Photocatalytic Micro/Nanomotors: From Construction to Applications

Dong, Renfeng; Cai, Yue‐Peng; Yang, Yiran; Gao, Wei; Ren, Biye

doi:10.1021/acs.accounts.8b00249

Cited by 143 publications

(101 citation statements)

References 59 publications

(124 reference statements)

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“…To date, several hybrid motor designs have successfully integrated dual‐powered engines, including chemical/light, magnetic/acoustic, chemical/magnetic, chemical/acoustic controlled operations. Among the different power sources, light is an attractive remote stimulus for generating an effective and extended micro/nanomotor propulsion in connection to variety of photoresponsive materials with different light intensities and wavelengths . Acoustic stimulus also attracts a tremendous recent attention due to distinct advantages, including fuel‐free, noninvasive, and salt‐tolerant motion The combination of light and acoustic propulsions holds considerable promise for expanding the scope of hybrid micromotors and for designing advanced microvehicles with adaptive operation in dynamically changing environments.…”

Section: Introductionmentioning

confidence: 99%

Structure‐Dependent Optical Modulation of Propulsion and Collective Behavior of Acoustic/Light‐Driven Hybrid Microbowls

Tang

Zhang

Zhao

et al. 2019

Adv Funct Materials

120

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Hybrid light/acoustic-powered microbowl motors, composed of gold (Au) and titanium dioxide (TiO 2 ) with a structure-dependent optical modulation of both their movement and collective behavior are reported by reversing the inner and outer positions of Au and TiO 2 . The microbowl propels in an acoustic field toward its exterior side. UV light activates the photochemical reaction on the TiO 2 surface in the presence of hydrogen peroxide and the Au/TiO 2 system moves toward its TiO 2 side by self-electrophoresis. Controlling the light intensity allows switching of the dominant propulsion mode and provides braking or reversal of motion direction when TiO 2 is on the interior, or accelerated motion when the TiO 2 is on its exterior. Theoretical simulations offer an understanding of the acoustic streaming flow and self-electrophoretic fluid flow induced by the asymmetric distribution of ions around the microbowl. The light-modulation behavior along with the tunable structure also leads to the control of the swarm behaviors under the acoustic field, including expansion or compaction of ensembles of microbowls with interior and exterior TiO 2 , respectively. Such structure-dependent motion control thus paves the way for a variety of complex microscale operations, ranging from cargo transport to drug delivery in biomedical and environmental applications.

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Section: Introductionmentioning

confidence: 99%

Structure‐Dependent Optical Modulation of Propulsion and Collective Behavior of Acoustic/Light‐Driven Hybrid Microbowls

Tang

Zhang

Zhao

et al. 2019

Adv Funct Materials

120

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“…TiO 2 is an attractive material for the construction of catalytic micromotors due to stability and resistance to catalyst poisoning. Potentially more importantly, TiO 2 is a photocatalyst, and so self‐propulsion can be switched on‐and‐off, and the strength of activity can be modulated in real‐time by adjusting the intensity of the activating light source . It should be noted that in photocatalytic active colloidal matter, the particles are still autonomous, with motion being determined by thermal fluctuations that couple to the directed self‐propelled motion, despite the strength of propulsion being modifiable.…”

mentioning

confidence: 99%

Engineering the Dynamics of Active Colloids by Targeted Design of Metal–Semiconductor Heterojunctions

Gibbs

Sarkar

Holterhoff

et al. 2019

Adv Materials Inter

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COMMUNICATION (1 of 7)Colloidal particles suspended in a fluid may become self-propelling when a catalyzed chemical reaction takes place at the interface between the particle and the fluid through which motion occurs. [1][2][3][4][5][6][7][8][9] If this reaction generates a local concentration gradient, [10] a chemiosmotic flow [11] over the particle's surface may arise. Such fluid flow is usually responsible for self-propulsion. This way of achieving active nano-and microscale autonomous motion is attractive since external fields, such as electric, [12] magnetic, [13][14][15][16][17][18] light, [19] or acoustic, [20,21] do not need to be applied, and moreover, nonequilibrium self-propelled systems

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“…TiO 2 ‐based micromotors move autonomously under UV illumination through a self‐electrophoresis mechanism triggered by the formation of a proton gradient and local electric field . In addition they have shown the capacity of “on‐the‐fly” photodegradation of organic pollutants by concomitant redox reactions . However, it is difficult for microscale‐devices to be efficient in large‐volume conditions due to their limited size and velocity and which impede their practical use in real environment like river, lake, or sea.…”

Section: Resultsmentioning

confidence: 99%

Self‐Propelled 3D‐Printed “Aircraft Carrier” of Light‐Powered Smart Micromachines for Large‐Volume Nitroaromatic Explosives Removal

Kong

Ambrosi

Nasir

et al. 2019

Adv Funct Materials

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Self-propelled micro-/nanomotors are in the forefront of materials research, for applications ranging from environmental remediation to biomedicine. However, due to their limited sizes, they can only navigate within small distances, typically in the order of millimeters, which inevitably hinder their use for large-volume real applications. Here it is shown that a 3D-printed millimeter-scale motor (3DP-motor) can act as "aircraft carrier" of TiO 2 /Pt Janus micromotors and be used for enhanced large-volume environmental remediation applications. The 3DP-motor can move fast for tens of meters through the Marangoni effect by asymmetrically releasing ethanol. During its navigation, this 3DP-motor can carry and slowly release in solution TiO 2 /Pt Janus micromotors which can be propelled by light illumination while acting as photodegradation agents. Highly efficient degradation of nitroaromatic explosives over a large solution area is achieved. A wall-following motion of the 3DP-motor without external guidance is also demonstrated which is generated by the chemiosmotic flow at the wall vicinity. This can be easily tuned by changing the wettability of the wall surface and also modifying the shape of 3DP-motor, leading to different motion behaviors. This work introduces a new concept of micromotors carried by large millimeter sized motors to traverse long distances and it should find a broad range of applications.

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Photocatalytic Micro/Nanomotors: From Construction to Applications

Cited by 143 publications

References 59 publications

Structure‐Dependent Optical Modulation of Propulsion and Collective Behavior of Acoustic/Light‐Driven Hybrid Microbowls

Structure‐Dependent Optical Modulation of Propulsion and Collective Behavior of Acoustic/Light‐Driven Hybrid Microbowls

Engineering the Dynamics of Active Colloids by Targeted Design of Metal–Semiconductor Heterojunctions

Self‐Propelled 3D‐Printed “Aircraft Carrier” of Light‐Powered Smart Micromachines for Large‐Volume Nitroaromatic Explosives Removal

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