Abbe number

In physics and optics, the Abbe number, also known as the V-number or constringence of a transparent material, is a measure of the material's dispersion (variation of refractive index with wavelength) in relation to the refractive index, with high values of V indicating low dispersion (low chromatic aberration). It is named after Ernst Abbe (1840–1905), the German physicist who defined it.

The Abbe number,^[2]^[3] V_D, of a material is defined as

V_{D}={\frac {n_{D}-1}{n_{F}-n_{C}}},

where n_D, n_F and n_C are the refractive indices of the material at the wavelengths of the Fraunhofer D-, F- and C- spectral lines (589.3 nm, 486.1 nm and 656.3 nm respectively).

Abbe numbers are used to classify glass and other optically transparent materials. For example, flint glass has V < 50 and crown glass has V > 50. Typical values of V range from around 20 for very dense flint glass, around 30 for polycarbonate plastics, and up to 65 for very light crown glass, and up to 85 for fluor-crown glass. Abbe numbers are only a useful measure of dispersion for visible light, and for other wavelengths, or for higher precision work, the full dispersion relation (refractive index as a function of wavelength) is used.

Due to the difficulty and inconvenience in producing sodium and hydrogen lines, alternate definitions of the Abbe number are used in some contexts (ISO 7944).^[4] The value V_d is given by

V_{d}={\frac {n_{d}-1}{n_{F}-n_{C}}}

which defines the Abbe number with respect to the yellow Fraunhofer d (or D₃) helium line at 587.5618 nm wavelength. It can also be defined using the green mercury E-line at 546.073 nm:

V_{e}={\frac {n_{e}-1}{n_{F'}-n_{C'}}}

where F' and C' are the blue and red cadmium lines at 480.0 nm and 643.8 nm, respectively.

An Abbe diagram is produced by plotting the Abbe number V_d of a material versus its refractive index n_d. Glasses can then be categorised by their composition and position on the diagram. This can be a letter-number code, as used in the Schott Glass catalogue, or a 6-digit glass code.

Abbe numbers are used to calculate the necessary focal lengths of achromatic doublet lenses to minimize chromatic aberration.

The following table lists standard wavelengths at which n is usually determined, indicated by subscripts.^[5] For example, n_D is measured at 589.3 nm:

λ in nm	Fraunhofer's symbol	Light source	Color
365.01	i	Hg	UV
404.66	h	Hg	violet
435.84	g	Hg	blue
479.99	F'	Cd	blue
486.13	F	H	blue
546.07	e	Hg	green
587.56	d	He	yellow
589.3	D	Na	yellow
643.85	C'	Cd	red
656.27	C	H	red
706.52	r	He	red
768.2	A'	K	IR
852.11	s	Cs	IR
1013.98	t	Hg	IR

References

^ Abbe number calculation of glasses
^ Hovestadt, H. (1902). Jena Glass and Its Scientific and Industrial Applications. London: Macmillan and Co. pp. 1–81.
^ Bergmann, Ludwig; Clemens Schaefer (1999). Optics of Waves and Particles. Berlin: Walter de Gruyter. pp. 198–201. ISBN 3-11-014318-6.
^ Meister, Darryl. "Understanding Reference Wavelengths" (PDF). Carl Zeiss Vision. Retrieved 2013-03-13.
^ L. D. Pye, V. D. Frechette, N. J. Kreidl: "Borate Glasses"; Plenum Press, New York, 1977

External links

Abbe graph and data for 356 glasses from Ohara, Hoya, and Schott

[1] Abbe number calculation of glasses

[2] Hovestadt, H. (1902). Jena Glass and Its Scientific and Industrial Applications. London: Macmillan and Co. pp. 1–81.

[3] Bergmann, Ludwig; Clemens Schaefer (1999). Optics of Waves and Particles. Berlin: Walter de Gruyter. pp. 198–201. ISBN 3-11-014318-6.

[4] Meister, Darryl. "Understanding Reference Wavelengths" (PDF). Carl Zeiss Vision. Retrieved 2013-03-13.

[5] L. D. Pye, V. D. Frechette, N. J. Kreidl: "Borate Glasses"; Plenum Press, New York, 1977

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