Kai Zhao scite author profile

Self-propelling microparticles are often proposed as synthetic models for biological microswimmers, yet they lack the internally regulated adaptation of their biological counterparts. Conversely, adaptation can be encoded in larger-scale soft-robotic devices but remains elusive to transfer to the colloidal scale. Here, we create responsive microswimmers, powered by electro-hydrodynamic flows, which can adapt their motility via internal reconfiguration. Using sequential capillary assembly, we fabricate deterministic colloidal clusters comprising soft thermo-responsive microgels and light-absorbing particles. Light absorption induces preferential local heating and triggers the volume phase transition of the microgels, leading to an adaptation of the clusters’ motility, which is orthogonal to their propulsion scheme. We rationalize this response via the coupling between self-propulsion and variations of particle shape and dielectric properties upon heating. Harnessing such coupling allows for strategies to achieve local dynamical control with simple illumination patterns, revealing exciting opportunities for developing tactic active materials.

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Continuous separation of nanoparticles by type via localized DC-dielectrophoresis using asymmetric nano-orifice in pressure-driven flow

Zhao

2017

Sensors and Actuators B: Chemical

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A novel POI recommendation method based on trust relationship and spatial–temporal factors

Ding

Zhao

2021

Electronic Commerce Research and Applications

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Continuous Cell Characterization and Separation by Microfluidic Alternating Current Dielectrophoresis

et al. 2019

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A novel alternating current (ac)-dielectrophoretic (DEP) microfluidic chip for continuous cell characterization and separation is presented in this paper. To generate DEP forces, two electrode-pads are embedded in a set of asymmetric orifices on the opposite sidewalls to produce the nonuniform electric fields. In the vicinity of a small orifice, the cells experience the strongest nonuniform gradient and are drawn toward it by the positive DEP forces, while the cells experiencing a negative DEP force are repelled away and move toward the large orifice. The DEP behaviors of yeast cells in suspending media with different ionic concentrations, i.e., different electrical conductivities, and over a large range of the ac electric field frequency were investigated. Furthermore, the lateral migrations of yeast cells as a function of the ac frequency were measured. The trends of measured lateral migrations of yeast cells are similar to the corresponding Clausius−Mossotti (CM) factors. In addition, by adjusting the frequency and strength of the ac electric field, the continuous separation of live and dead yeast cells as well as the yeast cells with targeted diameter and dielectric property can be easily achieved. This is the first time that the measurement of ac-DEP lateral migration of yeast cells in solutions with different electrical conductivities as a function of the applied frequency in a microfluidic chip was reported. This ac-DEP system provides a method to characterize the crossover frequency of the specific cells and manipulate the targeted cells.

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Kai Zhao

Forecasting Chinese CO2 emissions from fuel combustion using a novel grey multivariable model

Reconfigurable artificial microswimmers with internal feedback

Continuous separation of nanoparticles by type via localized DC-dielectrophoresis using asymmetric nano-orifice in pressure-driven flow

A novel POI recommendation method based on trust relationship and spatial–temporal factors

Continuous Cell Characterization and Separation by Microfluidic Alternating Current Dielectrophoresis

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