Yufan
Ji
and
Haifeng
Yu
*
School of Material Science and Engineering, Key Laboratory of Polymer Chemistry and Physics of Ministry of Education, Peking University, Beijing, 100871, China. E-mail: yuhaifeng@pku.edu.cn
First published on 26th June 2024
As a smart material, photoresponsive liquid-crystalline polymers exhibit interestingly tunable properties from the nanoscale to the macroscale, which are attributed to their combination of liquid crystal ordering and photoswitchable features. An azobenzene-containing liquid-crystalline polymer is a typical representative, which has been studied from many different aspects. However, the lack of research on the structure–performance relationship and multi-scale manipulation has limited its applications in a broader field. Over the past few years, great efforts have been devoted to achieving the control at multiple scales using light, which has promoted their applications in the fields of energy storage, advanced anticounterfeiting and switchable adhesion. Here, we summarize recent progress in photoresponsive liquid-crystalline polymers, including molecular design, fabrication techniques and the manipulation mechanism from the nanoscale to the micrometre scale and then the macroscale. Their various applications based on abundant photoresponsive properties are systematically summarized. Finally, the existing challenges and opportunities in this field are discussed.
Yufan Ji | Yufan Ji is currently a PhD candidate at Peking University. His current research interests focus on fabricating micro/nanostructures using azobenzene-containing photoresponsive materials. |
Typically, an azobenzene (AZ)-containing polymer (or azopolymer) is one of the most studied photoresponsive polymers,28–32 since its photoisomerization is a simple and fast process, which is more suitable for the construction of photoresponsive systems. Additionally, AZ in its trans form can be used as a mesogen due to its rod-like geometry, while its cis state with a bent shape is induced upon UV illumination (Fig. 1), which is often isotropic at room temperature.15 Moreover, trans-AZ groups have unique properties of liquid crystals (LCs): mesogenic self-assembly, molecular cooperative motion, optical anisotropy and birefringent behaviours. The LC phase is a special state of matter, where the most important feature is that the mesogenic molecule has a director, so it will expand perpendicularly to the director and contract along the director upon phase transition at the clearing point (Ti) upon heating.33 For trans-AZ mesogens or AZ-containing LC systems, another way to achieve the above-mentioned phenomenon is photoisomerization upon UV light irradiation since the order parameters can be decreased by the photoisomerization and the following molecular cooperative motion.34–36 Furthermore, cis-AZ is thermally unstable, and it often recovers to its trans state spontaneously. Also, suitable-wavelength visible-light irradiation or thermal treatment can achieve the cis-to-trans back-isomerization. This reversible isomerization process can be completed in a timescale from femtoseconds to several seconds depending on the kind of AZ moities,36–38 offering the possibility of applications in various fields.
Fig. 1 Schematic illustration of the manipulation of photoresponsive LCPs at multiple scales: the molecular scale, nanoscale, micrometre scale, and macroscale. Reproduced from ref. 39; copyright 2006, Wiley-VCH; reproduced from ref. 40; copyright 2007, American Chemical Society; reproduced from ref. 41; copyright 2017, American Chemical Society; reproduced from ref. 42; copyright 2018, American Chemical Society; reproduced from ref. 43; copyright 2020, Wiley-VCH; reproduced from ref. 44; copyright 2019, Wiley-VCH; reproduced from ref. 45; copyright 2019, The Royal Society of Chemistry. |
In this review, we discuss recent progress in the manipulation of photoresponsive liquid-crystalline polymers (LCPs) at multiple scales (Fig. 1). Considering that the switchable topographical deformation and numerous applications of LCPs have been reviewed previously,15,46–48 here we focus on multi-scale manipulation of LCPs from the nanoscale, and the micrometre scale to the macroscale. Firstly, we focus on the construction method of different material systems. Then, we discuss the manipulation of nanostructures and hierarchically supramolecular self-assembly in liquid-crystalline block copolymers (LCBCs). Subsequently, we highlight the fabrication techniques of microstructures in different LCPs. Moreover, the development of photo-actuation devices and their manipulation mechanisms have been systematically reviewed. Then, we present some potential applications in energy storage, advanced anticounterfeiting and switchable adhesion. Finally, we summarize this review and provide some promising prospects in this field.
Fig. 2 (a) Schematic illustration of the influence of pH value on the HB formation of PM6AzCOOH. (b) Transmission electron microscopy (TEM) images of PM6AzCOOH/DMF + water at pH = 3 (left), pH = 7 (middle), and pH = 13 (right). Reproduced from ref. 50; copyright 2015, The Royal Society of Chemistry. (c) Chemical structures of the azopyridine-containing polymer (PM11AzPy), oleic acid (OA), and the compound PM11AzPy-OA (1:1) gel. (d) POM images of the PM11AzPy-OA gel with different molar ratios. (e) Field emission scanning electron microscopy (FESEM) images of the PM11AzPy-OA gel with different molar ratios. Reproduced from ref. 52; copyright 2019, American Chemical Society. |
XB is an emerging topic in recent years, which can be described in general as D⋯X–Y, where X is an electrophilic halogen atom, D is the donor of electron density, and Y is a carbon, nitrogen or halogen atom.55 A series of photoresponsive XB complexes were successfully obtained using azopyridine-containing derivatives with molecular iodine or bromine (Fig. 3a).56 According to polarized optical microscopy (POM) results, photoinduced phase transition from the LC to the isotropic phase occurred in the iodine-bonded complex upon UV illumination, and the LC texture can be recovered under visible-light irradiation (Fig. 3b), just like other photoresponsive LC materials.57–59 However, there is no photochemical phase transition in bromine-bonded LC materials, exhibiting high mesophase stability in this system.
