Brady, John F.

Combined from CaltechAUTHORS

• Zhou, Tingtao and Wan, Xuan, et el. (2024) AI-aided geometric design of anti-infection catheters; Science Advances; Vol. 10; No. 1; eadj1741; PMCID PMC10776022; 10.1126/sciadv.adj1741
• Omar, Ahmad K. and Row, Hyeongjoo, et el. (2023) Mechanical theory of nonequilibrium coexistence and motility-induced phase separation; Proceedings of the National Academy of Sciences of the United States of America; Vol. 120; No. 18; Art. No. e2219900120; PMCID PMC10160997; 10.1073/pnas.2219900120
• Omar, Ahmad K. and Klymko, Katherine, et el. (2023) Tuning nonequilibrium phase transitions with inertia; Journal of Chemical Physics; Vol. 158; No. 7; Art. No. 074904; 10.1063/5.0138256
• Shaik, Vaseem A. and Peng, Zhiwei, et el. (2023) Confined active matter in external fields; Soft Matter; Vol. 19; No. 7; 1384-1392; 10.1039/d2sm01135b
• Elfring, Gwynn J. and Brady, John F. (2022) Active Stokesian dynamics; Journal of Fluid Mechanics; Vol. 952; Art. No. A19; 10.1017/jfm.2022.909
• Glisman, Alec and Brady, John F. (2022) Swimming in potential flow; Journal of Fluid Mechanics; Vol. 952; Art. No. R5; 10.1017/jfm.2022.946
• Ross, Tyler D. and Osmanović, Dino, et el. (2022) Ray Optics for Gliders; ACS Nano; Vol. 16; No. 10; 16191-16200; 10.1021/acsnano.2c05015
• Peng, Zhiwei and Brady, John F. (2022) Trapped-particle microrheology of active suspensions; Journal of Chemical Physics; Vol. 157; No. 10; Art. No. 104119; 10.1063/5.0108014
• Peng, Zhiwei and Brady, John F. (2022) Forced microrheology of active colloids; Journal of Rheology; Vol. 66; No. 5; 955-972; 10.1122/8.0000504
• Peng, Zhiwei and Zhou, Tingtao, et el. (2022) Activity-induced propulsion of a vesicle; Journal of Fluid Mechanics; Vol. 942; Art. No. A32; 10.1017/jfm.2022.398
• Peng, Zhiwei and Brady, John F. (2022) Forced microrheology of active colloids; 10.48550/arXiv.arXiv.2205.03715
• Kjeldbjerg, Camilla M. and Brady, John F. (2022) Partitioning of active particles into porous media; Soft Matter; Vol. 18; No. 14; 2757-2766; 10.1039/d1sm01752g
• Ross, Tyler D. and Osmanović, Dino, et el. (2021) Snell's Law for Swimmers; 10.48550/arXiv.2109.06360
• Mallory, Stewart A. and Omar, Ahmad K., et el. (2021) Dynamic overlap concentration scale of active colloids; Physical Review E; Vol. 104; No. 4; Art. No. 044612; 10.1103/PhysRevE.104.044612
• Brady, John F. (2021) Phoretic motion in active matter; Journal of Fluid Mechanics; Vol. 922; Art. No. A10; 10.1017/jfm.2021.530
• Dulaney, Austin R. and Brady, John F. (2021) Machine learning for phase behavior in active matter systems; Soft Matter; Vol. 17; No. 28; 6808-6816; 10.1039/d1sm00266j
• Marshall, Kevin J. and Brady, John F. (2021) The hydrodynamics of an active squirming particle inside of a porous container; Journal of Fluid Mechanics; Vol. 919; Art. No. A31; 10.1017/jfm.2021.276
• Zhou, Tingtao and Peng, Zhiwei, et el. (2021) Distribution and pressure of active Lévy swimmers under confinement; Journal of Physics A: Mathematical and General; Vol. 54; No. 27; Art. No. 275002; 10.1088/1751-8121/ac0509
• Kjeldbjerg, Camilla M. and Brady, John F. (2021) Theory for the Casimir effect and the partitioning of active matter; Soft Matter; Vol. 17; No. 3; 523-530; 10.1039/d0sm01797c
