Optical constants in the IR from thin film interference and reflectance: the reststrahlen region of muscovite mica

Edgar B. Singleton; Charles T. Shirkey

doi:10.1364/AO.22.000185

Applied Optics
Vol. 22,
Issue 1,
pp. 185-189
(1983)
•https://doi.org/10.1364/AO.22.000185

Optical constants in the IR from thin film interference and reflectance: the reststrahlen region of muscovite mica

Edgar B. Singleton and Charles T. Shirkey

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Edgar B. Singleton and Charles T. Shirkey, "Optical constants in the IR from thin film interference and reflectance: the reststrahlen region of muscovite mica," Appl. Opt. 22, 185-189 (1983)

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Abstract

A new technique for determining the IR optical constants of materials that can be formed into thin films is presented. At a given wavelength the thickness of the film t, the index of refraction n, and the extinction coefficient k combine to produce interference effects in the film, which in turn control reflectance from the film. When reflectance is plotted vs thickness the resultant curve is a unique function of n and k. Values of n and k are determined by curve fitting. The technique is illustrated using thin films of muscovite mica, and values of n and k are reported for wave numbers from 1200 to 400 cm⁻¹, which include the reststrahlen region of mica.

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Wave number (cm⁻¹)	n	k
1200	1.00	0.03
1180	0.79	0.04
1160	0.62	0.08
1140	0.43	0.20
1120	0.30	0.61
1100	0.34	0.99
1080	0.55	1.50
1060	0.81	1.54
1040	0.95	2.30
1020	1.78	2.30
1000	2.49	1.90
980	2.98	1.34
960	2.62	0.45
940	2.30	0.30
920	2.26	0.40
900	2.25	0.30
880	2.16	0.18
860	1.88	0.11
840	1.84	0.09
820	1.80	0.10
800	1.77	0.14
780	1.76	0.13
760	1.73	0.20
740	1.74	0.27
720	1.79	0.19
700	1.73	0.21
680	1.50	0.19
660	1.45	0.16
640	1.46	0.20
620	0.87	0.37
600	0.65	0.70
580	0.60	1.25
560	0.70	1.75
540	1.64	2.36
520	1.93	2.13
500	1.80	1.80
480	2.00	2.70
460	2.90	2.04
440	3.00	1.15
420	2.95	1.10
400	3.20	1.25

Vedder8 (cm⁻¹)		Present work
Vedder8 (cm⁻¹)		Transmission minima (Fig. 5) (cm⁻¹)	(nk) (Fig. 7) (cm⁻¹)
472υs		470	470
528υs		530	530
755w		750	742
805w		800	800
928m		920	920
985s	}	1000	1000
1024υs	}
1070s		1075	1080

Wave number (cm⁻¹)	n	k
1200	1.00	0.03
1180	0.79	0.04
1160	0.62	0.08
1140	0.43	0.20
1120	0.30	0.61
1100	0.34	0.99
1080	0.55	1.50
1060	0.81	1.54
1040	0.95	2.30
1020	1.78	2.30
1000	2.49	1.90
980	2.98	1.34
960	2.62	0.45
940	2.30	0.30
920	2.26	0.40
900	2.25	0.30
880	2.16	0.18
860	1.88	0.11
840	1.84	0.09
820	1.80	0.10
800	1.77	0.14
780	1.76	0.13
760	1.73	0.20
740	1.74	0.27
720	1.79	0.19
700	1.73	0.21
680	1.50	0.19
660	1.45	0.16
640	1.46	0.20
620	0.87	0.37
600	0.65	0.70
580	0.60	1.25
560	0.70	1.75
540	1.64	2.36
520	1.93	2.13
500	1.80	1.80
480	2.00	2.70
460	2.90	2.04
440	3.00	1.15
420	2.95	1.10
400	3.20	1.25

Vedder8 (cm⁻¹)		Present work
Vedder8 (cm⁻¹)		Transmission minima (Fig. 5) (cm⁻¹)	(nk) (Fig. 7) (cm⁻¹)
472υs		470	470
528υs		530	530
755w		750	742
805w		800	800
928m		920	920
985s	}	1000	1000
1024υs	}
1070s		1075	1080

Abstract

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Figures (7)

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Equations (3)

Applied Optics