Refractive index of BeAl2O4 (Beryllium aluminate, chrysoberyl)

Optical constants of BeAl₂O₄ (Beryllium aluminate, chrysoberyl)
Walling et al. 1980: n(γ) 0.25–2.6 µm

Wavelength: µm

(0.25–2.6)

Complex refractive index (n+ik)[ i ]

Derived optical constants

Dispersion formula [ i ]

$$n^2=1.70690+\frac{1.28477λ^{2}}{λ^2-0.01169}-0.01760λ^{2}$$

Comments

n_γ; Room temperature.

References

1) J. Walling, O. Peterson, H. Jenssen, R. Morris, E. O'Dell. Tunable alexandrite lasers, IEEE J. Quantum Electron., 16, 1302–1315 (1980)
2) P. Loiko, A. Major. Dispersive properties of alexandrite and beryllium hexaaluminate crystals, Opt. Mater. Express, 6, 2177–2183 (2016)
* Ref. 2 provides a dispersion formula based on the experimental data from Ref. 1

Data

[Expressions for n] [CSV - comma separated] [TXT - tab separated] [Full database record]

Optical transmission calculator

Wavelength: µm
Thickness:
Calculation method:

Transmittance[ i ]

T =

LogX LogY eV

Reflection calculator

Wavelength: µm
Angle of incidence (0~90°):
Direction: in out

Reflectance[ i ]

P-polarized

R_P =

S-polarized

R_S =

Non-polarized (Rp+Rs)/2

R =

R_P R_S R LogY

Reflection phase[ i ]

ɸ_P = °
ɸ_S = °

Brewster's angle[ i ]

θ_B = °

Critical angle[ i ] [ i ]

θ_C = °

INFO

Beryllium aluminate, BeAl₂O₄

BeAl₂O₄, commonly known as chrysoberyl, is a beryllium-aluminum oxide mineral that is noteworthy for its excellent hardness and durability. In the field of optics, chrysoberyl is used mainly as a gemstone and is not often encountered in technical applications due to its high cost and relative scarcity. However, its natural form, known as "cat's eye," is a unique gemstone admired for its chatoyancy. While not commonly utilized in high-technology optical applications, the properties of chrysoberyl, such as its excellent thermal stability and high hardness, could theoretically make it valuable in extreme environments where other materials may fail. The crystal structure of BeAl₂O₄ contributes to its remarkable hardness, which is second only to diamond among naturally occurring materials. Overall, while not a mainstream choice for technical optics, chrysoberyl remains an intriguing material whose unique characteristics could inspire future research and applications in specialized optical contexts.

RefractiveIndex.INFO

Optical constants of BeAl₂O₄ (Beryllium aluminate, chrysoberyl)
Walling et al. 1980: n(γ) 0.25–2.6 µm

Complex refractive index (n+ik)[ i ]

Refractive index[ i ]

Extinction coefficient[ i ]

Derived optical constants

Relative permittivity (dielectric constants)[ i ] [ i ]

Absorption coefficient[ i ] [ i ]

Abbe number[ i ]

Chromatic dispersion[ i ]

Group index[ i ] [ i ]

Group velocity dispersion[ i ] [ i ] [ i ]

Dispersion formula [ i ]

Comments

References

Data

Optical transmission calculator

Transmittance[ i ]

Reflection calculator

Reflectance[ i ]

P-polarized

S-polarized

Non-polarized (Rp+Rs)/2

Reflection phase[ i ]

Brewster's angle[ i ]

Critical angle[ i ] [ i ]

INFO

Beryllium aluminate, BeAl₂O₄

Other name

Mineral

External links

Optical constants of BeAl2O4 (Beryllium aluminate, chrysoberyl)Walling et al. 1980: n(γ) 0.25–2.6 µm

Complex refractive index (n+ik)[ i ]

Refractive index[ i ]

Extinction coefficient[ i ]

Derived optical constants

Relative permittivity (dielectric constants)[ i ] [ i ]

Absorption coefficient[ i ] [ i ]

Abbe number[ i ]

Chromatic dispersion[ i ]

Group index[ i ] [ i ]

Group velocity dispersion[ i ] [ i ] [ i ]

Dispersion formula [ i ]

Comments

References

Data

Optical transmission calculator

Transmittance[ i ]

Reflection calculator

Reflectance[ i ]

P-polarized

S-polarized

Non-polarized (Rp+Rs)/2

Reflection phase[ i ]

Brewster's angle[ i ]

Critical angle[ i ] [ i ]

INFO

Beryllium aluminate, BeAl2O4

Other name

Mineral

External links

Optical constants of BeAl₂O₄ (Beryllium aluminate, chrysoberyl)
Walling et al. 1980: n(γ) 0.25–2.6 µm

Beryllium aluminate, BeAl₂O₄