Refractive index of Au (Gold)

Optical constants of Au (Gold)
Rakić et al. 1998: Brendel-Bormann model; n,k 0.248–6.20 µm

Wavelength: µm

(2.4797e-01–6.1992e+00)

Complex refractive index (n+ik)[ i ]

Derived optical constants

Conditions & Spec sheet

n_is_absolute: true
wavelength_is_vacuum: true

Comments

Fit of experimental data from several sources to Brendel-Bormann (BB) model.

References

A. D. Rakić, A. B. Djurišic, J. M. Elazar, and M. L. Majewski. Optical properties of metallic films for vertical-cavity optoelectronic devices, Appl. Opt. 37, 5271-5283 (1998)
[Calculation script (Python)]

Data

[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

Gold, Au

Gold (Au) is a noble metal renowned for its unique combination of chemical stability, high reflectivity, and excellent electrical conductivity. In optics, gold is often used as a thin-film coating for mirrors and other optical components, particularly in applications requiring high reflectivity in the infrared range. Its stability against oxidation and corrosion ensures long-lasting performance, making it a preferred material for harsh or sensitive environments. Gold nanoparticles have also garnered attention in the field of plasmonics, where they are used to manipulate light on the nanoscale and have found applications in sensing, imaging, and photothermal therapy. Unlike many other metals, gold's optical properties are relatively consistent over a broad range of conditions, but it's important to note that its refractive index and other optical characteristics can vary based on its form—be it bulk, thin film, or nanoparticle. Given its unique attributes and versatility, gold remains an invaluable material in both classical and cutting-edge optical technologies.

RefractiveIndex.INFO

Optical constants of Au (Gold)
Rakić et al. 1998: Brendel-Bormann model; n,k 0.248–6.20 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 ]

Conditions & Spec sheet

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

Gold, Au

External links

Optical constants of Au (Gold)Rakić et al. 1998: Brendel-Bormann model; n,k 0.248–6.20 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 ]

Conditions & Spec sheet

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

Gold, Au

External links

Optical constants of Au (Gold)
Rakić et al. 1998: Brendel-Bormann model; n,k 0.248–6.20 µm