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target="_blank" rel="nofollow" href="#ulink_cccaa30c-fb2c-5bc0-9498-ff0bf4a38e0a">Figure 2.8 (a) General synthetic routes for P(NIPAM‐fv [DAV]) IL gels and P(...Figure 2.9 The evolutions of morphology of ceramic filler in SCEs.Figure 2.10 A switchable single‐molecule electrochromic device derived from ...Figure 2.11 Schematic representation of the synthesis of PIL‐b‐CD and PIL‐Fc...Figure 2.12 An ECD structure containing a gel electrolyte composition combin...Figure 2.13 An electrochromic device containing DNA‐based electrolyte.

      3 Chapter 3Figure 3.1 Commonly utilized device structure for small molecule electrochro...Figure 3.2 Technology development of small molecule electrochromic materials...Figure 3.3 General structure for violene‐type electrochromics.Figure 3.4 Electrochromic mechanism of violene–cyanine hybrid material.Figure 3.5 Structure of cyanine–cyanine hybrid materials.Figure 3.6 Structure of cyanine–cyanine hybrid materials.Figure 3.7 Structure of the cyanine–cyanine hybrid with a cyanine unit at on...Figure 3.8 Mechanism of violene–cyanine hybrids.Figure 3.9 Structure, absorption spectra, and images of colored cells.Figure 3.10 Structure of the TP film.Figure 3.11 Structure of biphenyl ester compounds with larger conjugated sys...Figure 3.12 Structures of oligothiophene derivatives, 5,5″‐dicyano‐2,2′: 5′,...Figure 3.13 (a) Molecular structures of OHC‐3T‐CHO and X‐T. (b–d) Schematic ...Figure 3.14 Mechanism of oligothiophene derivatives.Figure 3.15 (a) Molecular structures of 3TB, 3EB, 3ETB, and 3TB‐4EDOT. (b) P...Figure 3.16 (a) Molecular structures of 1EDOT‐2B‐COOCH3, 2EDOT‐2B‐COOCH3, ED...Figure 3.17 Structure of common isophthalate derivatives.Figure 3.18 (a) Electrochromism of 5‐substituted isophthalate derivatives an...Figure 3.19 Calculated HOMO, LUMO, and LUMO + 10 of the reduced species of M...Figure 3.20 Known reduction process of nitrobenzene.Figure 3.21 (A) Electrochromism of 5‐substituted isophthalate derivatives (w...Figure 3.22 Structures of Bis‐isophthalate derivative IS1‐6.Figure 3.23 UV–visible spectra and photos of displayed colors before and aft...Figure 3.24 Structure of the TP film.Figure 3.25 Optical (at 530 nm) (top) and electrical current (bottom) respon...Figure 3.26 (a) Structure of eleven esters synthesized and (b) photographs o...Figure 3.27 (a) Cyclic voltammograms of diesters and (b) in situ electrochem...Figure 3.28 Structure, synthesis, and properties of EC materials based on ph...Figure 3.29 Structure and UV spectra of conjugated anodically coloring elect...Figure 3.30 Synthesis and structures of azobenzene‐4,4′‐dicarboxylic acid di...Figure 3.31 Electrochromic mechanism of ADDEDs.Figure 3.32 Structure of pyridinium electrochromic materials.Figure 3.33 Molecular structures of electrochromic 2,4,6‐triphenyl‐1,3,5‐tri...Figure 3.34 Synthetic scheme for methyl ketone and (A) absorption spectra of...Figure 3.35 The structures of seven methyl ketone molecules and the colors o...Figure 3.36 (a) The synthetic route of M5; (b) The HOMO (bottom) and LUMO or...Figure 3.37 The electrochromic mechanism of M5 with a one‐electron reduction...Figure 3.38 The structure, electrochromic mechanism, and photographs of the ...Figure 3.39 (a) Lactone ring‐opening–closing reaction of fluoran dye. (b) Th...Figure 3.40 Mechanism of the reaction.Figure 3.41 Mechanism of imaging using a leuco dye on a mesoporous TiO2 elec...Figure 3.42 (A) The switch mechanism of fluorescein with electro‐reduced p‐b...Figure 3.43 (a) The fluorescence switching mechanism induced by p‐BQ as an e...Figure 3.44 Bonding alteration process of Rh–N via bond‐coupled electron tra...Figure 3.45 (a) Bonding alteration process of Rh–N via bond‐coupled electron...Figure 3.46 (a) Molecular structures of RHMA‐M1–RHMA‐M6 (the colored shading...Figure 3.47 The switch mechanism of fluorescein with electro‐reduced p‐benzo...Figure 3.48 (a) Structure of DMCS‐TPA and BMBCP and (b) photographs of DMCS‐...Figure 3.49 (a) Chemical structures of ambipolar EC materials BDP1–BDP6, (b)...Figure 3.50 (a) Schematic diagram of color change for ambipolar materials, (...Figure 3.51 (a) Structures of Thiele's hydrocarbon and bridged tetra‐aryl‐p‐...

      4 Chapter 4Scheme 4.1 Development routes of viologen.Figure 4.1 Viologens in three forms: R1 and R2 refer to the substituent at n...Figure 4.2 Adsorption of viologen on the surface of nanocrystalline electrod...Figure 4.3 Structure of ester viologen.Figure 4.4 Color coordinates of asymmetric viologens device. a Transmittance ...Figure 4.5 Different devices and color coordinates.Figure 4.6 Normalized absorption and emission spectra of H2TTz2+, Me2TTzFigure 4.7 Fluorescence quenching.Figure 4.8 Multilayer PDI‐MV device.Figure 4.9 Cyclic voltammograms of a 10 bilayer film at various scan rates a...Figure 4.10 The structure of photographs device.Scheme 4.2 The synthesis route of phosphoryl‐bridged pyridiniums.Figure 4.11 (a) Three‐electrode liquid crystalline cell. (b) Optical absorpt...Figure 4.12 (a) Fluorescence spectra of the applied voltage of the gel of 10...Figure 4.13 Side‐chain viologen‐based polymers.Figure 4.14 Spectral absorption of the device.Figure 4.15 Reversible photochromism spectrum.Figure 4.16 Synthesis of polyviologens via Menshutkin reaction.Figure 4.17 Synthesis of P(NIPAM‐DAV) IL gels and P(NIPAM‐BVIm‐DAV) gels....Figure 4.18 Thermochromic and electrochromic effect.Figure 4.19 Illustration of five‐layer classic structure.Figure 4.20 Illustration of simple sandwich structure.Figure 4.21 Illustration of cathode–anode separation structure.Figure 4.22 Illustration of reflective device structure.Figure 4.23 The structureof common redox mediators.Figure 4.24 Combination of GQDs anion and viologen.Figure 4.25 Photograph of RGO film in ethyl viologen device.Figure 4.26 (a) Formation of gel electrolytes based on MOP chemistry and (b)...Figure 4.27 Self‐healing electrolyte gel.Figure 4.28 (A) Dimerization behavior of radical cation. (B) Absorbance spec...Figure 4.29 The representative structure and components of ECD.

      5 Chapter 5Figure 5.1

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