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  1. 1461
    “…By comparing the stress–strain curves at different temperatures and strain rates, it was found that UHMWPE exhibits strain rate strengthening and temperature softening effects. By modifying the Sherwood–Frost model, a constitutive model was established to describe the dynamic mechanical properties of UHMWPE at different temperatures. …”
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    Dynamic Constitutive Model of Ultra-High Molecular Weight Polyethylene (UHMWPE): Considering the Temperature and Strain Rate Effects
  2. 1462
    “…The disparity of the Nusslet number, Skin friction, Sherwood number and their influence on the velocity, heat and concentration fields has been scrutinized. …”
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    Entropy Generation on Nanofluid Thin Film Flow of Eyring–Powell Fluid with Thermal Radiation and MHD Effect on an Unsteady Porous Stretching Sheet
  3. 1463
    “…The tabulated results for skin-friction, Nusselt number and Sherwood number are given. A decent agreement is noted in the results when compared with previously published literature on Williamson nanofluids.…”
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    Entropy Generation and Consequences of Binary Chemical Reaction on MHD Darcy–Forchheimer Williamson Nanofluid Flow Over Non-Linearly Stretching Surface
  4. 1464
    “…The strut diameter is an adequate characteristic length for the formulation of heat and mass transfer correlations; accordingly, a power-law dependence of the Sherwood number to the Reynolds number between 0.33 and 0.67 was found according to the flow regimes in the range 1–128 of the Reynolds number. …”
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    A Fundamental Investigation of Gas/Solid Heat and Mass Transfer in Structured Catalysts Based on Periodic Open Cellular Structures (POCS)
  5. 1465
    “…The skin friction factor, Nusselt number, Sherwood number and the motile density are determined. …”
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    An Analysis for Variable Physical Properties Involved in the Nano-Biofilm Transportation of Sutterby Fluid across Shrinking/Stretching Surface
  6. 1466
    “…The distribution of active/inert particles may lead to large variations of the cluster mass transfer performance, and individual particle deep inside the cluster may possess a high Sherwood number.…”
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    Direct Numerical Simulation of Fluid Flow and Mass Transfer in Particle Clusters
  7. 1467
    “…Processed data comprise the relevant non-dimensional groups, namely: Reynolds, non-dimensional axial duct length and Sherwood numbers.…”
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    Experimental data on transport coefficients for developing laminar flow in isosceles triangular ducts using the naphthalene sublimation technique
  8. 1468
    por Patel, Harshad R.
    Publicado 2019
    “…The numerical values of Skin friction, Nusselt number, and Sherwood number are presented in a tabular form. Obtained outcomes are compared with earlier studies in the special case and strong agreement is noted. …”
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    Effects of cross diffusion and heat generation on mixed convective MHD flow of Casson fluid through porous medium with non-linear thermal radiation
  9. 1469
    “…Unlike the shrinking flow, the surface velocity gradient, local Nusselt and Sherwood numbers for stretching flow intensify with the increment of the material parameter. …”
