Development of an Ultraviolet Raman Spectrometer for Standoff Detection of Chemicals |
Ha, Yeon Chul
(Agency for Defense Development)
Lee, Jae Hwan (Agency for Defense Development) Koh, Young Jin (Agency for Defense Development) Lee, Seo Kyung (Samyang Chemical Co., Ltd.) Kim, Yun Ki (Samyang Chemical Co., Ltd.) |
1 | E. B. Hanlon, R. Manoharan, T. W. Koo, K. E. Shafer, J. T. Motz, M. Fitzmaurice, J. R. Kramer, I. Itzkan, R. R. Dasari, and M. S. Feld, "Prospects for in vivo Raman spectroscopy," Phys. Med. Biol. 45, R1-R59 (2000). DOI |
2 | D. H. M. Lin, D. Manara, P. Lindqvist-Reis, T. Fanghanel, and K. Mayer, "The use of different dispersive Raman spectrometers for the analysis of uranium compounds," Vib. Spectrosc. 73, 102-110 (2014). DOI |
3 | J. Zhao and R. L. McCreery, "Multichannel FT-Raman spectroscopy: Noise analysis and performance assessment," Appl. Spectrosc. 51, 1687-1697 (1997). DOI |
4 | V. Pajcini, C. H. Munro, R. W. Bormett, R. E. Witkowski, and S. A. Asher, "UV Raman microspectroscopy: Spectral and spatial selectivity with sensitivity and simplicity," Appl. Spectrosc. 51, 81-86 (1997). DOI |
5 | S. Jin, Z. Feng, F. Fan, and C. Li, "UV Raman spectroscopic characterization of catalysts and catalytic active sites," Catal. Lett. 145, 468-481 (2015). DOI |
6 | R. Bhartia, W. F. Hugb, and R. D. Reid, "Improved sensing using simultaneous deep UV Raman and fluorescence detection," Proc. SPIE 8358, 83581A 1-9 (2012). |
7 | C. H. Camp Jr, Y. J. Lee, J. M. Heddleston, C. M. Hartshorn, A. R. Hight Walker, J. N. Rich, J. D. Lathia, and M. T. Cicerone, "High-speed coherent Raman fingerprint imaging of biological tissues," Nature Photon. 8, 627-634 (2014). DOI |
8 | E. L. Izake, S. Sundarajoo, W. Olds, B. Cletus, E. Jaatinen, and P. M. Fredericks, "Standoff Raman spectrometry for the non-invasive detection of explosives precursors in highly fluorescing packaging," Talanta 103, 20-27 (2013). DOI |
9 | S. M. Norton, "High-throughput spectrometer designs in a compact form-factor: Principles and applications," Proc. SPIE 8726, 87260L 1-11 (2013). |
10 | Y. Wu, Y. Tang, and G. Ni, "Design of FUV imaging spectrometer based on crossed Czerny-Turner structure," Proc. SPIE 7156, 715628 1-7 (2009). |
11 | P. J. Larkin, W. G. Gustafson, and S. A. Asher, "A new Raman cross section measurement technique monitors the tyrosine environmental dependence of the electromagnetic field strength," J. Chem. Phys. 94, 5324-5330 (1991). DOI |
12 | A. Gruger, A. Regis, T. Schatko, and P. Colomban, "Nanostructure of Nafion membranes at different states of hydration: An IR and Raman study," Vib. Spectrosc. 26, 215-225 (2001). DOI |
13 | C. Wang, Y.-L. Pan, S. C. Hill, and B. Redding, "Photo-phoretic trapping-Raman spectroscopy for single pollens and fungal spores trapped in air," QSRT 153, 4-12 (2015). |
14 | M. L. Frezzotti, F. Tecce, and A. Casagli, "Raman spectroscopy for fluid inclusion analysis," JGE 112, 1-20 (2012). |
15 | H. Hamaguchi and A. Hirakawa, Raman spectroscopy, 240-256 (Kookmin University, Korea, 2006). |