Hole-burning structure and mechanism of acridine and aminoacridines doped in polyvinyl alcohol films

Chien Chih Chiang; Ji Yen Cheng; Yah Ru Cheng; Hsuan Shen Chen; Chung Yuan Mou; Ta Chau Chang

doi:10.1080/10587259608042745

Hole-burning structure and mechanism of acridine and aminoacridines doped in polyvinyl alcohol films

Chien Chih Chiang, Ji Yen Cheng, Yah Ru Cheng, Hsuan Shen Chen, Chung Yuan Mou, Ta Chau Chang

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

Persistent hole-burning spectra of protonated acridine, 9-aminoacridine and proflavine doped in polyvinyl alcohol films have been studied to examine how the functional group affects chromophore-glass interactions. Proton transfer between the chromophore and the matrix upon electronic excitation is proposed to be the mechanism for the hole burned spectra of the three molecules studied. The high resolution of the spectrum of 9-aminoacridine is attributed to reduction of the electron-phonon coupling strength when substituting an amino group to the C(9) position of acridine. However, when substituting two amino groups to the C(3) and C(6) positions of acridine, significant increase of the electron-phonon coupling strength decreases the spectral resolution of proflavine.

Original language	English
Pages (from-to)	175-181
Number of pages	7
Journal	Molecular Crystals and Liquid Crystals Science and Technology Section A: Molecular Crystals and Liquid Crystals
Volume	291
DOIs	https://doi.org/10.1080/10587259608042745
Publication status	Published - 1996
Externally published	Yes

ASJC Scopus subject areas

Condensed Matter Physics

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Hole-burning structure and mechanism of acridine and aminoacridines doped in polyvinyl alcohol films. / Chiang, Chien Chih; Cheng, Ji Yen; Cheng, Yah Ru et al.
In: Molecular Crystals and Liquid Crystals Science and Technology Section A: Molecular Crystals and Liquid Crystals, Vol. 291, 1996, p. 175-181.

Research output: Contribution to journal › Article › peer-review

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title = "Hole-burning structure and mechanism of acridine and aminoacridines doped in polyvinyl alcohol films",

abstract = "Persistent hole-burning spectra of protonated acridine, 9-aminoacridine and proflavine doped in polyvinyl alcohol films have been studied to examine how the functional group affects chromophore-glass interactions. Proton transfer between the chromophore and the matrix upon electronic excitation is proposed to be the mechanism for the hole burned spectra of the three molecules studied. The high resolution of the spectrum of 9-aminoacridine is attributed to reduction of the electron-phonon coupling strength when substituting an amino group to the C(9) position of acridine. However, when substituting two amino groups to the C(3) and C(6) positions of acridine, significant increase of the electron-phonon coupling strength decreases the spectral resolution of proflavine.",

author = "Chiang, {Chien Chih} and Cheng, {Ji Yen} and Cheng, {Yah Ru} and Chen, {Hsuan Shen} and Mou, {Chung Yuan} and Chang, {Ta Chau}",

note = "Funding Information: This work was supported by the Academia Sinica and the NSC of the Republic of China",

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T1 - Hole-burning structure and mechanism of acridine and aminoacridines doped in polyvinyl alcohol films

AU - Chiang, Chien Chih

AU - Cheng, Ji Yen

AU - Cheng, Yah Ru

AU - Chen, Hsuan Shen

AU - Mou, Chung Yuan

AU - Chang, Ta Chau

N1 - Funding Information: This work was supported by the Academia Sinica and the NSC of the Republic of China

PY - 1996

Y1 - 1996

N2 - Persistent hole-burning spectra of protonated acridine, 9-aminoacridine and proflavine doped in polyvinyl alcohol films have been studied to examine how the functional group affects chromophore-glass interactions. Proton transfer between the chromophore and the matrix upon electronic excitation is proposed to be the mechanism for the hole burned spectra of the three molecules studied. The high resolution of the spectrum of 9-aminoacridine is attributed to reduction of the electron-phonon coupling strength when substituting an amino group to the C(9) position of acridine. However, when substituting two amino groups to the C(3) and C(6) positions of acridine, significant increase of the electron-phonon coupling strength decreases the spectral resolution of proflavine.

AB - Persistent hole-burning spectra of protonated acridine, 9-aminoacridine and proflavine doped in polyvinyl alcohol films have been studied to examine how the functional group affects chromophore-glass interactions. Proton transfer between the chromophore and the matrix upon electronic excitation is proposed to be the mechanism for the hole burned spectra of the three molecules studied. The high resolution of the spectrum of 9-aminoacridine is attributed to reduction of the electron-phonon coupling strength when substituting an amino group to the C(9) position of acridine. However, when substituting two amino groups to the C(3) and C(6) positions of acridine, significant increase of the electron-phonon coupling strength decreases the spectral resolution of proflavine.

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Hole-burning structure and mechanism of acridine and aminoacridines doped in polyvinyl alcohol films

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