Refractive index of AgBr (Silver bromide)

Optical constants of AgBr (Silver bromide)
Schröter 1931: n 0.495–0.67 µm

Wavelength: µm

(0.495–0.67)

Complex refractive index (n+ik)[ i ]

Derived optical constants

Dispersion formula

$$\frac{n^2-1}{n^2+2}=0.452505+\frac{0.09939λ^2}{λ^2-0.070537}-0.000150λ^2$$

References

H. Schröter. Über die Brechungsindizes einiger Schwermetallhalogenide im Sichtbaren und die Berechnung von Interpolationsformeln für den Dispersionsverlauf (On the refractive indices of some heavy-metal halides in the visible and calculation of interpolation formulas for dispersion), Z. Phys. 67, 24-36 (1931) [in German]

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

Silver bromide, AgBr

AgBr, or silver bromide, is an inorganic compound that has been extensively studied for its photo-sensitive properties. This ionic material forms a face-centered cubic crystal structure and exhibits a direct bandgap, making it an effective absorber of photons. Historically, AgBr has been a key material in traditional photographic films, where exposure to light leads to the reduction of the material and the formation of elemental silver, thereby creating a visible image. In the realm of modern technology, AgBr is being explored for its utility in optoelectronic devices, such as photodetectors and solar cells. Its wide bandgap and high refractive index make it suitable for applications requiring spectral selectivity and efficient light-matter interactions. However, it is sensitive to environmental factors like humidity and needs to be carefully encapsulated or treated to maintain its optical characteristics. In addition to its bulk form, AgBr nanostructures have also been studied for their unique optical and catalytic properties. Overall, AgBr continues to be a material of significant interest in both historical and emerging technologies, thanks to its unique photo-responsive behavior and optoelectronic properties.

RefractiveIndex.INFO

Optical constants of AgBr (Silver bromide)
Schröter 1931: n 0.495–0.67 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

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

Silver bromide, AgBr

External links

Optical constants of AgBr (Silver bromide)Schröter 1931: n 0.495–0.67 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

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

Silver bromide, AgBr

External links

Optical constants of AgBr (Silver bromide)
Schröter 1931: n 0.495–0.67 µm