Lampworked dichroic glass bead
In optics, a dichroic material is either one which causes visible light to be split up into distinct beams of different wavelengths (colours) (not to be confused with dispersion), or one in which light rays having different polarizations are absorbed by different amounts.[1]
Etymology
[edit]The term is derived from the Greek dichroos, meaning "two-colored," referring to the optical effect where a substance appears to have different colors when viewed from different angles or through different polarizations.
Types of dichroism
[edit]Dielectric (thin-film) dichroism
[edit]Dichroic filters or mirrors use alternating layers of optical coatings with different refractive indices to produce thin-film interference. This allows specific wavelengths to be reflected while others are transmitted without being absorbed.
Pleochroism (crystal dichroism)
[edit]In mineralogy, certain crystals like tourmaline, kunzite, and iolite exhibit dichroism due to their anisotropic lattice structure. These crystals absorb light differently depending on the orientation of the light's polarization vector.
Circular dichroism (CD)
[edit]Circular dichroism is the differential absorption of left-handed ($LHC$) and right-handed ($RHC$) circularly polarized light.
- Biological Significance: CD spectroscopy is widely used in biochemistry to determine the secondary structure of proteins (e.g., alpha helix and beta sheet) and the folding properties of DNA.
- Magnetic Circular Dichroism (MCD): Induced by a magnetic field, MCD is used to study the electronic structure and magnetic properties of atoms and molecules.
Mathematical representation
[edit]The interaction of light with dichroic materials can be modeled using Jones calculus.
- Absorption Coefficient: The strength is defined by the difference in absorption coefficients ($\alpha_1$ and $\alpha_2$) along the material's principal axes.
- Dichroic Ratio: Defined as $D = \alpha_1 / \alpha_2$.
Natural examples
[edit]- Beetle elytra: The exoskeletons of certain scarab beetles, such as Chrysina resplendens, reflect circularly polarized light due to their specialized chitin layers.[citation needed]
- Chloroplasts: The ordered arrangement of chlorophyll within thylakoid membranes can exhibit dichroic properties during light harvesting.[citation needed]
Technological applications
[edit]- LCD Technology: Liquid-crystal displays use dichroic liquid crystals to modulate light and create images.
- Dichroic Mirrors: Used in fluorescence microscopy and laser systems to separate excitation and emission light paths.
- Astronaut Helmets: Helmets used for extravehicular activity (EVA) are often coated with a thin layer of gold that acts as a dichroic filter, reflecting IR and UV radiation while remaining transparent to visible light.[citation needed]
In beam splitters
[edit]The original meaning of dichroic, from the Greek dikhroos, two-coloured, refers to any optical device which can split a beam of light into two beams with differing wavelengths. Such devices include mirrors and filters, usually treated with optical coatings, which are designed to reflect light over a certain range of wavelengths and transmit light which is outside that range. An example is the dichroic prism, used in some camcorders, which uses several coatings to split light into red, green and blue components for recording on separate CCD arrays, however it is now more common to have a Bayer filter to filter individual pixels on a single CCD array. This kind of dichroic device does not usually depend on the polarization of the light. The term dichromatic is also used in this sense.
With polarized light
[edit]The second meaning of dichroic refers to the property of a material, in which light in different polarization states traveling through it experiences a different absorption coefficient; this is also known as diattenuation. When the polarization states in question are right and left-handed circular polarization, it is then known as circular dichroism (CD). Most materials exhibiting CD are chiral,[2] although non-chiral materials showing CD have been recently observed.[3] Since the left- and right-handed circular polarizations represent two spin angular momentum (SAM) states, in this case for a photon, this dichroism can also be thought of as spin angular momentum dichroism and could be modelled using quantum mechanics.
In some crystals,[which?], such as tourmaline, the strength of the dichroic effect varies strongly with the wavelength of the light, making them appear to have different colours when viewed with light having differing polarizations.[dubious – discuss] This is more generally referred to as pleochroism,[4] and the technique can be used in mineralogy to identify minerals. In some materials, such as herapathite (iodoquinine sulfate) or Polaroid sheets, the effect is not strongly dependent on wavelength.
In liquid crystals
[edit]Dichroism, in the second meaning above, occurs in liquid crystals due to either the optical anisotropy of the molecular structure or the presence of impurities or the presence of dichroic dyes. The latter is also called a guest–host effect.[5]
See also
[edit]References
[edit]- ^ F. W. Sears; M. W. Zemansky; H. D. Young (1982). University Physics (6th ed.). Addison-Wesley. ISBN 0-201-07199-1.
- ^ Alison Rodger (2014). "Circular Dichroism and Linear Dichroism". Encyclopedia of Analytical Chemistry. John Wiley & Sons, Ltd. pp. 1–34. doi:10.1002/9780470027318.a5402.pub2. ISBN 978-0-470-02731-8.
- ^ X. Zambrana-Puyalto (2014). "Angular momentum-induced circular dichroism in non-chiral nanostructures". Nature Communications. 5: 4922. arXiv:1404.0440. Bibcode:2014NatCo...5.4922Z. doi:10.1038/ncomms5922. PMID 25215603. S2CID 2135734.
- ^ Walter Schumann (2009). Gemstones of the World. Sterling Publishing Company, Inc. pp. 49–. ISBN 978-1-4027-6829-3.
- ^ Stephen M. Kelly (2000). Flat Panel Displays: Advanced Organic Materials. Royal Society of Chemistry. p. 110. ISBN 0-85404-567-8.
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