Wood's glass is an optical filter glass invented in 1903 by American physicist Robert Williams Wood (1868–1955), which allows ultraviolet and infrared light to pass through, while blocking most visible light.[1]
YouTube Encyclopedic
-
1/5Views:3 612 4881 3412 056 43620 120329
-
Why is glass transparent? - Mark Miodownik
-
The Physics of Shading Glass
-
Only some humans can see this type of light
-
The Best Method to Cool Coffee - Physics
-
Paul Campbell on nuclear physics
Transcription
Take a look out your window, put on your glasses if you wear them. You might want to grab a pair of binoculars, too, or a magnifying lens. Now, what do you see? Well, whatever it is, it's not the multiple layers of glass right in front of you. But have you ever wondered how something so solid can be so invisible? To understand that, we have to understand what glass actually is, and where it comes from. It all begins in the Earth's crust, where the two most common elements are silicon and oxygen. These react together to form silicon dioxide, whose molecules arrange themselves into a regular crystalline form known as quartz. Quartz is commonly found in sand, where it often makes up most of the grains and is the main ingredient in most type of glass. Of course, you probably noticed that glass isn't made of multiple tiny bits of quartz, and for good reason. For one thing, the edges of the rigidly formed grains and smaller defects within the crystal structure reflect and disperse light that hits them. But when the quartz is heated high enough the extra energy makes the molecules vibrate until they break the bonds holding them together and become a flowing liquid, the same way that ice melts into water. Unlike water, though, liquid silicon dioxide does not reform into a crystal solid when it cools. Instead, as the molecules lose energy, they are less and less able to move into an ordered position, and the result is what is called an amorphous solid. A solid material with the chaotic structure of a liquid, which allows the molecules to freely fill in any gaps. This makes the surface of glass uniform on a microscopic level, allowing light to strike it without being scattered in different directions. But this still doesn't explain why light is able to pass through glass rather than being absorbed as with most solids. For that, we need to go all the way down to the subatomic level. You may know that an atom consists of a nucleus with electrons orbiting around it, but you may be surprised to know that it's mostly empty space. In fact, if an atom were the size of a sports stadium, the nucleus would be like a single pea in the center, while the electrons would be like grains of sand in the outer seats. That should leave plenty of space for light to pass through without hitting any of these particles. So the real question is not why is glass transparent, but why aren't all materials transparent? The answer has to do with the different energy levels that electrons in an atom can have. Think of these as different rows of seats in the stadium stands. An electron is initially assigned to sit in a certain row, but it could jump to a better row, if it only had the energy. As luck would have it, absorbing one of those light photons passing through the atom can provide just the energy the electron needs. But there's a catch. The energy from the photon has to be the right amount to get an electron to the next row. Otherwise, it will just let the photon pass by, and it just so happens that in glass, the rows are so far apart that a photon of visible light can't provide enough energy for an electron to jump between them. Photons from ultraviolet light, on the other hand, give just the right amount of energy, and are absorbed, which is why you can't get a suntan through glass. This amazing property of being both solid and transparent has given glass many uses throughout the centuries. From windows that let in light while keeping out the elements, to lenses that allow us to see both the vast worlds beyond our planet, and the tiny ones right around us. It is hard to imagine modern civilization without glass. And yet for such an important material we rarely think about glass and its impact. It is precisely because the most important and useful quality of glass is being featureless and invisible that we often forget that it's even there.
History
Wood's glass was developed as a light filter used in communications during World War I.[2][3] The glass filter worked both in infrared daylight communication and ultraviolet night communications by removing the visible components of a light beam, leaving only the "invisible radiation" as a signal beam. Wood's glass was commonly used to form the envelope for fluorescent and incandescent ultraviolet bulbs ("black lights"). In recent years, due to its disadvantages, other filter materials have largely replaced it.[4]
Composition
Wood's glass is special barium-sodium-silicate glass incorporating about 9% nickel oxide. It is a very deep violet-blue glass, opaque to all visible light rays except longest red and shortest violet. It is quite transparent in the violet/ultraviolet in a band between 320 and 400 nanometres with a peak at 365 nanometres, and a fairly broad range of infrared and the longest, least visible red wavelengths.[citation needed]
Properties and uses
Wood's glass has lower mechanical strength and higher thermal expansion than commonly used glasses, making it more vulnerable to thermal shocks and mechanical damage.[citation needed]
The nickel and barium oxides are also chemically reactive, with tendency to slowly form a layer of hydroxides and carbonates in contact with atmospheric moisture and carbon dioxide.
The susceptibility to thermal shock makes manufacture of hermetically sealed glass bulbs difficult and costly. Therefore, most contemporary "black-light" bulbs are made of structurally more suitable glass with only a layer of a UV-filtering enamel on its surface;[citation needed] such bulbs, however, pass much more visible light, appearing brighter to the eye. Due to manufacturing difficulties, Wood's glass is now more commonly used in standalone flat or dome-shaped filters, instead of being the material of the light bulb.
With prolonged exposure to ultraviolet radiation, Wood's glass undergoes solarization, gradually losing transparency for UV.[citation needed]
Photographic filters for ultraviolet photography, notably the Kodak Wratten 18A and 18B, are based on Wood's glass.[5][citation needed]
Health effects
Bulbs made of Wood's glass are potentially hazardous in comparison with those made of enameled glass, since the reduced visible light output may cause observers to be exposed to unsafe levels of UV, because the source appears dim. The low output of black lights is not considered sufficient to cause DNA damage or cellular mutations, but excessive exposure to UV can cause temporary or permanent damage to the eye.
See also
References
- ^ Williams, Robin; Gigi Williams (2002). "Wood, Professor Robert Williams". Pioneers of Invisible Radiation Photography. RMIT Online University, Melbourne, Australia. Retrieved January 16, 2013.
- ^ "Invisible Signals". Proceedings of the United States Naval Institute. Annapolis, Maryland: U.S. Naval Institute. 45 (10): 1794–1796. October 1919. Retrieved 27 March 2013.
- ^ Rodgers, John, ed. (1920). "Secret signaling by light rays". Kline Geology Laboratory. American Journal of Science. New Haven: Yale University. 49: 214–216. Retrieved 27 March 2013.
- ^ "...a BLB [black light bulb] has a thin coating of a visible wavelength (VIS) filter generally applied to the inner wall of the bulb" from "Part I: Lighting and its effects on color-grading diamonds" (PPT). AGA Task Force on Lighting and Color-Grading. Accredited Gemologists Association. 3 February 2010. Retrieved 27 March 2013. See also the 2009 report: "Part I: Lighting and its effects on color-grading diamonds" (PPT). AGA Task Force on Lighting and Color-Grading. Accredited Gemologists Association. 4 February 2009. Retrieved 20 April 2018.
- ^ "Reflected Ultraviolet Photography". Medical and Scientific Photography. RMIT University.
Further reading
- Wood, R. W. (1919). "Secret communications concerning light rays". Journal of Physiology. 5e (IX).
- Margarot, J.; Deveze, P. (1925). "Aspect de quelques dermatoses lumiere ultraparaviolette. Note preliminaire". Bulletin de la Société des sciences médicales et biologiques de Montpellier (in French). 6: 375–378.
- Williams, Robin, Prof.; Williams, Gigi. "Prof. Robert Williams Wood". Pioneers of invisible radiation photography. Archived from the original on 2011-04-07.
{{cite web}}: CS1 maint: multiple names: authors list (link)
This page was last edited on 30 June 2023, at 06:49