Directed self-assembly of viologen-based 2D semiconductors with intrinsic UV–SWIR photoresponse after photo/thermo activation

Yu, Xiaoqing; Sun, Cai; Liu, Bin‐Wen; Wang, Mingsheng; Guo, Guo‐Cong

doi:10.1038/s41467-020-14986-7

Cited by 105 publications

(60 citation statements)

References 55 publications

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“…Their intensity increases gradually with the duration of irradiation time and nearly reaches an ultimate saturation level after illumination for 25 min. On the basis of previous reports, − the characteristic absorption bands may result from the photogenerated viologen radicals through intra- and/or intermolecular electron transfer, which has indeed been confirmed by EPR studies.…”

Section: Results and Discussionsupporting

confidence: 74%

A Photochromic Zinc–Viologen Framework with a High-Contrast Nonlinear Optical Switchable Behavior

Yan

et al. 2021

Crystal Growth & Design

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As an important branch of nonlinear optical (NLO) switches, second-harmonic-generation (SHG) switches undergoing reversible SHG-on and SHG-off states upon external stimuli exposure have been the focus of intense scientific research due to their potential applications in photoelectric technologies. The high-contrast switching of SHG, a key issue for the potential applications of SHG optical switches, has been a challenge but is undoubtedly very interesting. Incorporating stimuli-responsive molecules into the SHG-active materials is an efficient approach to construct high-contrast SHG switches. In this paper, by using the ligand 1-(4-cyanobenzyl)-4,4′-bipyridinium (CBbpy) as a photosensitive group, a noncentrosymmetric photochromic zinc–viologen framework, {[(CBbpy)Zn3(TBC)(HTBC)(OH)]·NO3}n (1; H3BTC = 1,3,5-benzenetricarboylic acid), has been obtained. It shows an SHG intensity of 1.1 × KH2PO4 (KDP) due to the synergistic effect of the coplanar and parallel arrangement of NO3 – anions, the asymmetric disposition of electron densities, and the large permanent dipole moment, as confirmed by Bader charge and dipole moment calculations. More importantly, an outstanding SHG switching contrast was found to be at least 23 times larger than that of the coloration sample under a 1064 nm laser beam, originating from the large difference in the dipole moment and the self-absorption effect before and after coloration. Such excellent SHG switching is reversible and can be cycled several times, indicating that 1 is a good candidate as a new solid-state SHG-switching material. This work should prompt researchers to explore novel high-performance SHG switches based on devisable stimuli-responsive groups.

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Section: Results and Discussionsupporting

confidence: 74%

A Photochromic Zinc–Viologen Framework with a High-Contrast Nonlinear Optical Switchable Behavior

Yan

et al. 2021

Crystal Growth & Design

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“…Photoinduced electron transfer (PIET) using an electron-transfer photochromic ligand, like viologen, − especially favors postsynthesis, because a radical product may be generated in situ and the limit of stereospace is tiny. As for the second challenge, our group has recently established an effective coordination-directed intercalation self-assembly method; however, this method is still subjected to cyano-bridged systems to date.…”

Section: Introductionmentioning

confidence: 99%

Broadband Photoresponsive Bismuth Halide Hybrid Semiconductors Built with π-Stacked Photoactive Polycyclic Viologen

Jiang

Sun

et al. 2021

Inorg. Chem.

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Photoresponse ranges of commercially prevailing photoelectric semiconductors, typically Si and InGaAs, are far from fully covering the whole solar spectrum (∼295−2500 nm), resulting in insufficient solar energy conversion or narrow wave bands for photoelectric detection. Recent studies have shown that infinite π-aggregation of viologen radicals can provide semiconductors with a photoelectric response range covering the solar spectrum. However, controlled assembly of an infinite π-aggregate is still a great challenge in material design. Through directional self-assembly of electron-transfer photoactive polycyclic ligands, two crystalline inorganic− organic hybrid photochromic viologen-based bismuth halide semiconductors, ((Me) 3 pytpy)[BiCl 6 ]•2H 2 O [1; (Me) 3 pytpy = N,N′,N″-trimethyl-2,4,6-tris(4pyridyl)pyridine] and ((Me) 3 pytpy)[Bi 2 Cl 9 ]•H 2 O (2), have been synthesized. They represent the first series of pytpy-based photochromic compounds. After photoinduced coloration, the conductivities of both 1 and 2 increased. The radical products have electron absorption bands in the range of 200−1600 nm, exceeding that of Si. Both the conductivity and the photocurrent intensity of 2 are stronger than those of 1, due to better planarity, tighter π-stacking, and higher degrees of overlap of ((Me) 3 pytpy) 3+ cations. This study not only provides a new design idea for synthesizing radical-based multispectral photoelectric semiconductors but also enriches the family of electrontransfer photochromic compounds.

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“…In this respect, the electron-transfer photochromic complexes undoubtedly can be served as an ideal medium, in which naked-eye detectible color changes are easily observed and relatively stable radicals can be effectively regulated through direct light irradiation. Hitherto, lots of photochromic complexes have been prepared by using the donor-acceptor strategy, exemplified by some inorganicorganic hybrid photochromic frameworks, in which electronrich inorganic motifs like metallophosphates, polyoxomolybdates and halometallates [20][21][22] may offer electrons while electron-deficient organic groups [23][24][25] may be prone to accepting and stabilizing generated radicals. However, it is still a pivotal research challenge for extremely improving the stability of the photogenerated radicals under ambient conditions, which could greatly enhance the catalysis, luminescence and conductivity of the radical-based functional properties.…”

Section: Introductionmentioning

confidence: 99%

Optically actuating ultra-stable radicals in a large π-conjugated ligand constructed photochromic complex

Jiang

et al. 2021

Sci. China Chem.

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Producing ultra-stabilized radicals via light irradiation has raised considerable concern but remains a tremendous challenge in functional materials. Herein, optically actuating ultra-stable radicals are discovered in a sterically encumbered and large πconjugated tri(4-pyridyl)-1,3,5-triazine (TPT) ligands constructed photochromic compound Cu 3 (H-HEDP) 2 TPT 2 •2H 2 O (QDU-12; HEDP=hydroxyethylidene diphosphonate). The photogeneration of TPT• radicals is the photoactive behavior of electron transfer from HEDP motifs to TPT units. The ultra-long-lived radicals are contributed from strong interchain π-π interactions between the large π-conjugated TPT components, with the radical lifetime maintained for about 18 months under ambient conditions. Moreover, the antiferromagnetic couplings between TPT • radicals and Cu 2+ ions plummeted the demagnetization to 35% of its original state after light irradiation, showing the largest room temperature photodemagnetization in the current radicalbased photochromic materials.

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Directed self-assembly of viologen-based 2D semiconductors with intrinsic UV–SWIR photoresponse after photo/thermo activation

Cited by 105 publications

References 55 publications

A Photochromic Zinc–Viologen Framework with a High-Contrast Nonlinear Optical Switchable Behavior

A Photochromic Zinc–Viologen Framework with a High-Contrast Nonlinear Optical Switchable Behavior

Broadband Photoresponsive Bismuth Halide Hybrid Semiconductors Built with π-Stacked Photoactive Polycyclic Viologen

Optically actuating ultra-stable radicals in a large π-conjugated ligand constructed photochromic complex

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