Optical temperature sensing based on the Goos-Hänchen effect

Applied Optics

Volumn 46, Issue 22, 2007, Pages 5347-5351

  Chen, Chih Wei ^a,b   Lin, Wen Chi ^a,b   Liao, Lu Shing ^a,b   Lin, Zheng Hung ^a,b   Chiang, Hai Pang ^a,b   Leung, Pui Tak ^c   Sijercic, Edin ^c   Tse, Wan Sun ^d  

^a NATIONAL TAIWAN OCEAN UNIVERSITY   (Taiwan)

^b INSTITUTE OF PHYSICS   (Taiwan)

^c PORTLAND STATE UNIVERSITY   (United States)

^d MINGHSIN UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Taiwan)

Author keywords

[No Author keywords available]

Indexed keywords

DIELECTRIC MATERIALS; LIGHT POLARIZATION; MATHEMATICAL MODELS; OPTICAL SENSORS;

METAL-DIELECTRIC INTERFACES; OPTICAL TEMPERATURE SENSING;

TEMPERATURE SENSORS;

EID: 35448989715     PISSN: 1559128X     EISSN: 15394522     Source Type: Journal    
DOI: 10.1364/AO.46.005347     Document Type: Article

References (19)

1. See, e.g. K. Ujihahr, "Reflectivity of metals at high temperatures," J. App. Phys. 43, 2376-2383 (1972).
2. See, e.g., Y. Liu, M. Choy, A. Mandelis, J. Batista, and B. Li, "Laser thermoreflectance temperature measurements of metal coating alloys on a rotating platform," J. Phys. IV 125, 601-604 (2005), and references therein.
3. See, e.g., F. Lang and P. Leiderer, "Liquid-vapour phase transitions at interfaces: sub-nanosecond investigations by monitoring the ejection of thin liquid films," New J. Phys. 8, 14 (2006), and references therein.
4. H.-P. Chiang, Y.-C. Wang, P. T. Leung, and Wan-Sun Tse, "A theoretical model for the temperature-dependent sensitivity of the optical sensor based on surface plasmon resonance," Opt. Commun. 188, 283 (2001).
5. H.-P. Chiang, Y.-C. Wang, P. T. Leung, and Wan-Sun Tse," Surface plasmon resonance monitoring of temperature via phase measurement," Opt. Commun. 241, 409-418 (2004).
6. S. K. Ozdemir and G. Turhan-Sayan, "Temperature effects on surface plasmon resonance: design considerations for an optical temperature sensor," J. Lightwave Tech. 21, 805-814 (2003).
7. A. K. Sharma and B. D. Gupta, "Theoretical model of a fiber optic remote sensor based on surface plasmon resonance for temperature detection," Opt. Fiber Tech. 12, 87-100 (2006).
8. X. Yin and L. Hesselink, "Goos - Hänchen shift surface plasmon resonance sensor," Appl. Phys. Lett. 89, 261108 (2006).
9. F. Goos and H. Hänchen, "Ein neue und fundamentaler Versuch zur total reflection," Ann. Phys. 1, 333-346 (1947).
10. F. Goos and H. Hänchen, "Neumessung des strahlversetzungseffektes bei totalreflexion," Ann. Phys. 5, 251-252 (1949).
11. For an earlier comprehensive review, see H. Lotsch, "Beam displacement at total reflection: the Goos - Hänchen effect," Optik 32, 116-137 (1970).
12. H. Lotsch, "Beam displacement at total reflection: the Goos -Hänchen effect," Optik 32, 299-319 (1971).
13. H. Lotsch, "Beam displacement at total reflection: the Goos -Hänchen effect," Optik 32, 553-569 (1971).
14. W. J. Wild and C. L. Giles, "Goos-Hänchen shifts from absorbing media," Phys. Rev. A 25, 2099-2101 (1982).
15. H. M. Lai and S. W. Chan, "Large and negative Goos-Hänchen shift near Brewster dip on reflection from weakly absorbing media," Opt. Lett. 27, 680-682 (2002).
16. P. T. Leung, C.-W. Chen, and H.-P. Chiang, "Large negative Goos - Hänchen shift at metal surfaces," Opt. Commun. 276, 206-208 (2007).
17. Most of the details for the temperature model can be found in H.-P. Chiang, P. T. Leung, and Wan-Sun Tse, "Optical properties of composite materials at high temperatures," Solid State Commun. 101, 45-50 (1997).
18. Strictly speaking the effective mass does have a minor dependence on temperature, the theoretical modeling of such dependence will be extremely complicated. This was discussed, e.g., in a recent article by M. Rashidi-Huyeh and B. Palpant, "Counterintuitive thermo-optical response of metal-dielectric nanocomposite materials as a result of local electromagnetic field enhancement," Phys. Rev. B 74, 075405 (2006).
19. D. Z. Han, F. Q. Wu, X. Li, X. H. Liu, and J. Zi, "Enhanced transmission of optically thick metallic films at infrared wavelengths," Appl. Phys. Lett. 88, 161110 (2006).