Fig. 3 (a) Molecular structures of the photoresponsive XB complexes. (b) POM images of an iodine-bonded complex upon UV illumination and then visible-light irradiation. Reproduced from ref. 56; copyright 2014, The Royal Society of Chemistry. (c) Chemical structures, schemes, and simulation results of the supramolecular system. (d) 1H NMR of the compounds at 25 °C (orange line) and −30 °C (blue line), where the characteristic peaks of the cation–π interaction are marked as blue solid circles and those of the cis-isomer are marked as orange hollow circles. Reproduced from ref. 60; copyright 2022, American Chemical Society. |
The cation–π interaction is the “youngest” supramolecular interaction compared to the above-mentioned HB and XB, which was first named by Dougherty in 1996.61 The mechanism of this special interaction is different from the HB.62 Based on these properties, our group originally proposed a method to fabricate a supramolecular system by introducing the cation–π interaction into AZ-containing materials (Fig. 3c).60 By comparing 1H nuclear magnetic resonance (NMR) spectra at room temperature and −30 °C, the increased chemical shift could be observed, which is different from the peak of the cis-isomer (Fig. 3d), demonstrating the existence of the cation–π interaction. This interaction is of great importance to applications in biological and medical fields.63–65 Besides, amphiphilic and ionic interactions can be used to fabricate self-assembled nanofibers using low-molecular-weight azopyridinium salts with different additional components.66–68
Fig. 4 (a) Molecular structures and POM images of the azopolymer with a photo-switchable Tg. Scale bars are all 10 μm. (b) Frequency sweep of PM6AZC4 in the trans state. (c) Frequency sweep of PM6AZC4 in the cis state. (d) Temperature sweep of PM6AZC4 in the trans state. (e) Temperature sweep of PM6AZC4 in the cis state. Reproduced from ref. 43; copyright 2020, Wiley-VCH. |
These results are consistent with the differential scanning calorimetry (DSC) results, demonstrating the successful construction of a homopolymer system with a photo-switchable Tg.
Fig. 5 (a) Molecular structure and atomic force microscopy (AFM) height (left) and phase (right) images of the LCBC film after rubbing and annealing treatment. Reproduced from ref. 39; copyright 2006, Wiley-VCH. (b) Chemical structure and AFM height (left) and phase (right) images of the LCBC film upon irradiation. The bottom image is the AFM phase image in a larger area. Reproduced from ref. 72; copyright 2006, American Chemical Society. |
Another interesting LCBC system is an ABA-type triblock copolymer (TBC). It is well-known that there is physical cross-linking in polystyrene-b-polybutadiene-b-polystyrene (SBS),73,74 where the hard segment with a high Tg acts as a “physical cross-linker” and the soft segment with a low Tg functions as an elastic strand in the network.75 To mimic this phase behaviour, a well-defined SBS-like structure including an azopolymer as the middle block and polystyrene (PS) as the end blocks was designed, as shown in Fig. 6a.76 The Tg of this azopolymer in the middle block is higher than room temperature, so its trans state exhibits stiffness at room temperature (Fig. 6b). After UV irradiation, the Tg of the azopolymer drops below 0 °C, which can act as soft domains, while the PS block with a Tg higher than room temperature serves as a “physical cross-linker” (Fig. 6b), allowing this TBC to behave as an elastomer.
Fig. 6 (a) Molecular structures of the AZ-containing TBC. (b) Schematic illustration of the AZ-containing TBC and the nanostructures of this TBC film before and after UV irradiation. Reproduced from ref. 76; copyright 2022, American Association for the Advancement of Science. |
To take full advantage of sunlight for the photo-actuation of composite films, homodispersed GO, a nematic LC molecule (5CB) and a photoresponsive AZ molecule (5CAZ) shown in Fig. 7a were introduced into the poly(vinyl alcohol) (PVA)-dispersed LC system.77 Then, the stretched PDLC/GO composite film could respond to near-infrared (NIR) light or visible-light at room temperature (Fig. 7a). Upon irradiation, the film bent toward the light source along the stretching direction when its LC-rich layer faced the light source, while the bending direction is opposite if the other face of the film was irradiated.77 The reason for this interesting photomechanical deformation is that the photothermal effect of GO leads to the temperature rise of the film. When the temperature was higher than the Ti of the LC mixture, the phase transition from the LC to the isotropic occurred. Therefore, molecular contraction along the stretching direction in the LC-rich layer is much more than that in the LC-poor layer, resulting in a different bending direction. Moreover, phase transition from the nematic LC to the isotropic phase could occur upon exposure to UV light, since the photoisomerization of 5CAZ would bring about the photochemical phase transition. Hence, the composite film bent upon UV illumination, similarly to that actuated by NIR or visible-light (Fig. 7a). In addition, the results remained the same when the PVA matrix was replaced with shape-memory polyurethane (SMPU).78 Similarly, the SMPU-based composite system consisting of 5CAZ and upconversion nanoparticles (UCNPs) could respond to UV-Vis-NIR light.79 This design prevents the temperature rise of the film since the UCNPs can convert NIR light into green fluorescence, causing 5CAZ to undergo trans–cis isomerization, which is different from the photothermal mechanism of the PDLC/GO nanocomposite system.
