Modelling bacterial behaviour close to a no-slip plane boundary: the influence of bacterial geometry H Shum, EA Gaffney, DJ Smith Proceedings of the Royal Society A: Mathematical, Physical and Engineering …, 2010 | 179 | 2010 |
Self-propelled nanomotors autonomously seek and repair cracks J Li, OE Shklyaev, T Li, W Liu, H Shum, I Rozen, AC Balazs, J Wang Nano Letters 15 (10), 7077-7085, 2015 | 141 | 2015 |
An introduction to the hydrodynamics of swimming microorganisms JM Yeomans, DO Pushkin, H Shum The European Physical Journal Special Topics 223 (9), 1771-1785, 2014 | 95 | 2014 |
Convective flow reversal in self-powered enzyme micropumps I Ortiz-Rivera, H Shum, A Agrawal, A Sen, AC Balazs Proceedings of the National Academy of Sciences 113 (10), 2585-2590, 2016 | 92 | 2016 |
Fluid transport by individual microswimmers DO Pushkin, H Shum, JM Yeomans Journal of Fluid Mechanics 726, 5-25, 2013 | 77 | 2013 |
Harnessing catalytic pumps for directional delivery of microparticles in microchambers S Das, OE Shklyaev, A Altemose, H Shum, I Ortiz-Rivera, L Valdez, ... Nature communications 8 (1), 14384, 2017 | 72 | 2017 |
Solutal and thermal buoyancy effects in self-powered phosphatase micropumps L Valdez, H Shum, I Ortiz-Rivera, AC Balazs, A Sen Soft Matter 13 (15), 2800-2807, 2017 | 58 | 2017 |
Hydrodynamic analysis of flagellated bacteria swimming near one and between two no-slip plane boundaries H Shum, EA Gaffney Physical Review E 91 (3), 033012, 2015 | 47 | 2015 |
The effects of flagellar hook compliance on motility of monotrichous bacteria: A modeling study H Shum, EA Gaffney Physics of Fluids 24 (6), 2012 | 43 | 2012 |
Fight the flow: the role of shear in artificial rheotaxis for individual and collective motion R Baker, JE Kauffman, A Laskar, OE Shklyaev, M Potomkin, ... Nanoscale 11 (22), 10944-10951, 2019 | 42 | 2019 |
Patterns of bacterial motility in microfluidics-confining environments V Tokárová, A Sudalaiyadum Perumal, M Nayak, H Shum, O Kašpar, ... Proceedings of the National Academy of Sciences 118 (17), e2013925118, 2021 | 38 | 2021 |
Hydrodynamic analysis of flagellated bacteria swimming in corners of rectangular channels H Shum, EA Gaffney Physical review E 92 (6), 063016, 2015 | 32 | 2015 |
Designing bioinspired artificial cilia to regulate particle–surface interactions AC Balazs, A Bhattacharya, A Tripathi, H Shum The journal of physical chemistry letters 5 (10), 1691-1700, 2014 | 28 | 2014 |
Convective self-sustained motion in mixtures of chemically active and passive particles OE Shklyaev, H Shum, VV Yashin, AC Balazs Langmuir 33 (32), 7873-7880, 2017 | 27 | 2017 |
Active ciliated surfaces expel model swimmers H Shum, A Tripathi, JM Yeomans, AC Balazs Langmuir 29 (41), 12770-12776, 2013 | 27 | 2013 |
Harnessing surface-bound enzymatic reactions to organize microcapsules in solution OE Shklyaev, H Shum, A Sen, AC Balazs Science Advances 2 (3), e1501835, 2016 | 26 | 2016 |
Comment on the article by J. Elgeti, UB Kaupp, and G. Gompper: hydrodynamics of sperm cells near surfaces DJ Smith, EA Gaffney, H Shum, H Gadêlha, J Kirkman-Brown Biophysical Journal 100 (9), 2318-2320, 2011 | 23 | 2011 |
Entrainment and scattering in microswimmer-colloid interactions H Shum, JM Yeomans Physical Review Fluids 2 (11), 113101, 2017 | 22 | 2017 |
Microswimmer propulsion by two steadily rotating helical flagella H Shum Micromachines 10 (1), 65, 2019 | 21 | 2019 |
Fluid-driven motion of passive cilia enables the layer to expel sticky particles A Tripathi, H Shum, AC Balazs Soft matter 10 (9), 1416-1427, 2014 | 21 | 2014 |