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    Mixed Convective Flow and Heat Transfer of a Dual Stratified Micropolar Fluid Induced by a Permeable Stretching/Shrinking Sheet
  10. 1470
    “…A numerical model was applied to calculate the local Sherwood number on the membrane surface, allowing for qualitative comparison of gas exchange capacities in low-velocity areas caused by the microstructured geometries. …”
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    Microstructured Hollow Fiber Membranes: Potential Fiber Shapes for Extracorporeal Membrane Oxygenators
  11. 1471
    “…Finally, the results of skin frictions, Nusselt numbers and Sherwood numbers and for both ramped wall and isothermal wall conditions are evaluated in tabular form for various values of volume fraction. …”
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    Natural Convection Water/Glycerin–CNT Fractionalized Nanofluid Flow in a Channel with Isothermal and Ramped Conditions
  12. 1472
    “…Numerical data are used to illustrate physical parameters such as skin friction, Nusselt, and Sherwood numbers. For precise values of different flow parameters, the characteristics of fluid velocity, angular velocity, temperature, and concentration gradients are investigated graphically. …”
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    Numerical Case Study of Chemical Reaction Impact on MHD Micropolar Fluid Flow Past over a Vertical Riga Plate
  13. 1473
    por Abdullin, Salavat, Abramov, Victor, Acharya, Bannaje Sripathi, Adam, Nadia, Adams, Mark Raymond, Adzic, Petar, Akchurin, Nural, Akgun, Ugur, Albayrak, Elif Asli, Alemany-Fernandez, Reyes, Almeida, Nuno, Anagnostou, Georgios, Andelin, Daniel, Anderson, E Walter, Anfreville, Marc, Anicin, Ivan, Antchev, Georgy, Antunovic, Zeljko, Arcidiacono, Roberta, Arenton, Michael Wayne, Auffray, Etiennette, Argiro, Stefano, Askew, Andrew, Atramentov, Oleksiy, Ayan, S, Arcidy, M, Aydin, Sezgin, Aziz, Tariq, Baarmand, Marc M, Babich, Kanstantsin, Baccaro, Stefania, Baden, Drew, Baffioni, Stephanie, Bakirci, Mustafa Numan, Balazs, Michael, Banerjee, Sunanda, Banerjee, Sudeshna, Bard, Robert, Barge, Derek, Barnes, Virgil E, Barney, David, Barone, Luciano, Bartoloni, Alessandro, Baty, Clement, Bawa, Harinder Singh, Baiatian, G, Bandurin, Dmitry, Beauceron, Stephanie, Bell, Ken W, Bencze, Gyorgy, Benetta, Robert, Bercher, Michel, Beri, Suman Bala, Bernet, Colin, Berntzon, Lisa, Berthon, Ursula, Besançon, Marc, Betev, Botjo, Beuselinck, Raymond, Bhatnagar, Vipin, Bhatti, Anwar, Biino, Cristina, Blaha, Jan, Bloch, Philippe, Blyth, Simon, Bodek, Arie, Bornheim, Adolf, Bose, Suvadeep, Bose, Tulika, Bourotte, Jean, Brett, Angela Mary, Brown, Robert M, Britton, David, Budd, Howard, Bühler, M, Burchesky, Kyle, Busson, Philippe, Camanzi, Barbara, Camporesi, Tiziano, Cankocak, Kerem, Carrell, Kenneth Wayne, Carrera, E, Cartiglia, Nicolo, Cavallari, Francesca, Cerci, Salim, Cerutti, cM, Chang, Paoti, Chang, You-Hao, Charlot, Claude, Chen, E Augustine, Chen, Wan-Ting, Chen, Zheng-Yu, Chendvankar, Sanjay, Chipaux, Rémi, Choudhary, Brajesh C, Choudhury, Rajani Kant, Chung, Yeon Sei, Clarida, Warren, Cockerill, David J A, Combaret, Christophe, Conetti, Sergio, Cossutti, Fabio, Cox, Bradley, Cremaldi, Lucien Marcus, Cushman, Priscilla, Cussans, David, Dafinei, Ioan, Damgov, Jordan, Da Silva Di Calafiori, Diogo Raphael, Daskalakis, Georgios, Davatz, Giovanna, David, A, De Barbaro, Pawel, Debbins, Paul, Deiters, Konrad, Dejardin, Marc, Djordjevic, Milos, Deliomeroglu, Mehmet, Della Negra, Rodolphe, Della Ricca, Giuseppe, Del Re, Daniele, Demianov, A, De Min, Alberto, Denegri, Daniel, Depasse, Pierre, de