Hybrid Organic Semiconductors Including Chalcogen Atoms in π-Conjugated Skeletons. Tuning of Optical, Redox, and Vibrational Properties by Heavy Atom Conjugation

Casado, Juan; Oliva, María Moreno; Delgado, M. Carmen Ruiz; Ortiz, Rocío Ponce; Quirante, J.J.; Navarrete, Juan T. López; Takimiya, Kazuo; Otsubo, Tetsuo

doi:10.1021/jp061154p

Cited by 25 publications

(20 citation statements)

References 61 publications

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“…Addition of electronegative heteroatoms to the conjugated carbon skeleton has been shown to decrease the band gap by decreasing/increasing the LUMO/ HOMO energy, respectively. 99 Heteroatoms can also inuence the packing mode of the crystal. 94 For organic electrodes, functionalization has been commonly applied to modify the LUMO energy and thereby the redox voltage of the compound.…”

Section: Engineering Of Molecular Crystalsmentioning

confidence: 99%

Organic electrode materials with solid-state battery technology

2019

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Section: Engineering Of Molecular Crystalsmentioning

confidence: 99%

Organic electrode materials with solid-state battery technology

2019

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“…[83,84] However, this shift is associated not just with the increased mass of the selenium atom, but also with an increase in the delocalisation of the π-electron system due in part to greater coplanarity of the conjugated backbone. [85] Several studies have used Raman spectroscopy to probe the impacts of various atomic substitutions on the properties of conjugated molecules, and have shown that this simple chemical variation has profound effects not just on the force constants of the bonds, but also on the electron density distribution over the molecule, and molecular conformation as well as the molecular packing in the solid state. [84][85][86] One class of atomic substitution that has proven particularly useful for enhancing the semiconducting properties of conjugated molecules is fluorination.…”

Section: Heteroatom Substitution and Fluorinationmentioning

confidence: 99%

“…[85] Several studies have used Raman spectroscopy to probe the impacts of various atomic substitutions on the properties of conjugated molecules, and have shown that this simple chemical variation has profound effects not just on the force constants of the bonds, but also on the electron density distribution over the molecule, and molecular conformation as well as the molecular packing in the solid state. [84][85][86] One class of atomic substitution that has proven particularly useful for enhancing the semiconducting properties of conjugated molecules is fluorination. The replacement of hydrogen atoms with fluorine has a strong electron withdrawing effect from the conjugated part of the molecule, and also modifies the molecular packing.…”

Section: Heteroatom Substitution and Fluorinationmentioning

confidence: 99%

Raman spectroscopy as an advanced structural nanoprobe for conjugated molecular semiconductors

Wood¹,

Hollis²,

Kim³

2017

J. Phys. D: Appl. Phys.

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Raman spectroscopy has emerged as a powerful and important characterisation tool for probing molecular semiconducting materials. The useful optoelectronic properties of these materials arise from the delocalised -electron density in the conjugated core of the molecule, which also results in large Raman scattering cross-sections and a strong coupling between its electronic states and vibrational modes. For this reason, Raman spectroscopy offers a unique insight into the properties of molecular semiconductors, including: chemical structure, molecular conformation, molecular orientation, and fundamental photo-and electro-chemical processes-all of which are critically important to the performance of a wide range of optical and electronic organic semiconductor devices. Experimentally, Raman spectroscopy is non-intrusive, non-destructive, and requires no special sample preparation, and so is suitable for a wide range of in situ measurements, which are particularly relevant to issues of thermal and photochemical stability. Here we review the development of the family of Raman spectroscopic techniques, which have been applied to the study of conjugated molecular semiconductors. We consider the suitability of each technique for particular circumstances, and the unique insights it can offer, with a particular focus on the significance of these measurements for the continuing development of stable, high performance organic electronic devices.

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“…Structurally similar to thiophene, two other ve-membered heterocycles in the chalcogenophene family-selenophene and tellurophene, featuring group-16 Se and Te elements, respectively-have attracted considerable interest because (1) Se and Te atoms are larger and have d-orbitals of higher polarizability (relative to S) to induce strong Se/Se and Te/Te attractions, potentially strengthening their interpolymer interactions, [37][38][39][40][41] and (2) as the chalcogen becomes heavier, the p-electrons in selenophene and tellurophene tend to adopt a more quinoidal character with higher coplanarity, giving rise to narrower band gaps and bathochromic shis in their absorption. [42][43][44][45][46][47][48][49][50] The homopolymers 3alkylselenophene (P3AS) 51,52 and 3-alkyltellurophene (P3ATe) 53,54 have also been prepared using the KCTP. We were interested in studying the effects of incorporating two different chalcogenophenes into a single polymer to generate a new class of poly(bichalcogenophene)s. By integrating thiophene, selenophene, and tellurophene units in a single polymer in a controlled sequence, the properties of the polymer could presumably be tailored specically.…”

Section: Introductionmentioning

confidence: 99%