Fig. 7 (a) Schematic illustration of the NIR-Vis-UV light-responsive composite film composed of GO and the LC mixture. Reproduced from ref. 77; copyright 2015, American Chemical Society. (b) Molecular structures of the AZ derivative and its reversible photo-liquefaction from a crystal to an isotropic liquid. A schematic illustration of the bilayer actuator composed of the AZ derivative and the LDPE film is also provided. Reproduced from ref. 80; copyright 2018, The Royal Society of Chemistry. |
Another composite system was fabricated by dropwise coating a tetrahydrofuran (THF) solution of an AZ derivative on the mechanically-rubbed LDPE film and then annealing at a certain temperature.80 The composite film bent towards the AZ layer when exposed to UV light, which is in agreement with other systems.77,81 The AZ derivative used in this system could undergo a photoinduced transition directly from a crystal to an isotropic liquid upon UV irradiation due to photoisomerization and the decreased melting point, as shown in Fig. 7b. Moreover, the rubbing-induced microgrooves on the LDPE film surface and the good fluidity of the AZ derivative during the thermal annealing process could facilitate the AZ orientation along the microgroove (Fig. 7b). Then, the photoinduced phase transition of the aligned AZ derivative would drive the whole film to bend towards the AZ layer.
Furthermore, a bilayer composite film composed of the AZ-containing LCP and the Kapton substrate was fabricated using a facile drop casting method.45 One homopolymer PM6ABOC2 and two random copolymers P(M6ABOC2x-r-M6AzPy1−x) were synthesized (Fig. 8a), where introduction of the pyridine group offered a cross-linking site. After drop casting the LCP solution on the Kapton film, the composite film was then annealed at the LC temperature to obtain an oriented nematic phase (Fig. 8b). Subsequently, the annealed film was cross-linked by the quaternization reaction using 1,4-diidonetetra-butane vapor (Fig. 8b). So far, the bilayer composite film exhibiting photoinduced bending towards the Kapton layer upon UV illumination has been prepared successfully.
Fig. 8 (a) Molecular structures and schematic illustration of the bilayer film. (b) Scheme of the drop casting method to prepare the bilayer composite film. Reproduced from ref. 45; copyright 2019, The Royal Society of Chemistry. |
Fig. 9 (a)–(e) The variation of the MPS nanostructures in the LCBC film after UV illumination. (f) MPS nanostructures after reannealing at 145 °C. Reproduced from ref. 41; copyright 2017, American Chemical Society. (g) AFM phase image of the photopatterned film with PSSNa coating after reannealing at 125 °C. (h) UV-Vis absorption spectra during the whole process. Reproduced from ref. 82; copyright 2019, American Chemical Society. (i) The variation in the AFM phase image after the introduction of the XB and 460 nm linearly polarized light (LPL) irradiation. Reproduced from ref. 83; copyright 2020, American Chemical Society. |
Another more sophisticated system is based on the supramolecular XB interaction between 1,2-diiodo-3,4,5,6-tetrafluorobenzene and one non-mesogenic block copolymer composed of PEO and azopyridine-containing polymethacrylate,83 as shown in Fig. 9i. Generally, a XB is more directional than a HB, which results in the formation of highly ordered supramolecular mesogenic ordering. So the introduction of XB-driven supramolecular self-assembly enhanced the ordering of the MPS nanostructures in the polymer film.83 Furthermore, upon actinic LPL irradiation, the PEO nanocylinders were aligned consistent with the orientation of the supramolecular mesogens, demonstrating that this XB-involved LCBC system is promising for applications in optics.
