Optically switchable bistable guest–host displays in chiral-azobenzene- and dichroic-dye-doped cholesteric liquid crystals

“…This type of texture is also found in the cuticle of Plusiotis gloriosa in nature 23 and CLC films upon electric field application 24,25 and also upon photoisomerization of a doped azobenzene derivative. 26,27 Continuous visible light irradiation or thermal back process resulted in merging of scattered small-domain boundaries, leading to the formation of large domains. Simultaneously, the fingerprint texture emerged in several domains (Figure 2e) and finally merged recovering the initial polygonal fingerprint texture (Figure 2f) and HTP of motor 1 recovered to −33 μm −1 at PSS 436nm .…”

“…In case of CLC films, the absorbance of the azobenzene derivatives is depending on not only the isomer ratio but also the orientation of molecules. 27 Basically, when the directions of π−π* transition moment of azobenzene and the electric field of the incident light are parallel to each other, molecules show the maximum absorbance. If molecules become tilted from their parallel position, they cannot effectively absorb the light resulting in decrease of the absorption.…”

Molecular Crankshaft Effect Converting Piston-like Molecular Motion to Continuous Rotation of Macro Objects

“…This type of texture is also found in the cuticle of Plusiotis gloriosa in nature 23 and CLC films upon electric field application 24,25 and also upon photoisomerization of a doped azobenzene derivative. 26,27 Continuous visible light irradiation or thermal back process resulted in merging of scattered small-domain boundaries, leading to the formation of large domains. Simultaneously, the fingerprint texture emerged in several domains (Figure 2e) and finally merged recovering the initial polygonal fingerprint texture (Figure 2f) and HTP of motor 1 recovered to −33 μm −1 at PSS 436nm .…”

“…In case of CLC films, the absorbance of the azobenzene derivatives is depending on not only the isomer ratio but also the orientation of molecules. 27 Basically, when the directions of π−π* transition moment of azobenzene and the electric field of the incident light are parallel to each other, molecules show the maximum absorbance. If molecules become tilted from their parallel position, they cannot effectively absorb the light resulting in decrease of the absorption.…”

Molecular Crankshaft Effect Converting Piston-like Molecular Motion to Continuous Rotation of Macro Objects

“…Nematic liquid crystals memorizing the alignment were implemented by incorporating self-assembled hydrogen-bonded fibers into liquid crystals . Cholesteric liquid crystals are also used in memory display devices because of their homeotropic orientation, and these structures remain stable in the zero-field state. , …”

“…23 Cholesteric liquid crystals are also used in memory display devices because of their homeotropic orientation, and these structures remain stable in the zero-field state. 24,25 In addition, fluoran dyes, widespread chromogenic substances, are applied to color-memory materials due to the abundant color options, good responses, and reversibility. The chromogenic behavior of fluoran dyes arises from redox reaction-linked electron transfer.…”

Multicolor and Multistage Response Electrochromic Color-Memory Wearable Smart Textile and Flexible Display

“…A reversible modulation of such properties can be achieved by irradiating the device with photons of energy sufficient to trigger the reversible dopant photo isomerization process. The most prominent classes of photochromic compounds which have been used successfully in photo-switchable technologies are azobenzenes [18][19][20][21][22] and diarylethenes (DAEs). [20,21] In particular, DAEs show a number of properties which are highly desirable for the design and fabrication of a variety of responsive systems: i) vastly different optical, electrical, and energetic properties between the two, thermally stable, isomers; ii) highly reversible and fatigue…”

Diarylethenes in Optically Switchable Organic Light‐Emitting Diodes: Direct Investigation of the Reversible Charge Carrier Trapping Process