Refractive index of C (Carbon, diamond, graphite, graphene, carbon nanotubes)

Optical constants of C (Carbon, diamond, graphite, graphene, carbon nanotubes)
Querry 1985: Graphite pellet, Dixon 200-10; n,k 0.21–55.6 µm

Wavelength: µm

(0.2100–55.5556)

Complex refractive index (n+ik)[ i ]

Derived optical constants

Comments

Graphite pellet from Dixon 200-10 powder.

References

M. R. Querry. Optical constants, Contractor Report CRDC-CR-85034 (1985)

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

Carbon, C

Carbon (C) is a non-metallic element that serves as the building block for an astonishing range of materials with diverse properties, from soft graphite to hard diamond. In its diamond form, carbon exhibits remarkable hardness, high thermal conductivity, and a wide bandgap of around 5.47 eV, making it suitable for high-power electronics, cutting tools, and optical applications. Graphite, on the other hand, is a good conductor of electricity and is used in lubricants, batteries, and as a moderator in nuclear reactors. Carbon's most groundbreaking allotropes, graphene and carbon nanotubes, have introduced a host of possibilities in nanotechnology, optoelectronics, and materials science due to their exceptional electrical, mechanical, and thermal properties. Graphene, a single layer of carbon atoms arranged in a hexagonal lattice, boasts unparalleled electrical conductivity and mechanical strength. Carbon can be synthesized and manipulated using a variety of methods, including chemical vapor deposition (CVD), arc-discharge, and laser ablation. The versatility and multifaceted nature of carbon make it a central element in both established and emerging technologies, spanning from traditional uses like steelmaking to cutting-edge applications in quantum computing and biotechnology.

Most common allotropes

Diamond (cubic carbon)
Graphite
Amorphous carbon
Graphene
Carbon nanotube

RefractiveIndex.INFO

Optical constants of C (Carbon, diamond, graphite, graphene, carbon nanotubes)
Querry 1985: Graphite pellet, Dixon 200-10; n,k 0.21–55.6 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 ]

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

Carbon, C

Most common allotropes

External links

Optical constants of C (Carbon, diamond, graphite, graphene, carbon nanotubes)Querry 1985: Graphite pellet, Dixon 200-10; n,k 0.21–55.6 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 ]

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

Carbon, C

Most common allotropes

External links

Optical constants of C (Carbon, diamond, graphite, graphene, carbon nanotubes)
Querry 1985: Graphite pellet, Dixon 200-10; n,k 0.21–55.6 µm