Fig. 10 (a) Chemical structure of the urethane-containing LCBC system. (b) and (c) Structural models of two kinds of HBs. (d) AFM height image and cross-sectional profile of the annealed urethane-containing LCBC film. Reproduced from ref. 86; copyright 2018, Wiley-VCH. (e) Chemical structures of the LCBC and chiral additives. (f) AFM images of the LCBC composite films after being annealed for 1200 min. The dopant was L-TA (left) or D-TA (right). (g) AFM images of annealed films doped with L-TA (top) or D-TA (bottom) upon UV illumination for 1 s and then being annealed for 1200 min. Reproduced from ref. 87; copyright 2018, Wiley-VCH. |
In addition, helical nanostructures can be prepared by using LCBC doped with functional chiral additives, like enantiopure tartaric acid (TA) (Fig. 10e).87,88 The chirality transferred from a small molecular chiral dopant to non-chiral polymer phase-domains leads to the hierarchical self-assembly in the composite system.89–91 Therefore, helical nanostructures can be observed in the LCBC doped with L-TA or D-TA (Fig. 10f). It is worth noting that the induced aggregation chirality in the mesogenic segments was not determined by the handedness of the dopants, which is the reason why the result was the same whether the dopant was L-TA or D-TA. The HB introduced by TA enhanced the interactions between the two blocks of the LCBC,92,93 providing an opportunity for the emergence of aggregation chirality in the continuous phase and the formation of helical nanostructures in the film.
Furthermore, the manipulation of aggregation chirality to achieve the photocontrol of MPS helical nanostructures was successfully realized. Upon UV irradiation, photoisomerization and phase transition occurred simultaneously, and the in-plane orientation of chiral nanostructures in the film became out-of-plane correspondingly (Fig. 10g).41,82 Then, after thermal annealing for a long time (1200 min), the aggregation chirality reappeared (Fig. 10g), showing a reversible photocontrol process. This tunable hierarchical self-assembly offers a facile method to functionalize chiral materials with controllable properties and opens a door for countless applications in chiral recognition, enantiomer separation, enantioselective permeation, and chiral sensory systems for bio- and nanotechnology.87
Fig. 11 (a) Schematic illustration of the formation of hierarchical stripes via FESA. (b) Optical microscopic photograph of the hierarchical stripes produced by FESA. (c) Secondary stripes generated by moving the lower substrate at an appropriate speed continuously. (d) Two-dimensional (2D) map describing how the concentration of the solution and the moving speed of the lower substrate influence the formation of secondary stripes. If the parameters are in the shadow area, regular secondary stripes will exist. Reproduced from ref. 42; copyright 2018, American Chemical Society. |
Fig. 12 (a) POM images of the gratings in response to heating. (b) POM images of the gratings in response to UV irradiation. (c) POM images of the gratings in response to Ag+ ions. Reproduced from ref. 52; copyright 2019, American Chemical Society. (d) Schematic illustration of the procedures to fabricate micro-patterns. Reproduced from ref. 43; copyright 2020, Wiley-VCH. |
Another method to fabricate gratings and other micro-patterns is combining athermal nanoimprint lithography (AT-NIL) with photo-patterning.43 First, one THF solution of the azopolymer (PM6AZC4, half-life of the cis isomer: 14.6 h, Fig. 4a) was spin-coated on the poly(ethylene terephthalate) (PET) substrate and global UV illumination was provided (Fig. 12d). Then, a pre-designed poly(dimethyl siloxane) (PDMS) mold was placed on the film with an external mechanical stress and cis-rich PM6AZC4 would flow into the microarray of the mold. Subsequently, exposure to green light to cause cis–trans back-isomerization could achieve solidification of the azopolymer, and the first iteration result was obtained after removal of the mold. Furthermore, multiple selective photoisomerization in local areas was feasible by using a photomask, since the solid-to-liquid transition of PM6AZC4 was completely reversible. As shown in Fig. 12d, three letters of “P”, “K” and “U” were successfully imprinted on the flexible PET substrate.
Recently, microstructures fabricated by using the mass transport method have become popular, especially Marangoni flow.102–106 Marangoni flow is a kind of interfacial agitation driven by local variations of interfacial tension,107,108 which can be used in the photoresponsive AZ-containing system. Our group has developed a two-step method to fabricate microstructures on the film surface of PM6AZC4 (half-life: 14.6h, Fig. 4a): selective photoisomerization using a photomask and then immersion in a solvent (Fig. 13a).109 After UV-patterning the azopolymer film, the periodic distributions of trans and cis isomers were acquired. Since the surface energy of the trans-azopolymer and cis-azopolymer alternately distributed in the film was different, mass transport occurred when the pre-patterned film was immersed in a solvent such as ethanol (Fig. 13a). It is notable that the flow direction of the azopolymer in the solvent is opposite to the traditional Marangoni flow of the polymer itself,102,109 indicating that the interaction between the solvent and the film surface with wettability gradient exists, allowing the solvent to drag the underlying polymer to transport, and then surface morphing is formed (Fig. 13a). Essentially, this flow from the flowing fluid (cis-rich PM6AZC4) to the glassy plastic (trans-rich PM6AZC4) is the capillary flow induced by the flow of the solvent on the film surface with wettability gradients.110 Therefore, combining this unique phenomenon with the traditional Marangoni flow, a steerable mass transport direction was successfully realized.110 To obtain well-controlled bidirectional mass transport, one commercial small-molecule nematic LC, 4-cyano-4′-pentylbiphenyl (5CB), was introduced into the azopolymer as a functional additive to build a host–guest system (half-life: 7.8 h).110 Upon optimizing the host–guest ratio (the doping amount of 5CB) and the width of the photoisomerized areas, the polymer flow in both directions was obtained simultaneously (Fig. 13b, the middle scheme). As shown in Fig. 13b, when the width of the photoisomerized area was 5 μm, polymer flow occurred from the cis-rich region to the trans-rich region, while the direction was opposite if the width reached or exceeded 20 μm.