• Dulaney, Austin R. and Mallory, Stewart A., et el. (2021) The "isothermal" compressibility of active matter; Journal of Chemical Physics; Vol. 154; No. 1; Art. No. 014902; 10.1063/5.0029364
• Peng, Zhiwei and Brady, John F. (2020) Upstream swimming and Taylor dispersion of active Brownian particles; Physical Review Fluids; Vol. 5; No. 7; Art. No. 073102; 10.1103/PhysRevFluids.5.073102
• Row, Hyeongjoo and Brady, John F. (2020) Reverse osmotic effect in active matter; Physical Review E; Vol. 101; No. 6; Art. No. 062604; 10.1103/physreve.101.062604
• Dulaney, A. R. and Brady, J. F. (2020) Waves in active matter: The transition from ballistic to diffusive behavior; Physical Review E; Vol. 101; No. 5; Art. No. 052609; 10.1103/PhysRevE.101.052609
• Wang, Mu and Jamali, Safa, et el. (2020) A hydrodynamic model for discontinuous shear-thickening in dense suspensions; Journal of Rheology; Vol. 64; No. 2; 379-394; 10.1122/1.5134036
• Burkholder, Eric W. and Brady, John F. (2020) Nonlinear microrheology of active Brownian suspensions; Soft Matter; Vol. 16; No. 4; 1034-1016; 10.1039/c9sm01713e
• Makuch, Karol and Hołyst, Robert, et el. (2020) Diffusion and flow in complex liquids; Soft Matter; Vol. 16; No. 1; 114-124; 10.1039/c9sm01119f
• Omar, Ahmad K. and Wang, Zhen-Gang, et el. (2020) Microscopic origins of the swim pressure and the anomalous surface tension of active matter; Physical Review E; Vol. 101; No. 1; Art. No. 012604; 10.1103/physreve.101.012604
• Jamali, Safa and Brady, John F. (2019) Alternative Frictional Model for Discontinuous Shear Thickening of Dense Suspensions: Hydrodynamics; Physical Review Letters; Vol. 123; No. 13; Art. No. 138002; 10.1103/physrevlett.123.138002
• Burkholder, Eric W. and Brady, John F. (2019) Fluctuation-dissipation in active matter; Journal of Chemical Physics; Vol. 150; No. 18; Art. No. 184901; 10.1063/1.5081725
• Omar, Ahmad K. and Wu, Yanze, et el. (2019) Swimming to Stability: Structural and Dynamical Control via Active Doping; ACS Nano; Vol. 13; No. 1; 560-572; 10.1021/acsnano.8b07421
• Burkholder, Eric W. and Brady, John F. (2018) Do hydrodynamic interactions affect the swim pressure?; Soft Matter; Vol. 14; No. 18; 3581-3589; 10.1039/c8sm00197a
• Yan, Wen and Brady, John F. (2018) Anisotropic swim stress in active matter with nematic order; New Journal of Physics; Vol. 20; No. 5; Art. No. 053056; 10.1088/1367-2630/aac3c5
• Sokolov, Andrey and Dominguez Rubio, Leonardo, et el. (2018) Instability of expanding bacterial droplets; Nature Communications; Vol. 9; Art. No. 1322; PMCID PMC5883006; 10.1038/s41467-018-03758-z
• Yan, Wen and Brady, John F. (2018) The curved kinetic boundary layer of active matter; Soft Matter; Vol. 14; No. 2; 279-290; 10.1039/C7SM01643C
• Yan, Wen and Brady, John F. (2017) Antiswarming: Structure and dynamics of repulsive chemically active particles; Physical Review E; Vol. 96; No. 6; Art. No. 060601; 10.1103/PhysRevE.96.060601
• Wang, Mu and Brady, John F. (2017) Microstructures and mechanics in the colloidal film drying process; Soft Matter; Vol. 13; No. 44; 8156-8170; 10.1039/c7sm01585b
• Takatori, S. C. and Brady, J. F. (2017) Inertial effects on the stress generation of active fluids; Physical Review Fluids; Vol. 2; No. 9; Art. No. 094305; 10.1103/PhysRevFluids.2.094305
• Burkholder, Eric W. and Brady, John F. (2017) Tracer diffusion in active suspensions; Physical Review E; Vol. 95; No. 5; Art. No. 052605; 10.1103/PhysRevE.95.052605
