of a drying non-hygroscopic porous medium. AIChE Journal 64:4, pages 1435-1447.
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Saman Beyhaghi, Zhenyu Xu & Krishna M. Pillai. (2016) Achieving the Inside–Outside Coupling During Network Simulation of Isothermal Drying of a Porous Medium in a Turbulent Flow. Transport in Porous Media 114:3, pages 823-842.
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J. Matadamas-Hernández, G. Román-Alonso, F. Rojas-González, M.A. Castro-García, Azzedine Boukerche, M. Aguilar-Cornejo & S. Cordero-Sánchez. (2014) Parallel Simulation of Pore Networks Using Multicore CPUs. IEEE Transactions on Computers 63:6, pages 1513-1525.
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Sara Taslimi Taleghani & Mitra Dadvar. (2014) Two dimensional pore network modelling and simulation of non-isothermal drying by the inclusion of viscous effects. International Journal of Multiphase Flow 62, pages 37-44.
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Rui Wu, Guo-Min Cui & Rong Chen. (2014) Pore network study of slow evaporation in hydrophobic porous media. International Journal of Heat and Mass Transfer 68, pages 310-323.
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Mohammad Reza Shaeri, Saman Beyhaghi & Krishna M. Pillai. (2013) On applying an external-flow driven mass transfer boundary condition to simulate drying from a pore-network model. International Journal of Heat and Mass Transfer 57:1, pages 331-344.
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Mohammad Reza Shaeri, Saman Beyhaghi & Krishna M. Pillai. (2012) Drying of a porous medium with multiple open sides using a pore-network model simulation. International Communications in Heat and Mass Transfer 39:9, pages 1320-1324.
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Abdolreza Kharaghani, Thomas Metzger & Evangelos Tsotsas. (2012) An irregular pore network model for convective drying and resulting damage of particle aggregates. Chemical Engineering Science 75, pages 267-278.
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M. Prat. (2011) Pore Network Models of Drying, Contact Angle, and Film Flows. Chemical Engineering & Technology 34:7, pages 1029-1038.
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Abdolreza Kharaghani, Thomas Metzger & Evangelos Tsotsas. (2011) A proposal for discrete modeling of mechanical effects during drying, combining pore networks with DEM. AIChE Journal 57:4, pages 872-885.
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F. DEBASTE & V. HALLOIN. (2010) APPLICATION OF DISCRETE MODELING APPROACH TO FLUIDIZED BED YEAST DRYING. Journal of Food Process Engineering 33, pages 2-22.
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V. K. Surasani, T. Metzger & E. Tsotsas. (2009) A Non-isothermal Pore Network Drying Model with Gravity Effect. Transport in Porous Media 80:3, pages 431-439.
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V.K. Surasani, T. Metzger & E. Tsotsas. (2008) Influence of heating mode on drying behavior of capillary porous media: Pore scale modeling. Chemical Engineering Science 63:21, pages 5218-5228.
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Thomas Metzger & Evangelos Tsotsas. (2008) Viscous stabilization of drying front: Three-dimensional pore network simulations. Chemical Engineering Research and Design 86:7, pages 739-744.
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V.K. Surasani, T. Metzger & E. Tsotsas. (2008) Consideration of heat transfer in pore network modelling of convective drying. International Journal of Heat and Mass Transfer 51:9-10, pages 2506-2518.
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Thomas Metzger, Anton Irawan & Evangelos Tsotsas. (2007) Influence of pore structure on drying kinetics: A pore network study. AIChE Journal 53:12, pages 3029-3041.
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