Visser, Theo, Descamps, Julien, Deshpande, Pandurang Vishnu, Díaz, Jonathan, Diemoz, Marcella, Di Marco, Emanuele, Dimitrov, Lubomir, Dissertori, Günther, Dittmar, Michael, Djambazov, Lubomir, Dobrzynski, Ludwik, Drndarevic, Snezana, Duboscq, Jean Etienne, Dugad, Shashikant, Dumanoglu, Isa, Duru, Firdevs, Dutta, Dipanwita, Dzelalija, Mile, Efthymiopoulos, I, Elias, John E, Peisert, A, El-Mamouni, H, Elvira, D, Emeliantchik, Igor, Eno, Sarah Catherine, Ershov, Alexander, Erturk, Sefa, Esen, Selda, Eskut, Eda, Evangelou, Ioannis, Evans, David, Fabbro, Bernard, Faure, Jean-Louis, Fay, Jean, Fenyvesi, Andras, Ferri, Federico, Fisher, Wade Cameron, Flower, Paul S, Franci, Daniele, Franzoni, Giovanni, Freeman, Jim, Freudenreich, Klaus, Funk, Wolfgang, Ganjour, Serguei, Gargiulo, Corrado, Gascon, Susan, Gataullin, Marat, Gaultney, Vanessa, Gamsizkan, Halil, Gavrilov, Vladimir, Geerebaert, Yannick, Genchev, Vladimir, Gentit, François-Xavier, Gerbaudo, Davide, Gershtein, Yuri, Ghezzi, Alessio, Ghodgaonkar, Manohar, Gilly, Jean, Givernaud, Alain, Gleyzer, Sergei V, Gninenko, Sergei, Go, Apollo, Gobbo, Benigno, Godinovic, Nikola, Golubev, Nikolai, Golutvin, Igor, Goncharov, Petr, Gong, Datao, Govoni, Pietro, Grant, Nicholas, Gras, Philippe, Grassi, Tullio, Green, Dan, Greenhalgh, R J S, Gribushin, Andrey, Grinev, B, Guevara Riveros, Luz, Guillaud, Jean-Paul, Gurtu, Atul, Murat Guler, A, Gülmez, Erhan, Gümüs, K, Haelen, T, Hagopian, Sharon, Hagopian, Vasken, Haguenauer, Maurice, Halyo, Valerie, Hamel de Monchenault, Gautier, Hansen, Sten, Hashemi, Majid, Hauptman, John M, Hazen, Eric, Heath, Helen F, Heering, Arjan Hendrix, Heister, Arno, Heltsley, Brian, Hill, Jack, Hintz, Wieland, Hirosky, Robert, Hobson, Peter R, Honma, Alan, Hou, George Wei-Shu, Hsiung, Yee, Hunt, Adam, Husejko, Michal, Ille, Bernard, Ilyina, N, Imlay, Richard, Ingram, D, Ingram, Quentin, Isiksal, Engin, Jarry, Patrick, Jarvis, Chad, Jeong, Chiyoung, Jessop, Colin, Johnson, Kurtis F, Jones, John, Jovanovic, Dragoslav, Kaadze, Ketino, Kachanov, Vassili, Kaftanova, V, Kailas, Swaminathan, Kalagin, Vladimir, Kalinin, Alexey, Kalmani, Suresh Devendrappa, Karmgard, Daniel John, Kataria, Sushil Kumar, Kaur, Manjit, Kaya, Mithat, Kaya, Ozlem, Kayis-Topaksu, A, Kellogg, Richard G, Kennedy, Bruce W, Khmelnikov, Alexander, Kim, Heejong, Kisselevich, I, Kloukinas, Kostas, Kodolova, Olga, Kohli, Jatinder Mohan, Kokkas, Panagiotis, Kolberg, Ted, Kolossov, V, Korablev, Andrey, Korneev, Yury, Kosarev, Ivan, Kramer, Laird, Krasnikov, Nikolai, Krinitsyn, Alexander, Krokhotin, Andrey, Krpic, Dragomir, Kryshkin, V, Kubota, Yuichi, Kubrik, A, Kuleshov, Sergey, Kumar, Arun, Kumar, P, Kunori, Shuichi, Kuo, Chen-Cheng, Kurt, Pelin, Kyberd, Paul, Kyriakis, Aristotelis, Laasanen, Alvin T, Ladygin, Vladimir, Laird, Edward, Landsberg, Greg, Laszlo, Andras, Lawlor, C, Lazic, Dragoslav, Lebeau, Michel, Lecomte, Pierre, Lecoq, Paul, Ledovskoy, Alexander, Lee, Sang Joon, Leshev, Georgi, Lethuillier, Morgan, Levchuk, Leonid, Lin, Sheng-Wen, Lin, Willis, Linn, Stephan, Lintern, A L, Litvine, Vladimir, Litvintsev, Dmitri, Litov, Leander, Lobolo, L, Locci, Elizabeth, Lodge, Anthony B, Longo, Egidio, Loukas, Demetrios, Los, Serguei, Lubinsky, V, Luckey, Paul David, Lukanin, Vladimir, Lustermann, Werner, Lynch, Clare, Ma, Yousi, Machado, Emanuel, Mahlke-Krüger, H, Maity, Manas, Majumder, Gobinda, Malberti, Martina, Malclès, Julie, Maletic, Dimitrije, Mandjavidze, Irakli, Mans, Jeremy, Manthos, Nikolaos, Maravin, Yurii, Marchica, Carmelo, Marinelli, Nancy, Markou, Athanasios, Markou, Christos, Marlow, Daniel, Markowitz, Pete, Marone, Matteo, Martínez, German, Mathez, Hervé, Matveev, Viktor, Mavrommatis, Charalampos, Maurelli, Georges, Mazumdar, Kajari, Meridiani, Paolo, Merlo, Jean-Pierre, Mermerkaya, Hamit, Mescheryakov, G, Mestvirishvili, Alexi, Mikhailin, V, Milenovic, Predrag, Miller, Michael, Milleret, Gérard, Miné, Philippe, Möller, A, Mohammadi-Najafabadi, M, Mohanty, Ajit