• Marenne, Stéphanie and Morris, Jeffrey F., et el. (2017) Unsteady shear flows of colloidal hard-sphere suspensions by dynamic simulation; Journal of Rheology; Vol. 61; No. 3; 477-501; 10.1122/1.4979005
• Takatori, S. C. and Brady, J. F. (2017) Superfluid Behavior of Active Suspensions from Diffusive Stretching; Physical Review Letters; Vol. 118; No. 1; Art. No. 018003; 10.1103/PhysRevLett.118.018003
• Yan, Wen and Brady, John F. (2016) The behavior of active diffusiophoretic suspensions: An accelerated Laplacian dynamics study; Journal of Chemical Physics; Vol. 145; No. 13; Art. No. 134902; 10.1063/1.4963722
• Wang, M. and Brady, J. F. (2016) Reply to the comment from Ikeda, Berthier, and Sollich (IBS); 10.48550/arXiv.1604.01370
• Koumakis, Nick and Brady, John F., et el. (2016) Amorphous and ordered states of concentrated hard spheres under oscillatory shear; Journal of Non-Newtonian Fluid Mechanics; Vol. 233; 119-132; 10.1016/j.jnnfm.2016.02.004
• Koumakis, N. and Laurati, M., et el. (2016) Start-up shear of concentrated colloidal hard spheres: Stresses, dynamics, and structure; Journal of Rheology; Vol. 60; No. 4; 603-623; 10.1122/1.4949340
• Wang, M. and Brady, J. F. (2016) Wang and Brady Reply; Physical Review Letters; Vol. 116; No. 17; Art. No. 179802; 10.1103/PhysRevLett.116.179802
• Takatori, Sho C. and De Dier, Raf, et el. (2016) Acoustic trapping of active matter; Nature Communications; Vol. 7; Art. No. 10694; PMCID PMC4792924; 10.1038/ncomms10694
• Wang, Mu and Brady, John F. (2016) Spectral Ewald Acceleration of Stokesian Dynamics for polydisperse suspensions; Journal of Computational Physics; Vol. 306; 443-477; 10.1016/j.jcp.2015.11.042
• Takatori, Sho C. and Brady, John F. (2016) Forces, Stresses and the (Thermo?) Dynamics of Active Matter; Current Opinion in Colloid and Interface Science; Vol. 21; 24-33; 10.1016/j.cocis.2015.12.003
• Yan, Wen and Brady, John F. (2016) The force on a body in active matter; 10.48550/arXiv.1510.07731
• Yan, Wen and Brady, John F. (2015) The force on a boundary in active matter; Journal of Fluid Mechanics; Vol. 785; Art. No. R1; 10.1017/jfm.2015.621
• Takatori, Sho C. and Brady, John F. (2015) A theory for the phase behavior of mixtures of active particles; Soft Matter; Vol. 11; No. 40; 7920-7931; 10.1039/c5sm01792k
• Wang, Mu and Brady, John F. (2015) Constant Stress and Pressure Rheology of Colloidal Suspensions; Physical Review Letters; Vol. 115; No. 15; Art. No. 158301; 10.1103/PhysRevLett.115.158301
• Heinen, Marco and Schnyder, Simon K., et el. (2015) Classical Liquids in Fractal Dimension; Physical Review Letters; Vol. 115; No. 9; Art. No. 097801; 10.1103/PhysRevLett.115.097801
• Yan, Wen and Brady, John F. (2015) The swim force as a body force; Soft Matter; Vol. 11; No. 31; 6235-6244; 10.1039/C5SM01318F
• Heinen, Marco and Schnyder, Simon K., et el. (2015) Fractal Liquids; 10.48550/arXiv.1505.01023
• Koumakis, Nick and Moghimi, Esmaeel, et el. (2015) Tuning colloidal gels by shear; Soft Matter; Vol. 11; No. 23; 4640-4648; 10.1039/c5sm00411j
• Wang, Mu and Brady, John F. (2015) Short-time transport properties of bidisperse suspensions and porous media: a Stokesian Dynamics study; Journal of Chemical Physics; Vol. 142; No. 9; Art. No. 094901; 10.1063/1.4913518
