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[ Author(Desc)] Title Type Year
B
Baker, R. et al. Fight the flow: the role of shear in artificial rheotaxis for individual and collective motion. Nanoscale 11, 10944-10951 (2019).
Balazs, A.C., Bhattacharya, A., Tripathi, A. & Shum, H. Designing bioinspired artificial cilia to regulate particle–surface interactions. The Journal of Physical Chemistry Letters 5, 10, 1691-1700 (2014).
D
Das, S. et al. Harnessing catalytic pumps for directional delivery of microparticles in microchambers. Nature Communications 8, 14384 (2017). das_et_al_2017_-_harnessing_catalytic_pumps_for_directional_delivery_of_microparticles_in_microchambers.pdf
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Ghadami, S. & Shum, H. Designing a magnetic micro-robot for transporting stiff filamentous microcargo. Physics of Fluids 36, 081908 (2024). Ghadami Shum 2024 - Designing a magnetic micro-robot.pdf
H
Huffman, A. & Shum, H. Boundary-bound reactions: Pattern formation with and without hydrodynamics. Physical Review E 108, 055103 (2023). Huffman Shum 2023 - Boundary-bound reactions preprint.pdf
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Li, J. et al. Self-propelled nanomotors autonomously seek and repair cracks. Nano Letters 15, 10, 7077-7085 (2015).
M
Marchello, R., Morandotti, M., Shum, H. & Zoppello, M. The N-link swimmer in three dimensions: controllability and optimality results. Acta Applicandae Mathematicae 178, 6 (2022).
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Nikolov, S.V., Shum, H., Balazs, A.C. & Alexeev, A. Computational design of microscopic swimmers and capsules: From directed motion to collective behavior. Current Opinion in Colloid & Interface Science 21, 44-56 (2015).
Nourian, V. & Shum, H. Modeling of uniflagellated bacterial locomotion in unbounded fluid and near a no-slip plane surface. (Submitted).at <https://arxiv.org/abs/2307.00223>
Nourian, V. & Shum, H. A numerical method for the locomotion of bi-flagellated bacteria in viscous fluid. Flow 3, E4 (2023). a-numerical-method-for-the-locomotion-of-bi-flagellated-bacteria-in-viscous-fluid.pdf
O
Ortiz-Rivera, I., Shum, H., Agrawal, A., Sen, A. & Balazs, A.C. Convective flow reversal in self-powered enzyme micropumps. Proceedings of the National Academy of Sciences of the United States of America 113, 10, 2585-2590 (2016). ortiz-rivera_et_al._-_2016_-_convective_flow_reversal_in_self-powered_enzyme_mi.pdf
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Pushkin, D.O., Shum, H. & Yeomans, J.M. Fluid transport by individual microswimmers. Journal of Fluid Mechanics 726, 5-25 (2013).
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Rivas, D.P., Shah, Z.H., Shum, H. & Das, S. Alignment, rising, sticking, and phototaxis: modulating the behavior of hematite micropeanuts. Advanced Material Interfaces 2400741 (2024).at <https://doi.org/10.1002/admi.202400741>
S
Shklyaev, O.E., Shum, H. & Balazs, A.C. Achieving self-sustained motion of particles in solution with chemical pumps. Robotic Systems and Autonomous Platforms 223-249 (2019).at <https://www.sciencedirect.com/science/article/pii/B978008102260300010X>
Shklyaev, O.E., Shum, H. & Balazs, A.C. Using chemical pumps and motors to design flows for directed particle assembly. Accounts of Chemical Research 51, 11, 2672-2680 (2018).
Shklyaev, O., Shum, H., Yashin, V.V. & Balazs, A.C. Convective self-sustained motion in mixtures of chemically active and passive particles. Langmuir 33, 32, 7873-7880 (2017).
Shklyaev, O.E., Shum, H., Sen, A. & Balazs, A.C. Harnessing surface-bound enzymatic reactions to organize microcapsules in solution. Science Advances 2, 3, e1501835 (2016). shklyaev_et_al._-_2016_-_harnessing_surface-bound_enzymatic_reactions_to_or.pdf
Shum, H., Palaniappan, D. & Young, Y.-N. Hydrodynamic interactions between a sedimenting squirmer and a planar wall. Journal of Fluid Mechanics 1010, A24 (2025).
Shum, H., Zoppello, M., Astwood, M. & Morandotti, M. Control of microparticles through hydrodynamic interactions. Journal of Fluid Mechanics 1004, A4 (2025).
Shum, H. Microswimmer propulsion by two steadily rotating helical flagella. Micromachines 10, 1, 65 (2019).

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