Kumar, Moissenz, P, Mondal, Naba Kumar, Moortgat, Filip, Mossolov, Vladimir, Mur, Michel, Musella, Pasquale, Musienko, Yuri, Nagaraj, P, Nardulli, Alessandro, Nash, Jordan, Nédélec, Patrick, Negri, Pietro, Newman, Harvey B, Nikitenko, Alexander, Norbeck, Edwin, Nessi-Tedaldi, Francesca, Obertino, Maria Margherita, Olson, Jonathan, Onel, Yasar, Onengüt, G, Organtini, Giovanni, Orimoto, Toyoko, Ozkan, Cigdem, Ozkurt, Halil, Ozkorucuklu, Suat, Ozok, Ferhat, Paganoni, Marco, Paganini, Pascal, Paktinat, S, Pal, Andras, Palma, Alessandro, Panev, Bozhidar, Pant, Lalit Mohan, Papadakis, Antonakis, Papadakis, Ioannis, Papadopoulos, Ioannis, Paramatti, Riccardo, Parracho, P, Pastrone, Nadia, Patil, Mandakini Ravindra, Patterson, Juliet Ritchie, Pauss, Felicitas, Penzo, Aldo, Petrakou, Eleni, Petrushanko, Sergey, Petrosian, A, Phillips II, David, Pikalov, Vladimir, Piperov, Stefan, Piroué, Pierre, Podrasky, V, Polatoz, A, Pompos, Arnold, Popescu, Sorina, Posch, C, Pozdnyakov, Andrey, Ptochos, Fotios, Puljak, Ivica, Pullia, Antonino, Punz, Thomas, Puzovic, Jovan, Qian, Weiming, Ragazzi, Stefano, Rahatlou, Shahram, Ralich, Robert, Rande, J, Razis, Panos A, Redaelli, Nicola, Reddy, L, Reidy, Jim, Renker, Dieter, Reucroft, Steve, Reymond, Jean-Marc, Ribeiro, Pedro Quinaz, Röser, Ulf, Rogalev, Evgueni, Rogan, Christopher, Roh, Youn, Rohlf, James, Romanteau, Thierry, Rondeaux, Françoise, Ronquest, Michael, Ronzhin, Anatoly, Rosowsky, André, Rovelli, Chiara, Ruchti, Randy, Rumerio, Paolo, Rusack, Roger, Rusakov, Sergey V, Ryan, Matthew John, Ryazanov, Anton, Safronov, Grigory, Sala, Leonardo, Salerno, Roberto, Sanders, David A, Santanastasio, Francesco, Sanzeni, Christopher, Sarycheva, Ludmila, Satyanarayana, B, Schinzel, Dietrich, Schmidt, Ianos, Seez, Christopher, Sekmen, Sezen, Semenov, Sergey, Senchishin, V, Sergeyev, S, Serin, Meltem, Sever, Ramazan, Sharp, Peter, Shepherd-Themistocleous, Claire, Siamitros, Christos, Sillou, Daniel, Singh, Jas Bir, Singovsky, Alexander, Sirois, Yves, Sirunyan, Albert M, Silva, J, Silva, Pedro, Skuja, Andris, Sharma, Seema, Sherwood, Brian, Shiu, Jing-Ge, Shivpuri, Ram Krishen, Shukla, Prashant, Shumeiko, Nikolai, Smirnov, Vitaly, Smith, Brian, Smith, Vincent J, Sogut, Kenan, Sonmez, Nasuf, Sorokin, Pavel, Spezziga, Mario, Sproston, Martin, Stefanovich, R, Stockli, F, Stolin, Viatcheslav, Sudhakar, Katta, Sulak, Lawrence, Suter, Henry, Suzuki, Ichiro, Swain, John, Tabarellide Fatis, T, Talov, Vladimir, Takahashi, Maiko, Tcheremoukhine, Alexandre, Teller, Olivier, Teplov, Konstantin, Theofilatos, Konstantinos, Thiebaux, Christophe, Thomas, Ray, Timciuc, Vladlen, Timlin, Claire, Titov, Maksym, Tobias, A, Tonwar, Suresh C, Topakli, Huseyin, Topkar, Anita, Triantis, Frixos A, Troshin, Sergey, Tully, Christopher, Turchanovich, L, Tyurin, Nikolay, Ueno, Koji, Ulyanov, A, Uzunian, Andrey, Vanini, A, Vankov, Ivan, Vardanyan, Irina, Varela, F, Varela, Joao, Vasil ev, A, Velasco, Mayda, Vergili, Mehmet, Verma, Piyush, Verrecchia, Patrice, Vesztergombi, Gyorgy, Veverka, Jan, Vichoudis, Paschalis, Vidal, Richard, Virdee, Tejinder, Vishnevskiy, Alexander, Vlassov, E, Vodopiyanov, Igor, Volobouev, Igor, Volkov, Alexey, Volodko, Anton, Von Gunten, Hans Peter, Wang, Lei, Wang, Minzu, Wardrope, David, Weber, Markus, Weng, Joanna, Werner, Jeremy Scott, Wetstein, Matthew, Winn, Dave, Wigmans, Richard, Williams, Jennifer C, Whitmore, Juliana, Won, Steven, Wu, Shouxiang, Yang, Yong, Yaselli, Ignacio, Yazgan, Efe, Yetkin, Taylan, Yohay, Rachel, Zabi, Alexandre, Zálán, Peter, Zamiatin, Nikolai, Zarubin, Anatoli, Zelepoukine, Serguei, Zeyrek, Mehmet, Zhang, Jia-Wen, Zhang, Lin, Zhu, Kejun, Zhu, Ren-Yuan