• Takatori, Sho C. and Brady, J. F. (2015) Towards a thermodynamics of active matter; Physical Review E; Vol. 91; No. 3; Art. No. 032117; 10.1103/PhysRevE.91.032117
• Wang, Mu and Heinen, Marco, et el. (2015) Short-time diffusion in concentrated bidisperse hard-sphere suspensions; Journal of Chemical Physics; Vol. 142; No. 6; Art. No. 064905; 10.1063/1.4907594
• Takatori, Sho C. and Brady, John F. (2014) Swim stress, motion, and deformation of active matter: effect of an external field; Soft Matter; Vol. 10; No. 47; 9433-9445; 10.1039/c4sm01409j
• Slominski, Charles G. and Kraynik, Andrew M., et el. (2014) The Einstein shear viscosity correction for non no-slip hyperspheres; Journal of Colloid and Interface Science; Vol. 430; 302-304; 10.1016/j.jcis.2014.05.052
• Takatori, S. C. and Yan, W., et el. (2014) Swim Pressure: Stress Generation in Active Matter; Physical Review Letters; Vol. 113; No. 2; Art. No. 028103; 10.1103/PhysRevLett.113.028103
• Shklyaev, Sergey and Brady, John F., et el. (2014) Non-spherical osmotic motor: chemical sailing; Journal of Fluid Mechanics; Vol. 748; 488-520; 10.1017/jfm.2014.177
• Swan, James W. and Zia, Roseanna N., et el. (2014) Large amplitude oscillatory microrheology; Journal of Rheology; Vol. 58; No. 1; 1-41; 10.1122/1.4826939
• Michailidou, V. N. and Swan, J. W., et el. (2013) Anisotropic diffusion of concentrated hard-sphere colloids near a hard wall studied by evanescent wave dynamic light scattering; Journal of Chemical Physics; Vol. 136; No. 16; Art. No. 164905; 10.1063/1.4825261
• Córdova-Figueroa, U. M. and Brady, J. F., et el. (2013) Osmotic propulsion of colloidal particles via constant surface flux; Soft Matter; Vol. 9; No. 28; 6382-6390; 10.1039/C3SM00017F
• Koumakis, N. and Brady, J. F., et el. (2013) Complex Oscillatory Yielding of Model Hard-Sphere Glasses; Physical Review Letters; Vol. 110; No. 17; Art. No. 178301; 10.1103/PhysRevLett.110.178301
• Zia, R. N. and Brady, J. F. (2013) Stress development, relaxation, and memory in colloidal dispersions: Transient nonlinear microrheology; Journal of Rheology; Vol. 57; No. 2; 457-492; 10.1122/1.4775349
• Koumakis, N. and Ballesta, P., et el. (2013) Colloidal gels under shear: Strain rate effects; 10.1063/1.4794598
• Laurati, M. and Mutch, K. J., et el. (2012) Transient dynamics in dense colloidal suspensions under shear: shear rate dependence; Journal of Physics: Condensed Matter; Vol. 24; No. 46; Art. No. 464104; 10.1088/0953-8984/24/46/464104
• Zia, R. N. and Brady, J. F. (2012) Microviscosity, microdiffusivity, and normal stresses in colloidal dispersions; Journal of Rheology; Vol. 56; No. 5; 1175-1208; 10.1122/1.4722880
• Koumakis, N. and Laurati, M., et el. (2012) Yielding of Hard-Sphere Glasses during Start-Up Shear; Physical Review Letters; Vol. 108; No. 9; Art. No. 098303; 10.1103/PhysRevLett.108.098303
• Swan, James W. and Brady, John F. (2011) The hydrodynamics of conned dispersions; Journal of Fluid Mechanics; Vol. 687; 254-299; 10.1017/jfm.2011.351
• Swan, James W. and Brady, John F. (2011) The hydrodynamics of confined dispersions; Journal of Fluid Mechanics; Vol. 687; 254-299; 10.1017/jfm.2011.351
• Swan, James W. and Brady, John F. (2011) Anisotropic diffusion in confined colloidal dispersions: The evanescent diffusivity; Journal of Chemical Physics; Vol. 135; No. 1; Art. No. 014701; 10.1063/1.3604530