Fig. 13 (a) Schematic illustration of the two-step method. The first step is UV-patterning, and the second step is immersion in a solvent. Reproduced from ref. 109; copyright 2023, American Chemical Society. (b) Schematic illustration of the variation in the mass transport direction of the host–guest system as the width of the photoisomerized area increases. Reproduced from ref. 110; copyright 2024, Cell Press. (c) Schematic illustration of the dynamic process upon heating at 100 °C. (d) Photographs of the variation in structural color during the whole process. The film was spin-coated on the silicon wafer with a size of 1 cm × 1 cm. Reproduced from ref. 111; copyright 2024, Wiley-VCH. |
Furthermore, the microstructures fabricated using the host–guest system (half-life: 7.8 h) at room temperature were responsive to thermal treatment. It is well-known that cis-AZ groups will undergo cis–trans back-isomerization upon heating and the recovered trans-AZ moieties may self-organize into the mesogenic phase.111,112 Therefore, surface morphing has been conveniently manipulated by just heating the film with periodic microstructures, exhibiting a vivid structural color (Fig. 13c and d).111 When heating the host–guest film at 100 °C, cis–trans back-isomerization occurred first, leading to the first disappearance of the structural color (1st DA) and then mesogenic assembly of the recovered AZ groups occurred due to the inherent properties at the LC phase. Since there was a difference in the time required for accomplishing the assembly between recovered AZ moieties and original trans-AZ groups, the surface-energy gradient could be reproduced and Marangoni flow would occur, resulting in the reappearance of structural color (RA). Finally, the assembly of the AZ moieties in all regions was completed, so the structural color disappeared again (2nd DA).
Fig. 14 (a) Schematic illustration of different kinds of photoinduced bending that occur in the CLCP system. Reproduced from ref. 119; copyright 2017, American Chemical Society. (b) Photographs of the photoinduced bending of the LCP-Kapton bilayer composite system and the schematic illustration of its mechanism. Reproduced from ref. 45; copyright 2019, The Royal Society of Chemistry. (c) Schematic diagram of the photoinduced helices of the photo-actuators. (d) Photographs of the photo-actuators mimicking the predation of pythons. Reproduced from ref. 80; Copyright 2018, The Royal Society of Chemistry. |
Furthermore, if the photo-actuator was obtained by cutting from the AZ derivative/LDPE bilayer film (Fig. 7b) and there is an angle between its long axis (L) and rubbing-caused microgroove direction (M), helically twisted motions would occur (Fig. 14c and d).80 In addition, the size of the actuator and the light intensity could influence the photomechanical performance. As shown in Fig. 14c, there is a positive connection between the deformation amplitude of the actuator and the light intensity. When the amplitudes of these photoinduced helices were large enough, it could grasp objects, just like the predation of pythons. Specifically, objects with irregular shapes and different sizes such as oblate metal plates or slender wood sticks can be captured using this photo-actuator (Fig. 14d). The metal plate or wood stick was released upon removal of UV light due to the reversible deformation behaviours. Moreover, the actuator could enwind around the slender rod helically and the winding tightness could be manipulated by tuning the light intensity. This biomimetic actuator paves the way for applications in miniaturized robotics.
Fig. 15 (a) Chemical structure of the random copolymer. (b) Schematic illustration of the chaotic self-oscillation when exposed to UV light. (c) Schematic illustration of the self-oscillation of the bilayer film under continuous UV illumination. Reproduced from ref. 129; copyright 2021, American Chemical Society. (d) Chemical structure of the random copolymer and a schematic illustration of the light-fueled autonomous self-oscillation. Reproduced from ref. 130; copyright 2021, The Royal Society of Chemistry.(e) Chemical structures of the cross-linker RM82, LC monomer RM23, and photothermal agent GO. (f) Schematic diagram of the deformation mechanism of the film cut along or perpendicular to the rubbing direction, respectively. (g) Schematic illustration of the deformation process under NIR light irradiation. Reproduced from ref. 131; copyright 2022, American Chemical Society. |
Another system with physical crosslinking sites has been designed, which is responsive to UV illumination and visible-light irradiation (Fig. 15d).130 The maximum deflection angle became smaller as the wavelength of the light increased from 365 nm to 460 nm and 530 nm,130 which is due to the combined influence of the cis-AZ content and the trans–cis dynamic process. Based on these studies, light-powered self-oscillators have been fabricated. When the actuator bent across the equilibrium position (state B in Fig. 15d), the self-shadowing effect dominated and it would recover back to receive light energy again. This repeated behaviour could occur spontaneously under consistent light irradiation and it can be manipulated by tuning the size of the oscillator, the light intensity/wavelength, the light-irradiated position and the loaded mass on the bilayer film.130
Furthermore, GO/liquid-crystalline network (LCN) composite films have been used to fabricate light-activated self-oscillators (Fig. 15e).131 Due to the mismatch of the coefficient of thermal expansion (CTE) between GO and the LCN layer and asymmetric contraction/expansion in the LCN layer, the bending direction and the deflection angle were different when changing the cutting direction upon NIR light irradiation (Fig. 15f). Moreover, an unconventional hybrid oscillation mode consisting of bending and twisting occurred during the self-oscillation process upon exposure to NIR light (Fig. 15g). These results offer the possibility to design a light-powered actuator with various oscillation modes.
