An Untethered Magnetic‐ and Light‐Responsive Rotary Gripper: Shedding Light on Photoresponsive Liquid Crystal Actuators

Cunha, Marina Pilz da; Foelen, Yari; Raak, Roel J. H. van; Murphy, Jeffrey J.; Engels, Tap Tom; Debije, Michael G.; Schenning, Albert P. H. J.

doi:10.1002/adom.201801643

“…The thermoplastic actuator was fabricated using a scalable spray‐coating method, depositing the light‐responsive LCs from xylene on a biaxially stretched 12 μm thick PET polymer (Figure S1 in the Supporting Information) . The sprayed nematic LC mixture (Figure S2) self‐aligned in a splay molecular alignment on the PET, see Figure S3 .…”

Section: Resultsmentioning

confidence: 99%

Liquid Crystal Networks on Thermoplastics: Reprogrammable Photo‐Responsive Actuators

Verpaalen

¹

,

Cunha

²

,

Engels

³

et al. 2020

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Arbitrary shape (re)programming is appealing for fabricating untethered shape‐morphing photo‐actuators with intricate configurations and features. We present re‐programmable light‐responsive thermoplastic actuators with arbitrary initial shapes through spray‐coating of polyethylene terephthalate (PET) with an azobenzene‐doped light‐responsive liquid crystal network (LCN). The initial geometry of the actuator is controlled by thermally shaping and fixing the thermoplastic PET, allowing arbitrary shapes, including origami‐like folds and left‐ and right‐handed helicity within a single sample. The thermally fixed geometries can be reversibly actuated through light exposure, with fast, reversible area‐specific actuation such as winding, unwinding and unfolding. By shape re‐programming, the same sample can be re‐designed and light‐actuated again. The strategy presented here demonstrates easy fabrication of mechanically robust, recyclable, photo‐responsive actuators with highly tuneable geometries and actuation modes.

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“…The thermoplastic actuator was fabricated using a scalable spray-coating method, depositing the light-responsive LCs from xylene on a biaxially stretched 12 mm thick PET polymer ( Figure S1 in the Supporting Information). [36][37][38] The sprayed nematic LC mixture ( Figure S2) self-aligned in a splay molecular alignment on the PET, see Figure S3. [37] The LC mixture was photopolymerized in the nematic phase at 85 8C for 10 minutes in an inert nitrogen atmosphere ( Figure S4).…”

Section: Resultsmentioning

confidence: 99%

Liquid Crystal Networks on Thermoplastics: Reprogrammable Photo‐Responsive Actuators

Verpaalen

¹

,

Cunha

²

,

Engels

³

et al. 2020

Self Cite

View full text Add to dashboard Cite

Arbitrary shape (re)programming is appealing for fabricating untethered shape‐morphing photo‐actuators with intricate configurations and features. We present re‐programmable light‐responsive thermoplastic actuators with arbitrary initial shapes through spray‐coating of polyethylene terephthalate (PET) with an azobenzene‐doped light‐responsive liquid crystal network (LCN). The initial geometry of the actuator is controlled by thermally shaping and fixing the thermoplastic PET, allowing arbitrary shapes, including origami‐like folds and left‐ and right‐handed helicity within a single sample. The thermally fixed geometries can be reversibly actuated through light exposure, with fast, reversible area‐specific actuation such as winding, unwinding and unfolding. By shape re‐programming, the same sample can be re‐designed and light‐actuated again. The strategy presented here demonstrates easy fabrication of mechanically robust, recyclable, photo‐responsive actuators with highly tuneable geometries and actuation modes.

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“…The bilayer actuator consists of a photoresponsive LCN (20 µm in thickness) and a PDMS layer of varying thicknesses (50, 130, and 210 µm). The liquid crystal polymer is a splay aligned network, composed of two LC monomers (M1, 56.5 mol% and M2, 40.5 mol%,), a photo responsive azobenzene dopant (A1, 2 mol%) and a photoinitiator (PI, 1 mol%) (Figure S1, Supporting Information): film preparation follows previously reported methods . In splay alignment, the LC molecules at the opposing surfaces of the film have different orientations: one has a planar alignment in which the molecules are oriented parallel to the surface, and the other a homeotropic with molecules aligned perpendicular to the surface (Figure A).…”

Section: Resultsmentioning

confidence: 99%

“…In our previous work, we revealed the mechanism for the light triggered response of a liquid crystal network doped with a fast isomerizing azobenzene . The single films studied display an unbending actuation upon illumination from a precurled shape into an extended film, the actuation motion independent from the illumination direction.…”

Section: Introductionmentioning

confidence: 95%

On Untethered, Dual Magneto‐ and Photoresponsive Liquid Crystal Bilayer Actuators Showing Bending and Rotating Motion

Cunha

¹

,

Foelen

²

,

Engels

³

et al. 2019

Advanced Optical Materials

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The integration of untethered, multi‐stimuli responsive actuation into soft microrobotic devices is a goal in the development of “smart” materials. This manuscript reports on a dual‐stimuli responsive bilayer actuator consisting of a light responsive liquid crystal network (LCN) and a magnetic responsive polydimethylsiloxane (PDMS) composite. This design is of facile fabrication with ample design freedom, using no additional adhesion layers. Untethered control of the bilayer permits motions including bending and rotation, steered individually or in synchronization. Through a systematic study the direct impact of the PDMS layer was elucidated on the light triggered rate of actuation and maximum deformation amplitude of the LCN film. The alignment (homeotropic or planar) of the LCN has a profound effect on the resulting bilayer actuation. It is demonstrated, both experimentally and theoretically, that the rates of sample heating and actuation are directly correlated and highlight the critical role of the PDMS as a heat sink. The maximum amplitude of displacement of the bilayer is tied to the stiffness, being inversely correlated to the PDMS thickness to the third power. These results give insights and provide straightforward design rules to fabricate bilayer actuators with programmed multi‐responsive properties.

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An Untethered Magnetic‐ and Light‐Responsive Rotary Gripper: Shedding Light on Photoresponsive Liquid Crystal Actuators

Cited by 86 publications

References 39 publications

Liquid Crystal Networks on Thermoplastics: Reprogrammable Photo‐Responsive Actuators

Liquid Crystal Networks on Thermoplastics: Reprogrammable Photo‐Responsive Actuators

Liquid Crystal Networks on Thermoplastics: Reprogrammable Photo‐Responsive Actuators

On Untethered, Dual Magneto‐ and Photoresponsive Liquid Crystal Bilayer Actuators Showing Bending and Rotating Motion

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