Physics:Invisibility

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Short description: State of an object that cannot be seen
By using two parabolic cylindric mirrors and one plane mirror, the image of the background is directed around an object, making the object itself invisible - at least from two sides.

Invisibility is the state of an object that cannot be seen. An object in this state is said to be invisible (literally, "not visible"). The phenomenon is studied by physics and perceptual psychology.

Since objects can be seen by light in the visible spectrum from a source reflecting off their surfaces and hitting the viewer's eye, the most natural form of invisibility (whether real or fictional) is an object that neither reflects nor absorbs light (that is, it allows light to pass through it). This is known as transparency, and is seen in many naturally occurring materials (although no naturally occurring material is 100% transparent).

Invisibility perception depends on several optical and visual factors.[1] For example, invisibility depends on the eyes of the observer and/or the instruments used. Thus an object can be classified as "invisible to" a person, animal, instrument, etc. In research on sensorial perception it has been shown that invisibility is perceived in cycles.[2]

Invisibility is often considered to be the supreme form of camouflage, as it does not reveal to the viewer any kind of vital signs, visual effects, or any frequencies of the electromagnetic spectrum detectable to the human eye, instead making use of radio, infrared or ultraviolet wavelengths.

In illusion optics, invisibility is a special case of illusion effects: the illusion of free space.

The term is often used in fantasy and science fiction, where objects cannot be seen by means of magic or hypothetical technology.

Practical efforts

Technology can be used theoretically or practically to render real-world objects invisible.

Making use of a real-time image displayed on a wearable display, it is possible to create a see-through effect. This is known as active camouflage. Though stealth technology is declared to be invisible to radar, all officially disclosed applications of the technology can only reduce the size and/or clarity of the signature detected by radar.

In 2003 the Chilean scientist Gunther Uhlmann postulates the first mathematical equations to create invisible materials.[3][better source needed] In 2006, a team effort of researchers from Britain and the US announced the development of a real cloak of invisibility, an artificially made meta material that is invisible to the microwave spectrum, though it is only in its first stages.[4]

In filmmaking, people, objects, or backgrounds can be made to look invisible on camera through a process known as chroma keying.

Engineers and scientists have performed various kinds of research to investigate the possibility of finding ways to create real optical invisibility (cloaks) for objects. Methods are typically based on implementing the theoretical techniques of transformation optics, which have given rise to several theories of cloaking.

Currently, a practical cloaking device does not exist.[5][6] A 2006 theoretical work predicts that the imperfections are minor, and metamaterials may make real-life "cloaking devices" practical.[7][8] The technique is predicted to be applied to radio waves within five years, and the distortion of visible light is an eventual possibility. The theory that light waves can be acted upon the same way as radio waves is now a popular idea among scientists. The agent can be compared to a stone in a river, around which water passes, but slightly down-stream leaves no trace of the stone. Comparing light waves to the water, and whatever object that is being "cloaked" to the stone, the goal is to have light waves pass around that object, leaving no visible aspects of it, possibly not even a shadow.[9] This is the technique depicted in the 2000 television portrayal of The Invisible Man.

Two teams of scientists worked separately to create two "Invisibility Cloaks" from 'metamaterials' engineered at the nanoscale level. They demonstrated for the first time the possibility of cloaking three-dimensional (3-D) objects with artificially engineered materials that redirect radar, light or other waves around an object. While one uses a type of fishnet of metal layers to reverse the direction of light, the other uses tiny silver wires. Xiang Zhang, of the University of California, Berkeley said: "In the case of invisibility cloaks or shields, the material would need to curve light waves completely around the object like a river flowing around a rock. An observer looking at the cloaked object would then see light from behind it, making it seem to disappear."

UC Berkeley researcher Jason Valentine's team made a material that affects light near the visible spectrum, in a region used in fibre optics: 'Instead of the fish appearing to be slightly ahead of where it is in the water, it would actually appear to be above the water's surface. It's kind of weird. For a metamaterial to produce negative refraction, it must have a structural array smaller than the wavelength of the electromagnetic radiation being used." Valentine's team created their 'fishnet' material by stacking silver and metal dielectric layers on top of each other and then punching holes through them. The other team used an oxide template and grew silver nanowires inside porous aluminum oxide at tiny distances apart, smaller than the wavelength of visible light. This material refracts visible light.

The Imperial College London research team achieved results with microwaves. An invisibility cloak layout of a copper cylinder was produced in May, 2008, by physicist Professor Sir John Pendry. Scientists working with him at Duke University in the US put the idea into practice.[10][11]

Pendry, who theorized the invisibility cloak "as a joke" to illustrate the potential of metamaterials, said in an interview in August 2011 that grand, theatrical manifestations of his idea are probably overblown: "I think it’s pretty sure that any cloak that Harry Potter would recognize is not on the table. You could dream up some theory, but the very practicality of making it would be so impossible. But can you hide things from light? Yes. Can you hide things which are a few centimeters across? Yes. Is the cloak really flexible and flappy? No. Will it ever be? No. So you can do quite a lot of things, but there are limitations. There are going to be some disappointed kids around, but there might be a few people in industry who are very grateful for it."[12]

In Turkey in 2009, Bilkent University Search Center Of Nanotechnology researches explained and published in New Journal of Physics that they achieved to make invisibility real in practice using nanotechnology making an object invisible with no shadows etc. next to perfect transparent scene by producing nanotechnologic material that can also be produced like a suit anyone can wear.