• Swan, James W. and Brady, John F., et el. (2011) Modeling hydrodynamic self-propulsion with Stokesian Dynamics. Or teaching Stokesian Dynamics to swim; Physics of Fluids; Vol. 23; No. 7; Art. No. 071901; 10.1063/1.3594790
• Brady, John F. (2011) Particle motion driven by solute gradients with application to autonomous motion: continuum and colloidal perspectives; Journal of Fluid Mechanics; Vol. 667; 216-259; 10.1017/S0022112010004404
• Lele, Pushkar P. and Swan, James W., et el. (2011) Colloidal diffusion and hydrodynamic screening near boundaries; Soft Matter; Vol. 7; No. 15; 6844-6852; 10.1039/c0sm01466d
• Swan, James W. and Brady, John F. (2010) Particle motion between parallel walls: Hydrodynamics and simulation; Physics of Fluids; Vol. 22; No. 10; Art. No. 103301; 10.1063/1.3487748
• Zia, Roseanna N. and Brady, John F. (2010) Single-particle motion in colloids: force-induced diffusion; Journal of Fluid Mechanics; Vol. 658; 188-210; 10.1017/S0022112010001606
• Wagner, Norman J. and Brady, John F. (2009) Shear thickening in colloidal dispersions; Physics Today; Vol. 62; No. 10; 27-32; 10.1063/1.3248476
• Michailidou, V. N. and Petekidis, G., et el. (2009) Dynamics of Concentrated Hard-Sphere Colloids Near a Wall; Physical Review Letters; Vol. 102; No. 6; 068302; 10.1103/PhysRevLett.102.068302
• Córdova-Figueroa, Ubaldo M. and Brady, John F. (2008) Osmotic Propulsion: The Osmotic Motor; Physical Review Letters; Vol. 100; No. 15; Art. No. 158303; 10.1103/PhysRevLett.100.158303
• Leshansky, Alexander M. and Morris, Jeffrey F., et el. (2008) Collective diffusion in sheared colloidal suspensions; Journal of Fluid Mechanics; Vol. 597; 305-341; 10.1017/S0022112007009834
• Khair, Aditya S. and Brady, John F. (2008) Microrheology of colloidal dispersions: Shape matters; Journal of Rheology; Vol. 52; No. 1; 165-196; 10.1122/1.2821894
• Swan, James W. and Brady, John F. (2007) Simulation of hydrodynamically interacting particles near a no-slip boundary; Physics of Fluids; Vol. 19; No. 11; Art. No. 113306; 10.1063/1.2803837
• Subramanian, G. and Brady, John F. (2006) Trajectory analysis for non-Brownian inertial suspensions in simple shear flow; Journal of Fluid Mechanics; Vol. 559; 151-203; 10.1017/S0022112006000255
• Khair, Aditya S. and Brady, John F. (2006) Single particle motion in colloidal dispersions: a simple model for active and nonlinear microrheology; Journal of Fluid Mechanics; Vol. 557; 73-117; 10.1017/S0022112006009608
• Brady, John F. and Khair, Aditya S., et el. (2006) On the bulk viscosity of suspensions; Journal of Fluid Mechanics; Vol. 554; 109-123; 10.1017/S0022112006009438
• Khair, Aditya S. and Swaroop, Manuj, et el. (2006) A new resistance function for two rigid spheres in a uniform compressible low-Reynolds-number flow; Physics of Fluids; Vol. 18; No. 4; Art. No. 043102
• Pine, D. J. and Gollub, J. P., et el. (2005) Chaos and threshold for irreversibility in sheared suspensions; Nature; Vol. 438; No. 7070; 997-1000; 10.1038/nature04380
• Carpen, Ileana C. and Brady, John F. (2005) Microrheology of colloidal dispersions by Brownian dynamics simulations; Journal of Rheology; Vol. 49; No. 6; 1483-1502; 10.1122/1.2085174
• Squires, Todd M. and Brady, John F. (2005) A simple paradigm for active and nonlinear microrheology; Physics of Fluids; Vol. 17; No. 7; Art. no. 073101; 10.1063/1.1960607