Fig. 16 (a) Chemical structures of the materials. (b) Schematic illustration of the photo-controlled motions, which is analogous to a dolphin kick. (c) Photographs of the transportation process of a well-designed device. Reproduced from ref. 44; copyright 2019, Wiley-VCH. (d) Chemical structures of the composite system. (e) Photographs of the composite films exhibiting their flapping properties under different conditions. (f) Digital photographs, trajectory tracking curves, and schematic illustration of the light-driven flight of the artificial dragonfly device. Reproduced from ref. 138; copyright 2021, Elsevier. |
Furthermore, photo-actuated flight has become popular in recent years.139–141 As shown in Fig. 16d, a light-powered soft actuator was prepared based on the composite system consisting of AZ-containing LCPs and Kapton nanofibers.138 The mechanical properties were reinforced via the supramolecular HB; therefore, the oscillation induced by photoisomerization was capable of lifting a load by 40 times the weight of the film itself.138 Then, the relationship between the bending angle, vibration frequency and light intensity was explored. As shown in Fig. 16e, (i) is the original composite film without UV illumination; (ii) and (v) are in the gliding region with a low flapping frequency and a large bending angle; and (iii) and (iv) are in the flapping region with a high flapping frequency and a small bending angle. Then, the composite films were assembled into an artificial dragonfly device to demonstrate the realization of light-driven flight (Fig. 16f). The forewings and hindwings were designed to bend upwards and downwards, respectively, simulating the phase difference during the flight of natural dragonfly.138 Upon blue light (460 nm) irradiation, the artificial dragonfly flew away from the light source and five dives could be observed over 30 s (Fig. 16f). This is almost an early demonstration of a light-driven flying device.
Fig. 17 (a) Schematic illustration of the fabrication, charging and discharging processes of the STF device. (b) Mechanism of energy storage in the STF device. Reproduced from ref. 149; copyright 2019, Wiley-VCH. (c) Schematic illustration of the cation–π interaction enhanced STF at the molecular scale. (d) Schematic illustration of the cation–π interaction enhanced STF at the aggregation scale. Reproduced from ref. 60; copyright 2022, American Chemical Society. |
Furthermore, a supramolecular system with a cation–π interaction was designed by introducing decanoquaternary amine bromide (DMBI) into the photo-liquefiable MO-Azo, as shown in Fig. 3c.60 Improvement of the STF energy density has been proved in two aspects: the molecular scale and the aggregation scale (Fig. 17c and d). At the molecular scale, there is a competition between cation–π interaction and π–π stacking during trans–cis photoisomerization and photo-caused recovery, whether it is in the solution or just the liquid state (cis-rich state). Therefore, more MO-Azo molecules will undergo trans–cis isomerization under UV illumination even though the molar extinction coefficient of MO-Azo is decreased and the quantum efficiency of photoisomerization varies slightly (Fig. 17c).60 As for the aggregation scale, the cation–π interaction has a great impact on the crystalline structure. It is well-known that photoisomerization occurs much more easily in liquid than in a solid.60 For the pristine MO-Azo, there is a mismatch between trans–cis photoisomerization and crystal structure evolution, hindering the further photoisomerization (Fig. 17d, left). The introduction of the cation–π interaction hinders the π–π stacking of MO-Azo molecules and reduces the isomerization rate, enabling the evolution of the crystal structure to keep pace with the photoisomerization.60 As a result, more MO-Azo molecules can undergo the photoisomerization process efficiently (Fig. 17d, right). In a word, the construction of this supramolecular system opens a door for increasing the energy density of STF and achieving the balance between the molecular design and aggregation state.