    Publicado 2008
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    The CMS Barrel Calorimeter Response to Particle Beams from 2 to 350 GeV/c
  14. 1474
    “…Also, the significance of different physical factors on skin frictions, local Nusselt number and Sherwood number are demonstrated with the help of Tables. …”
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    Analysis of the Time-Dependent magnetohydrodynamic Newtonian fluid flow over a rotating sphere with thermal radiation and chemical reaction
  15. 1475
    “…The outcomes are presented through graphical representations and tables, showcasing various parameters such as momentum slip, temperature slip, local Nusselt number, Sherwood number, and suction parameter. The primary motivation of this research lies in investigating the behaviour of Maxwell fluid flow in the absence of slip conditions. …”
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    Viscoelastic fluid flow over a horizontal flat plate with various boundary slip conditions and suction effects
  16. 1476
    “…The numerical results for the dimensionless axial velocity, temperature and nanoparticle volume fraction as well as the reduced Nusselt and Sherwood number have been presented graphically and discussed. …”
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    MHD Free Convective Boundary Layer Flow of a Nanofluid past a Flat Vertical Plate with Newtonian Heating Boundary Condition
  17. 1477
    por Godongwana, Buntu
    Publicado 2016
    “…The effectiveness factor is shown to be a function of the Thiele modulus, the partition coefficient, the Sherwood number, the Peclet number, and membrane thickness. …”
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    Effectiveness Factors and Conversion in a Biocatalytic Membrane Reactor
  18. 1478
    por Parveen, Rujda, Mahapatra, T.R.
    Publicado 2019
    “…The effect of these parameters are revealed in terms of streamlines, isotherms, isoconcentrations, entropy generation, average Nusselt number and Sherwood number. Results indicate that heat and mass transfer rate augment as Rayleigh number and volume fraction of nanoparticles increase and are found to drop with the increase in Hartmann number and buoyancy ratio.…”
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    Numerical simulation of MHD double diffusive natural convection and entropy generation in a wavy enclosure filled with nanofluid with discrete heating
  19. 1479
    por Alotaibi, Hammad, Eid, Mohamed R.
    Publicado 2021
    “…Results of nanofluid flow and heat as well as the convective heat transport coefficient, drag force coefficient, and Nusselt and Sherwood numbers under the impact of the studied parameters are discussed and presented through graphs and tables. …”
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    Thermal Analysis of 3D Electromagnetic Radiative Nanofluid Flow with Suction/Blowing: Darcy–Forchheimer Scheme
  20. 1480
    “…We also noticed that the Sherwood number falls incrementally in Deborah and Prandtl numbers, but it upsurges with an increase in the buoyancy parameter.…”
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    Mass and Heat Transport Assessment and Nanomaterial Liquid Flowing on a Rotating Cone: A Numerical Computing Approach
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