• Leshansky, Alexander M. and Brady, John F. (2005) Dynamic structure factor study of diffusion in strongly sheared suspensions; Journal of Fluid Mechanics; Vol. 527; 141-169; 10.1017/S0022112004002903
• Sierou, Asimina and Brady, John F. (2004) Shear-induced self-diffusion in non-colloidal suspensions; Journal of Fluid Mechanics; Vol. 506; 285-314; 10.1017/S0022112004008651
• Leshansky, A. M. and Brady, J. F. (2004) Force on a sphere via the generalized reciprocal theorem; Physics of Fluids; Vol. 16; No. 3; 843-844; 10.1063/1.1645491
• Banchio, Adolfo J. and Brady, John F. (2003) Accelerated Stokesian dynamics: Brownian motion; Journal of Chemical Physics; Vol. 118; No. 22; 10323-10332; 10.1063/1.1571819
• Carpen, Ileana C. and Brady, John F. (2002) Gravitational instability in suspension flow; Journal of Fluid Mechanics; Vol. 472; 201-210; 10.1017/S0022112002002513
• Bergenholtz, J. and Brady, J. F., et el. (2002) The non-Newtonian rheology of dilute colloidal suspensions; Journal of Fluid Mechanics; Vol. 456; 239-275; 10.1017/S0022112001007583
• Brady, John F. and Carpen, Ileana C. (2002) Second normal stress jump instability in non-Newtonian fluids; Journal of Non-Newtonian Fluid Mechanics; Vol. 102; No. 2; 219-232; 10.1016/s0377-0257(01)00179-3
• Sierou, Asimina and Brady, John F. (2001) Accelerated Stokesian Dynamics simulations; Journal of Fluid Mechanics; Vol. 448; 115-146; 10.1017/S0022112001005912
• Dimitrakopoulos, P. and Brady, J. F., et el. (2001) Short- and intermediate-time behavior of the linear stress relaxation in semiflexible polymers; Physical Review E; Vol. 64; No. 5; Art. No. 050803; 10.1103/PhysRevE.64.050803
• Ichiki, Kengo and Brady, John F. (2001) Many-body effects and matrix inversion in low-Reynolds-number hydrodynamics; Physics of Fluids; Vol. 13; No. 1; 350-353
• Foss, David R. and Brady, John F. (2000) Structure, diffusion and rheology of Brownian suspensions by Stokesian Dynamics simulation; Journal of Fluid Mechanics; Vol. 407; 167-200; 10.1017/S0022112099007557
• Foss, David R. and Brady, John F. (1999) Self-diffusion in sheared suspensions by dynamic simulation; Journal of Fluid Mechanics; Vol. 401; 243-274
• Brady, John F. and Morris, Jeffrey F. (1997) Microstructure of strongly sheared suspensions and its impact on rheology and diffusion; Journal of Fluid Mechanics; Vol. 348; 103-139
• Phung, Thanh N. and Brady, John F., et el. (1996) Stokesian Dynamics simulation of Brownian suspensions; Journal of Fluid Mechanics; Vol. 313; 181-207; 10.1017/S0022112096002170
• Morris, Jeffrey F. and Brady, John F. (1996) Self-diffusion in sheared suspensions; Journal of Fluid Mechanics; Vol. 312; 223-252; 10.1017/S002211209600198X
• Yurkovetsky, Yevgeny and Brady, John F. (1996) Statistical mechanics of bubbly liquids; Physics of Fluids; Vol. 8; No. 4; 881-895; 10.1063/1.868869
• Morris, Jeffrey F. and Brady, John F. (1995) Bulk Reaction Rate in a Heterogeneous Reaction System; Industrial & Engineering Chemistry Research; Vol. 34; No. 10; 3514-3523; 10.1021/ie00037a040
• Lovalenti, Phillip M. and Brady, John F. (1995) The temporal behaviour of the hydrodynamic force on a body in response to an abrupt change in velocity at small but finite Reynolds number; Journal of Fluid Mechanics; Vol. 293; 35-46; 10.1017/S0022112095001625
