Transparency and translucency: Difference between revisions

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Line 1: {{Short description\|Property of an object or substance to transmit light with minimal scattering}} {{~~Other uses of~~otheruses\|Transparency (disambiguation)\|Translucence (disambiguation)}} [[File:Dichroic filters.jpg\|thumb\|right\|[[Dichroic filter]]s are created using optically transparent materials.]] In the field of [[optics]], '''transparency''' (also called '''pellucidity''' or '''diaphaneity''') is the [[physical property]] of allowing [[light]] to pass through the material without appreciable [[light scattering by particles\|scattering of light]]. On a [[macroscopic scale]] (one in which the dimensions are much larger than the wavelengths of the [[photon]]s in question), the photons can be said to follow [[Snell's law]]. '''Translucency''' (also called '''translucence''' or '''translucidity''') ~~allows~~is the physical property of allowing light to pass through ~~but~~the ~~does~~material ~~not~~(with ~~necessarily~~or ~~(again,~~without onscattering of light). It allows light to pass through but the ~~macroscopic~~light ~~scale)~~does not necessarily follow Snell's law on the macroscopic scale; the photons ~~can~~may be scattered at either of the two interfaces, or internally, where there is a change in the index of [[refraction]]. In other words, a translucent material is made up of components with different indices of refraction. A transparent material is made up of components with a uniform index of refraction.<ref>{{cite journal \|last=Thomas \|first=S. M. \|title=What determines whether a substance is transparent? \|journal=[[Scientific American]] \|date=October 21, 1999}}</ref> Transparent materials appear clear, with the overall appearance of one color, or any combination leading up to a brilliant [[spectrum]] of every color. The opposite property of translucency is [[Opacity (optics)\|opacity]]. Other categories of visual appearance, related to the perception of regular or diffuse reflection and transmission of light, have been organized under the concept of [[Cesia (visual appearance)\|cesia]] in an order system with three variables, including transparency, translucency and opacity among the involved aspects. When light encounters a material, it can interact with it in several different ways. These interactions depend on the [[wavelength]] of the light and the nature of the material. Photons interact with an object by some combination of reflection, absorption and transmission. Line 12: Transparency can provide almost perfect [[camouflage]] for animals <!--or possibly military equipment?--> able to achieve it. This is easier in dimly-lit or turbid [[sea]]water than in good illumination. Many [[marine biology\|marine animals]] such as [[jellyfish]] are highly transparent. [[File:Opacity Translucency Transparency.svg\|thumb\|250px\|right\|Comparisons of 1. opacity, 2. translucency with scattering, and 3. transparency; behind each panel (from top to bottom: grey, red, white) is a star.]] == Etymology == Line 24: * At the electronic level, absorption in the [[ultraviolet]] and visible (UV-Vis) portions of the spectrum depends on whether the [[Atomic orbital\|electron orbitals]] are spaced (or "quantized") such that electrons can absorb a [[quantum]] of light (or [[photon]]) of a specific [[frequency]]. For example, in most glasses, electrons have no available energy levels above them in the range of that associated with visible light, or if they do, the transition to them would violate [[selection rules]], meaning there is no appreciable absorption in pure (undoped) glasses, making them ideal transparent materials for windows in buildings. * At the atomic or molecular level, physical absorption in the infrared portion of the spectrum depends on the [[frequencies]] of atomic or [[molecular vibrations]] or [[chemical bonds]], and on [[selection rule]]s. Nitrogen and oxygen are not greenhouse gases because there is no [[molecular dipole moment]]. {{np}}{{pb}} With regard to the [[light scattering in liquids and solids\|scattering of light]], the most critical factor is the length scale of any or all of these structural features relative to the wavelength of the light being scattered. Primary material considerations include: * Crystalline structure: whether the atoms or molecules exhibit the 'long-range order' evidenced in crystalline solids.