Phase-change materials (PCMs) are important for energy storage due to the increase of the energy density resulting from the simultaneous absorption of ambient heat and light energy.152–156 Therefore, we proposed a method to combine one light-inactive PCM with an AZ-containing LCBC to improve the energy storage efficiently.112 First, the LCBC shown in Fig. 5a was used, where the PEO (a repeated unit of 114) used as the separated phase is a kind of PCM and the continuous phase is the AZ-containing LCP where two kinds of energies can be stored: one is arising from photoisomerization of AZ groups and the other is the latent heat of phase transition from the LC to the isotropic phase (Fig. 18a). Then, one small-molecule PEO (sPEO) was introduced into the LCBC system as the PCM, so the energy can be stored in the AZ-containing LCP block, the PEO block and the additional sPEO (Fig. 18a). The size and periodicity of MPS nanostructures would change with different addition ratios of sPEO (Fig. 18b). As the doping ratio of sPEO increased, the size of PEO nanocylinders became larger and then irregular until non-uniform structures at the macroscale appeared. Correspondingly, the crystallization point (Tc) of the composites was completely different when the doping amount of sPEO varied, as shown in Fig. 18c. A significant supercooling was observed since the Tc of the sPEO was 24 °C but the Tc of the PEO block in the cis-rich LCBC was −35 °C.112 Also, the Tc remains almost unchanged when sPEO is at a low doping amount. In this case, the nanoconfinement effect of MPS in the LCBC and the steric hindrance of cis-AZ would limit the crystallization of sPEO, resulting in a decreased Tc of sPEO even at −38 °C (Fig. 18c). Therefore, this composite can store the energy at a suitable temperature, and release at higher and lower temperatures, respectively. In addition, STF devices fabricated using this composite can be charged upon UV illumination and discharged using 460 nm blue light.157 As shown in Fig. 18d, pure cloth without this composite (top) and a charged wearable device (bottom) were wrapped around the wrist for comparison, respectively. There was almost no temperature change in the pure cloth, while for the charged device, the stored energy could be released under blue light irradiation, allowing the temperature to increase from 32.2 °C to 43.6 °C as the irradiation time increased. These results strongly demonstrate that this STF device can be used to keep warm in winter and facilitated applications in the field of wearable smart materials.112
Fig. 18 (a) Schematic illustration of the energy storage in the composite system composed of the LCBC and sPEO. (b) Schematic illustration of the composite films with different addition ratios of sPEO. (c) DSC curves of the charged composites with different doping amounts of sPEO. (d) IR thermography images of the pure cloth (top) and charged wearable device (bottom) wrapped around the wrist upon 460 nm blue light irradiation for different times. Reproduced from ref. 112; Copyright 2021, American Chemical Society. |
Fig. 19 (a) Photographs of clover patterns with an angle-dependent structural color. Reproduced from ref. 43; copyright 2020, Wiley-VCH. (b) Schematic illustration, photographs, and AFM images of the microstructures on the film surface, which can serve as anticounterfeiting labels. Reproduced from ref. 109; copyright 2023, American Chemical Society. |
Moreover, combining the two-step method in Fig. 13a with the half-life of the cis-azopolymer, anticounterfeiting labels were prepared.109 It is obvious that the stored information is unable to be read without immersion in a solvent. Therefore, there is a maximum time interval between photo-patterning and immersion in a solvent since the cis-isomer will thermally recover to its trans state if the time interval is long enough, resulting in a little surface-energy gradient and non-occurrence of mass transport. As shown in Fig. 19b, the maximum time interval was about 8 h. If it is more than 8 h, surface morphing will not be generated, let alone the structural color, so this time interval can be called the expiration time. By designing the molecular structure of the azopolymer, the half-life can be modulated in a controlled manner, then anticounterfeiting labels with different expiration times on-demand can be fabricated.
Moreover, a multi-mode anticounterfeiting platform was designed by tailoring the bidirectional flow in the host–guest system.110 Specifically, the first mode is to determine the authenticity of the information by using two photomasks with inversed patterns, where one has alternating 5 μm transparent width and 20 μm opaque width, and the other is just the opposite. If the information is true, the bidirectional polymer flow occurs upon exposure to ethanol vapor, leading to a similar surface topography in both cases (Fig. 20a and b). However, if there is only unidirectional mass transport, the resulting two surface topographies should be reversed, suggesting that the information is false. When there is only one photomask consisting of a three-letter pattern, another anticounterfeiting mode can be applied to distinguish between two patterns that look similar under the observation of an optical microscope (Fig. 20c and d). When the unidirectional flow occurs, the obtained pattern is false information (Fig. 20c). If the host–guest ratio is suitable, bidirectional flow occurs and all the flowing mass moves to the boundary, then the height difference is only reflected in the one-dimensional (1D) boundary, not a 2D area (Fig. 20d), which is different from the traditional patterns, demonstrating the true information. The third mode is that the authenticity of the information can be identified by laser scanning confocal microscopy (LSCM) measurements (Fig. 20e). A doped red fluorescent dye could be considered as a visualization of the polymer flow in fluorescent images and readout signal intensity mapping images. If the information is true, there is little difference in fluorescence intensity between the trans-rich and cis-rich regions due to the bidirectional mass transport (Fig. 20e). Additionally, there is a sharp decrease in red fluorescence intensity at the boundary in the original film plane, since the fluorescent molecules have been delivered to the boundary along with the polymer flow (away from the original film plane). Therefore, true information is allowed to be identified using LSCM, providing opportunities for the design of numerous anticounterfeiting platforms.