• Nott, Prabhu R. and Brady, John F. (1994) Pressure-driven flow of suspensions: simulation and theory; Journal of Fluid Mechanics; Vol. 275; 157-199; 10.1017/S0022112094002326
• Brady, John F. (1994) The long-time self-diffusivity in concentrated colloidal dispersions; Journal of Fluid Mechanics; Vol. 272; 109-134; 10.1017/S0022112094004404
• Brady, John F. (1994) Response to "Comment on 'The rheological behavior of concentrated colloidal dispersions'"; Journal of Chemical Physics; Vol. 101; No. 2; 1758; 10.1063/1.467737
• Lovalenti, Phillip M. and Brady, John F. (1993) The force on a sphere in a uniform flow with small-amplitude oscillations at finite Reynolds number; Journal of Fluid Mechanics; Vol. 256; 607-614; 10.1017/S0022112093002897
• Lovalenti, Phillip M. and Brady, John F. (1993) The hydrodynamic force on a rigid particle undergoing arbitrary time-dependent motion at small Reynolds number; Journal of Fluid Mechanics; Vol. 256; 561-605; 10.1017/S0022112093002885
• Jeffrey, D. J. and Morris, J. F., et el. (1993) The pressure moments for two rigid spheres in low-Reynolds-number flow; Physics of Fluids A; Vol. 5; No. 10; 2317-2325; 10.1063/1.858795
• Lovalenti, Phillip M. and Brady, John F. (1993) The force on a bubble, drop, or particle in arbitrary time-dependent motion at small Reynolds number; Physics of Fluids A; Vol. 5; No. 9; 2104-2116; 10.1063/1.858550
• Brady, John F. (1993) The rheological behavior of concentrated colloidal dispersions; Journal of Chemical Physics; Vol. 99; No. 1; 567-581; 10.1063/1.465782
• Claeys, Ivan L. and Brady, John F. (1993) Suspensions of prolate spheroids in Stokes flow. Part 1. Dynamics of a finite number of particles in an unbounded fluid; Journal of Fluid Mechanics; Vol. 251; 411-442; 10.1017/S0022112093003465
• Claeys, Ivan L. and Brady, John F. (1993) Suspensions of prolate spheroids in Stokes flow. Part 2. Statistically homogeneous dispersions; Journal of Fluid Mechanics; Vol. 251; 443-477; 10.1017/S0022112093003477
• Claeys, Ivan L. and Brady, John F. (1993) Suspensions of prolate spheroids in Stokes flow. Part 3. Hydrodynamic transport properties of crystalline dispersions; Journal of Fluid Mechanics; Vol. 251; 479-500; 10.1017/S0022112093003489
• Brady, John F. (1993) Brownian motion, hydrodynamics, and the osmotic pressure; Journal of Chemical Physics; Vol. 98; No. 4; 3335-3341; 10.1063/1.464105
• Bonnecaze, R. T. and Brady, J. F. (1992) Dynamic simulation of an electrorheological fluid; Journal of Chemical Physics; Vol. 96; No. 3; 2183-2202; 10.1063/1.462070
• Bossis, G. and Meunier, A., et el. (1991) Hydrodynamic stress on fractal aggregates of spheres; Journal of Chemical Physics; Vol. 94; No. 7; 5064-5070; 10.1063/1.460543
• Bonnecaze, R. T. and Brady, J. F. (1991) The Effective Conductivity of Random Suspensions of Spherical Particles; Proceedings of the Royal Society A: Mathematical, physical, and engineering sciences; Vol. 432; No. 1886; 445-465; 10.1098/rspa.1991.0025
• Bonnecaze, R. T. and Brady, John F. (1991) Rate of diffusion-limited reactions in dispersions of spherical traps via multipole scattering; Journal of Chemical Physics; Vol. 94; No. 1; 537-540; 10.1063/1.460372