In 2019, Hyperstealth Biotechnology has patented the technology behind a material that bends light to make people and objects near invisible to the naked eye. The material, called Quantum Stealth, is currently still in the prototyping stage, but was developed by the company's CEO Guy Cramer primarily for military purposes, to conceal agents and equipment such as tanks and jets in the field. Unlike traditional camouflage materials, which are limited to specific conditions such as forests or deserts, according to Cramer this "invisibility cloak" works in any environment or season, at any time of day. This is despite its actual application requiring artificial backgrounds made up of horizontal lines.[13]

Psychological

Main page: Social:Social invisibility

A person can be described as invisible if others refuse to see them or routinely overlook them. The term was used in this manner in the title of the book Invisible Man, by Ralph Ellison, in reference to the protagonist, likely modeled after the author, being overlooked on account of his status as an African American. This is supported by the quote taken from the Prologue, "I am invisible, understand, simply because people refuse to see me." (Prologue.1)[14]

Fictional use

Alberich puts on the Tarnhelm and vanishes; illustration by Arthur Rackham to Richard Wagner's Das Rheingold

In fiction, people or objects can be rendered completely invisible by several means:

  • Magical objects such as rings, cloaks and amulets can be worn to grant the wearer permanent invisibility (or temporary invisibility until the object is taken off).
  • Magical potions can be consumed to grant temporary or permanent invisibility.
  • Magic spells can be cast on people or objects, usually giving temporary invisibility.
  • Some mythical creatures can make themselves invisible at will, such as in some tales in which leprechauns or Chinese dragons can shrink so much that humans cannot see them.
  • In science fiction, the idea of a "cloaking device".

In some works, the power of magic creates an effective means of invisibility by distracting anyone who might notice the character. But since the character is not truly invisible, the effect could be betrayed by mirrors or other reflective surfaces.

Where magical invisibility is concerned, the issue may arise of whether the clothing worn by and any items carried by the invisible being are also rendered invisible. In general they are also regarded as being invisible, but in some instances clothing remains visible and must be removed for the full invisibility effect.

See also

References

  1. Moreno, Ivan; Jauregui-Sánchez, Y.; Avendaño-Alejo, Maximino (2014). "Invisibility assessment: a visual perception approach". Journal of the Optical Society of America A 31 (10): 2244–2248. doi:10.1364/josaa.31.002244. PMID 25401251. Bibcode2014JOSAA..31.2244M. http://fisica.uaz.edu.mx/~imoreno/Publicaciones/JOSA2014.pdf. Retrieved 2016-01-24. 
  2. Craig, Eugene A.; Lichtenstein, M. (1953). "Visibility-Invisibility Cycles as a Function of Stimulus-Orientation". The American Journal of Psychology 66 (4): 554–563. doi:10.2307/1418951. PMID 13124563. 
  3. Alonso, N. (March 21, 2013). "Un genio invisible" (in es). http://www.quepasa.cl/articulo/ciencia/2013/03/3-11386-9-un-genio-invisible.shtml/. 
  4. "Cloak of invisibility: Fact or fiction?". http://www.nbcnews.com/id/15329396. 
  5. Nachman, Adrian I. (November 1988). "Reconstructions From Boundary Measurements". Annals of Mathematics 128 (3): 531–576. doi:10.2307/1971435. 
  6. Wolf, Emil; Tarek Habashy (May 1993). "Invisible Bodies and Uniqueness of the Inverse Scattering Problem". Journal of Modern Optics 40 (5): 785–792. doi:10.1080/09500349314550821. Bibcode1993JMOp...40..785W. 
  7. Pendry, J. B.; D. Schurig; D. R. Smith (June 2006). "Controlling Electromagnetic Fields". Science 312 (5781): 1780–1782. doi:10.1126/science.1125907. PMID 16728597. Bibcode2006Sci...312.1780P. 
  8. Leonhardt, Ulf (June 2006). "Optical Conformal Mapping". Science 312 (5781): 1777–1780. doi:10.1126/science.1126493. PMID 16728596. Bibcode2006Sci...312.1777L. 
  9. Cho, Adrian (2006-05-26). "High-Tech Materials Could Render Objects Invisible". Science: p. 1120. http://www.sciencemag.org/cgi/content/summary/312/5777/1120a. 
  10. "Scientists Turn Fiction Into Reality, Closer to Make Objects "Invisible"". http://www.themoneytimes.com/articles/20080811/scientists_turn_fiction_into_reality_closer_to_make_objects_invisible-id-1032139.html. 
  11. "Secrets of invisibility discovered". 10 August 2008. https://www.mirror.co.uk/news/top-stories/2008/08/11/secrets-of-invisibility-discovered-115875-20692852/. 
  12. John Pendry (18 October 2011). video: The birth and promise of metamaterials. doi:10.1117/2.3201110.02. http://spie.org/x57588.xml. 
  13. "Hyperstealth Biotechnology's "invisibility cloak" can conceal people and buildings" (in en). 2019-11-07. https://www.dezeen.com/2019/11/07/hyperstealth-biotechnology-quantum-stealth-invisibility-cloak/. 
  14. Ellison, Ralph (1947). Invisible man. New York: Modern Library/Random House. ISBN 9780679601395. 

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