| 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 | 153 | 2015 |
| Cellulose microfibril twist, mechanics, and implication for cellulose biosynthesis Z Zhao, OE Shklyaev, A Nili, MNA Mohamed, JD Kubicki, VH Crespi, ... The Journal of Physical Chemistry A 117 (12), 2580-2589, 2013 | 106 | 2013 |
| Role of Strain-Dependent Surface Energies in Island Formation OE Shklyaev, MJ Beck, M Asta, MJ Miksis, PW Voorhees Physical review letters 94 (17), 176102, 2005 | 101 | 2005 |
| Stability of an evaporating thin liquid film OE Shklyaev, E Fried Journal of Fluid Mechanics 584, 157-183, 2007 | 80 | 2007 |
| 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 | 75 | 2017 |
| Chemical pumps and flexible sheets spontaneously form self-regulating oscillators in solution RK Manna, OE Shklyaev, AC Balazs Proceedings of the National Academy of Sciences 118 (12), e2022987118, 2021 | 68 | 2021 |
| Thermocapillary flows under an inclined temperature gradient OE Shklyaev, AA Nepomnyashchy Journal of Fluid Mechanics 504, 99-132, 2004 | 50 | 2004 |
| 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 | 46 | 2019 |
| Light-powered, fuel-free oscillation, migration, and reversible manipulation of multiple cargo types by micromotor swarms J Zhang, A Laskar, J Song, OE Shklyaev, F Mou, J Guan, AC Balazs, ... ACS nano 17 (1), 251-262, 2022 | 40 | 2022 |
| Self-organization of fluids in a multienzymatic pump system S Maiti, OE Shklyaev, AC Balazs, A Sen Langmuir 35 (10), 3724-3732, 2019 | 39 | 2019 |
| Organization of Particle Islands through Light‐Powered Fluid Pumping BM Tansi, ML Peris, OE Shklyaev, AC Balazs, A Sen Angewandte Chemie 131 (8), 2317-2321, 2019 | 30 | 2019 |
| Harnessing surface-bound enzymatic reactions to organize microcapsules in solution OE Shklyaev, H Shum, A Sen, AC Balazs Science Advances 2 (3), e1501835, 2016 | 29 | 2016 |
| 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 | 28 | 2017 |
| Designing self-propelled, chemically active sheets: Wrappers, flappers, and creepers A Laskar, OE Shklyaev, AC Balazs Science Advances 4 (12), eaav1745, 2018 | 27 | 2018 |
| Harnessing the power of chemically active sheets in solution RK Manna, A Laskar, OE Shklyaev, AC Balazs Nature Reviews Physics 4 (2), 125-137, 2022 | 26 | 2022 |
| Modeling electrostatically induced collapse transitions in carbon nanotubes OE Shklyaev, E Mockensturm, VH Crespi Physical review letters 106 (15), 155501, 2011 | 22 | 2011 |
| Constraints on cellulose twist from DFT calculations of NMR chemical shifts OE Shklyaev, JD Kubicki, HD Watts, VH Crespi Cellulose 21, 3979-3991, 2014 | 21 | 2014 |
| Using chemical pumps and motors to design flows for directed particle assembly OE Shklyaev, H Shum, AC Balazs Accounts of chemical research 51 (11), 2672-2680, 2018 | 20 | 2018 |
| Interlinking spatial dimensions and kinetic processes in dissipative materials to create synthetic systems with lifelike functionality OE Shklyaev, AC Balazs Nature Nanotechnology 19 (2), 146-159, 2024 | 19 | 2024 |
| Chemically controlled shape-morphing of elastic sheets RK Manna, OE Shklyaev, HA Stone, AC Balazs Materials Horizons 7 (9), 2314-2327, 2020 | 19 | 2020 |
