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Proceedings Paper

Fluorescence quantum efficiency of three samples at atmosphere based on electrospray ionization and drift tube of ion mobility spectrometry
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Paper Abstract

In the traditional fluorescence detection, samples are tested in the solvent, and the mutual effect of solvent, micro impurity and sample affects the fluorescence characteristics. Meanwhile, such effect includes vibrational relaxation, electron rearrangement of solvent molecule, special role of the sample with the solvent molecules and so on. The experiment of fluorescence quantum efficiency at atmosphere reduces the interference, because the distance between molecules is much larger in gas phase. In addition, the research of quantum efficiency can also promote the understanding of LIF and expand the range.

In this paper, the fluorescence quantum efficiency of 3 different samples at atmosphere was compared, and the electrospray ionization source was selected for its soft ionization characteristics. The ionization method did not spoil the fluorophore of the sample, and the drift tube of ion mobility spectrometry (IMS) was used for ions transport and desolvation. The ionization source was on the one side of the drift tube and the test point was on the other side. The paths of excited laser and emission light were orthogonal at the test point. Meanwhile, stable ions flowed through the drift tube. The emission light was captured by the camera, which was coupled with a long-wave pass filter. The test samples were Rhodamine 6G,Rhodamine B and amino copper indium sulfide quantum dots of the same mass fraction. The energy of excited laser was between 30 mW and 150 mW. Then the results showed that the emission intensity was proportional to the laser power in gas phase, and the sort of the fluorescence quantum efficiency was the quantum dots>Rhodamine 6G>Rhodamine B.

Paper Details

Date Published: 5 November 2018
PDF: 7 pages
Proc. SPIE 10816, Advanced Optical Imaging Technologies, 1081611 (5 November 2018); doi: 10.1117/12.2326969
Show Author Affiliations
Yuan Shi, Tsinghua Univ. (China)
Kaitai Guo, Tsinghua Univ. (China)
Kai Ni, Tsinghua Univ. (China)
Quan Yu, Tsinghua Univ. (China)
Xiaohao Wang, Tsinghua Univ. (China)

Published in SPIE Proceedings Vol. 10816:
Advanced Optical Imaging Technologies
Xiao-Cong Yuan; Kebin Shi; Michael G. Somekh, Editor(s)

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