Photochromic Diarylethenes Designed for Surface Deposition: From Self‐Assembled Monolayers to Single Molecules

Calupitan, Jan Patrick; Galangau, Olivier; Nakashima, Torahiko; Kawai, Tsuyoshi; Rapenne, Gwénaël

doi:10.1002/cplu.201800640

Cited by 7 publications

(3 citation statements)

References 116 publications

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“…Photochromic molecules have also been applied as a "switch" for property modulation of self-assembled monolayers (SAMs). [98][99][100][101][102][103] The SAMs were formed on Au-stripped substrates using a spiropyran derivative, H 2 SPDT (H 2 SPDT = 2-(3′,3′-dimethyl-6-nitrospiro[chromene-2,2′-indolin]-1′-yl)ethyl 6,8-dimercaptooctanoate; c = 1; Figure 11), through immersing the Au surface in an ethanol solution of H 2 SPDT. [96] The thickness of the resulting photochromic SAM was estimated to be 15.4 ± 2 Å, and quantitative analysis using XPS suggested that 38% of the spiropyran molecules undergo photoisomerization to merocyanine.…”

Section: D Materials (D = 2) With Covalently Integrated Photochromic ...mentioning

confidence: 99%

Dynamically Controlled Electronic Behavior of Stimuli‐Responsive Materials: Exploring Dimensionality and Connectivity

Leith

Martin

Mathur

et al. 2021

Advanced Energy Materials

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Materials with dynamically controlled electronic structures (i.e., upon external stimuli) are at the forefront of the renewable energy sector with applications as memory devices, smart supercapacitors, programmable solar cells, and field‐effect transistors. Moreover, their continued development as device components is critical for the field of optoelectronics since their performance is comparable, or could even surpass, the current benchmarks. Adaptive electronic properties are the main focus of this review that discusses recent developments in the modulation of electronic behavior that can be tuned using external stimuli in metal–organic frameworks (MOFs), covalent–organic frameworks (COFs), primarily inorganic hybrids, polymers, and graphitic‐type materials. Triggers to achieve “dynamic” behavior discussed within this manuscript are primarily light‐based switches that include different classes of photochromic molecules such as naphthalene diimide, viologen, diarylethene, azobenzene, and spiropyran. The effect of material dimensionality and photoswitch connectivity achieved through integration of photochromic moieties inside 0D, 1D, 2D, and 3D hybrid matrices is discussed. This review showcases the prospects of advancing the material and energy landscapes through employment of structural motifs with adaptive electronic structures occurring as a function of their dimensionality and connectivity.

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Section: D Materials (D = 2) With Covalently Integrated Photochromic ...mentioning

confidence: 99%

Dynamically Controlled Electronic Behavior of Stimuli‐Responsive Materials: Exploring Dimensionality and Connectivity

Leith

Martin

Mathur

et al. 2021

Advanced Energy Materials

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“…A photochromic molecule adsorbs light at specific wavelengths and thus appears with convertible colors [2,5]. Concomitant with color changes, their physical and chemical properties, such as molecular geometry, dipole moment and electronic structure, alter with isomerization and show switchable on and off states [5][6][7]. The interest in photoswitchable molecules is large and covers diverse research fields ranging from nanomachines (rotaxane-based molecular machines [8][9][10], light-driven rotary molecular motors [11,12]), photoactive nanoparticles (noble metal Nps [13][14][15], fluorescent Nps [16,17]), nanoelectronics [7] (photoactive molecular junctions [18][19][20][21][22], rectifiers [23], memories [24,25] or organic field effect transistors [25,26]), metal organic nanoassemblies (photoswitchable metal-organic molecular cage [27] or metal-organic frameworks [28,29]), supramolecular self-assembled systems (light-driven supramolecular amphiphiles [30], supramolecular polymers [31,32]), biological nanosystems [5,33] and pharmacology [34].…”