Fig. 20 (a) Information decryption when using a photomask with a 5 μm transparent width and a 20 μm opaque width in the UV-patterning process. (b) Information decryption when using a photomask with a 5 μm opaque width and a 20 μm transparent width in the UV-patterning process. (c) False information obtained by using the photomask with a three-letter pattern. (d) True information obtained by using the photomask with a three-letter pattern. (e) Laser scanning confocal microscopy (LSCM) images and readout signal intensity mapping images of the identification process of the true information. Scale bars are all 20 μm. Reproduced from ref. 110; copyright 2024, Cell Press. |
Besides multi-mode static anticounterfeiting, multi-level dynamic anticounterfeiting has become popular recently.164 Our group has proposed a facile strategy to realize time-dependent anticounterfeiting and double-lock information encryption.111 Based on the dynamic process upon heating the host–guest film with periodic microstructures at 100 °C, anticounterfeiting labels with a tunable structural color were fabricated. Two pieces of information that look identical could be distinguished by observing the heating process: if the “Love” pattern disappeared and emerged again, it suggests that the information was correct (Fig. 21a), while if vanished gradually and no longer appeared, it indicates that it was false information (Fig. 21b). Also, the time-dependent multi-information display can be achieved using three clover patterns with different host–guest ratios and the dynamic processes of different three-clover-pattern combinations are distinct.111 Taking advantage of this unique feature, information at each time period can be encoded, where the displayed state is 1 and the erased state is 0. As a result, passwords can be encrypted and stored as binary numbers in this dynamic process. To decrypt the password, the whole process of the variation in three-clover-pattern combination and the decoding method should be acquired simultaneously. If different decoding methods are used, different passwords would be obtained even if the dynamic process of the three-clover-pattern combination is the same (Fig. 21c). Similarly, passwords are distinct when the dynamic processes are different but the decoding method is the same (Fig. 21d). Therefore, this host–guest system with time-dependent features can be regarded as a material with a double-lock,111 and information could only be decrypted with the correct dynamic process and correct decoding method, efficiently improving the capability of information encryption with a higher level of security.
Fig. 21 (a) Photographs of the identification process of the correct “Love” pattern in the film. Scale bars are all 1 cm. (b) Photographs of the identification process of the false “Love” pattern in the film. Scale bars are all 5 mm. (c) Decryption of two different passwords using one dynamic process and different decoding methods. Scale bars are all 2 mm. (d) Decryption of two different passwords using different dynamic processes and the same decoding method. Scale bars are all 2 mm. Reproduced from ref. 111; copyright 2024, Wiley-VCH. |
Fig. 22 (a) Chemical structures of the siloxane-based materials. (b) Photographs exhibiting photoinduced reversible opening and closing of a ring. Reproduced from ref. 165; copyright 2021, American Chemical Society. (c) Photographs of the TBC film in trans and cis states. (d) Photographs of the naked device immersed in water for different times. (e) Photographs of the packaged device immersed in water for different times. Reproduced from ref. 76; copyright 2022, American Association for the Advancement of Science. |
Furthermore, the AZ-containing TBC in Fig. 6a can also be used for photo-switchable adhesion since it has two reversible states with different mechanical properties: stiffness and elasticity (Fig. 22c).76 Due to its stronger capability to achieve the adhesion of two objects through elastic deformation after UV irradiation, the cis-rich TBC film can be used for packaging electronic devices. Compared with other traditional encapsulating materials, this TBC has three advantages: first, the photoinduced transition from stiff to elastic occurs at room temperature; second, this free-standing elastomer can be applied in more situations, whether hard or soft substrates; last but not least, it can be easily removed by using ethanol. As shown in Fig. 22d, the naked device began to decompose when immersed in water for 10 s and completely decomposed at 180 s.76 In contrast, no significant discoloration was observed in the device packaged with the TBC film after immersion in water for 3600 s (Fig. 22e). These results strongly demonstrate that the photo-switchable TBC is an excellent candidate for isolating the device from water efficiently, which is suitable for the fabrication of various devices that need to work underwater.
Although significant processes in this field have been made, challenges still exist and further studies are required. The current research studies on AZ-containing LCPs are limited in scalability and most of the fabricating techniques are still in the laboratory stage. In addition, the preparation of sub-10 nm nanostructures is urgently needed to be well explored, whether from molecular design or external manipulation. Moreover, taking advantage of photo-controlled mass transport directly to fabricate dynamic microstructures at room temperature is expected to be achieved. Furthermore, the stability of the cis isomer should be improved, if it can exist for a very long time, many more situations will be applicable. More importantly, the mechanism of photomechanical deformation should be investigated in depth, then actuators with multiple sophisticated motions can be designed on-demand. Expanding the range of photoinduced changes of mechanical properties is also a key point. In a word, it is imperative for researchers to focus on these issues and contribute to the development of AZ-containing LCPs by improving their performance in industrial applications.
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