• Bonnecaze, R. T. and Brady, J. F. (1990) A Method for Determining the Effective Conductivity of Dispersions of Particles; Proceedings of the Royal Society of London. Series A, Mathematical, Physical and Engineering Sciences; Vol. 430; No. 1879; 285-313
• Bossis, G. and Brady, J. F. (1989) The rheology of Brownian suspensions; Journal of Chemical Physics; Vol. 91; No. 3; 1866-1874; 10.1063/1.457091
• Koch, Donald L. and Brady, John F. (1989) Anomalous diffusion due to long-range velocity fluctuations in the absence of a mean flow; Physics of Fluids A; Vol. 1; No. 1; 47-51; 10.1063/1.857522
• Phillips, R. J. and Brady, J. F., et el. (1988) Hydrodynamic transport properties of hard-sphere dispersions. I. Suspensions of freely mobile particles; Physics of Fluids; Vol. 31; No. 12; 3462-3472; 10.1063/1.866914
• Phillips, R. J. and Brady, J. F., et el. (1988) Hydrodynamic transport properties of hard-sphere dispersions. II. Porous media; Physics of Fluids; Vol. 31; No. 12; 3473-3479; 10.1063/1.866915
• Brady, John F. and Phillips, Ronald J., et el. (1988) Dynamic simulation of hydrodynamically interacting suspensions; Journal of Fluid Mechanics; Vol. 195; 257-280; 10.1017/S0022112088002411
• Koch, Donald L. and Brady, John F. (1988) Anomalous diffusion in heterogeneous porous media; Physics of Fluids; Vol. 31; No. 5; 965-973; 10.1063/1.866716
• Brady, John F. and Durlofsky, Louis J. (1988) The sedimentation rate of disordered suspensions; Physics of Fluids; Vol. 31; No. 4; 717-727; 10.1063/1.866808
• Brady, John F. and Bossis, Georges (1988) Stokesian Dynamics; Annual Review of Fluid Mechanics; Vol. 20; 111-157; 10.1146/annurev.fl.20.010188.000551
• Brady, John F. and Koch, Donald L. (1988) Dispersion in Porous Media; ISBN 978-90-247-3789-5; Disorder and Mixing; 107-122; 10.1007/978-94-009-2825-1_8
• Bossis, G. and Brady, J. F. (1988) Diffusion of Brownian hard spheres in shear flow; ISBN 9783642493393; Progress and Trends in Rheology II; 147-148; 10.1007/978-3-642-49337-9_42
• Bossis, G. and Brady, J. F. (1987) Self-diffusion of Brownian particles in concentrated suspensions under shear; Journal of Chemical Physics; Vol. 87; No. 9; 5437-5448; 10.1063/1.453708
• Durlofsky, L. and Brady, J. F. (1987) Analysis of the Brinkman equation as a model for flow in porous media; Physics of Fluids; Vol. 30; No. 11; 3329-3341; 10.1063/1.866465
• Durlofsky, L. and Brady, J. F., et el. (1987) Dynamic simulation of hydrodynamically interacting particles; Journal of Fluid Mechanics; Vol. 180; 21-49; 10.1017/S002211208700171X
• Koch, Donald L. and Brady, John F. (1987) The symmetry properties of the effective diffusivity tensor in anisotropic porous media; Physics of Fluids; Vol. 30; No. 3; 642-650; 10.1063/1.866368
• Koch, Donald L. and Brady, John F. (1987) A non-local description of advection-diffusion with application to dispersion in porous media; Journal of Fluid Mechanics; Vol. 180; 387-403; 10.1017/S0022112087001861
• Bossis, Georges and Brady, John F. (1984) Dynamic simulation of sheared suspensions. I. General method; Journal of Chemical Physics; Vol. 80; No. 10; 5141-5154; 10.1063/1.446585
• Brady, J. F. (1984) Flow development in a porous channel and tube; Physics of Fluids; Vol. 27; No. 5; 1061-1067; 10.1063/1.864735
• Durlofsky, L. and Brady, J. F. (1984) The spatial stability of a class of similarity solutions; Physics of Fluids; Vol. 27; No. 5; 1068-1076; 10.1063/1.864736