Section: Introductionmentioning

confidence: 99%

Visualization and Comprehension of Electronic and Topographic Contrasts on Cooperatively Switched Diarylethene-Bridged Ditopic Ligand

et al. 2022

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Diarylethene is a prototypical molecular switch that can be reversibly photoisomerized between its open and closed forms. Ligands bpy-DAE-bpy, consisting of a phenyl-diarylethene-phenyl (DAE) central core and bipyridine (bpy) terminal substituents, are able to self-organize. They are investigated by scanning tunneling microscopy at the solid–liquid interface. Upon light irradiation, cooperative photochromic switching of the ligands is recognized down to the submolecular level. The closed isomers show different electron density of states (DOS) contrasts, attributed to the HOMO or LUMO molecular orbitals observed. More importantly, the LUMO images show remarkable differences between the open and closed isomers, attributed to combined topographic and electronic contrasts mainly on the DAE moieties. The electronic contrasts from multiple HOMO or LUMO distributions, combined with topographic distortion of the open or closed DAE, are interpreted by density functional theory (DFT) calculations.

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“…A photochromic molecule adsorbs light at specific wave-lengths and thus appears with convertible colors [2,5]. Concomitant with color changes, their physical and chemical properties, such as molecular geometry, dipole moment and electronic structure, alter with isomerization and show switchable on and off states [5][6][7]. The interest in photo-switchable molecules is large and covers diverse research fields ranging from nanomachines (rotaxane-based molecular machines [8][9][10], light-driven rotary molecular motors [11,12]), photoactive nanoparticles (noble metal Nps [13][14][15], fluorescent Nps [16,17]), nanoelectronics [7] (photoactive molecular junctions [18][19][20][21][22], rectifiers [23], memories [24,25] or organic field effect transistors [25,26]), metal organic nanoassemblies (photoswitchable metal-organic molecular cage [27] or metal-organic frameworks [28,29]) supramolecular self-assembled systems (light driven supramolecular amphiphiles [30], supramolecular polymers [31,32]), biological nanosystems [5,33] and pharmacology [34].…”

Section: Introductionmentioning

confidence: 99%

Visualization and Comprehension of Electronic and Topographic Contrasts on Cooperatively Switched Diarylethene-Bridged Ditopic Ligand

Hnid¹,

Guan²,

Chatir³

et al. 2022

Preprint

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Diarylethene is a prototypical molecular switch that can be reversibly photoisomerized between its open and closed forms. Ligands bpy-DAE-bpy, consisting of a phenyl-diarylethene-phenyl (DAE) central core and bipyridine (bpy) terminal substituents, are able to self-organize. They are investigated by scanning tunneling microscopy at the solid-liquid interface. Upon light irradiation, cooperative photochromic switching of the ligands is recognized down to the sub-molecular level. The closed isomers show different electron density of states (DOS) contrasts, attributed to the HOMO or LUMO molecular orbitals observed. More importantly, the LUMO images show remarkable differences between the open and closed isomers, attributed to combined topographic and electronic contrasts mainly on the DAE moieties. The electronic contrasts from multiple HOMO or LUMO distributions, combined with topographic distortion of the open or closed DAE, are interpreted by density functional theory (DFT) calculations.

show abstract

Photochromic Diarylethenes Designed for Surface Deposition: From Self‐Assembled Monolayers to Single Molecules

Cited by 7 publications

References 116 publications

Dynamically Controlled Electronic Behavior of Stimuli‐Responsive Materials: Exploring Dimensionality and Connectivity

Dynamically Controlled Electronic Behavior of Stimuli‐Responsive Materials: Exploring Dimensionality and Connectivity

Visualization and Comprehension of Electronic and Topographic Contrasts on Cooperatively Switched Diarylethene-Bridged Ditopic Ligand

Visualization and Comprehension of Electronic and Topographic Contrasts on Cooperatively Switched Diarylethene-Bridged Ditopic Ligand

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