fbpx
Wikipedia

Visible spectrum

March 06, 2023

"Color spectrum" redirects here. For The Dear Hunter album, see The Color Spectrum.

The visible spectrum is the portion of the electromagnetic spectrum that is visible to the human eye. Electromagnetic radiation in this range of wavelengths is called visible light or simply light. A typical human eye will respond to wavelengths from about 380 to about 750 nanometers.[1] In terms of frequency, this corresponds to a band in the vicinity of 400–790 terahertz. These boundaries are not sharply defined and may vary per individual.[2] Under optimal conditions these limits of human perception can extend to 310 nm (ultraviolet) and 1100 nm (near infrared).[3][4] The optical spectrum is sometimes considered to be the same as the visible spectrum, but some authors define the term more broadly, to include the ultraviolet and infrared parts of the electromagnetic spectrum as well.[5]

White light is dispersed by a prism into the colors of the visible spectrum.
Laser beams with visible spectrum

The spectrum does not contain all the colors that the human visual system can distinguish. Unsaturated colors such as pink, or purple variations like magenta, for example, are absent because they can only be made from a mix of multiple wavelengths. Colors containing only one wavelength are also called pure colors or spectral colors.[6]

Visible wavelengths pass largely unattenuated through the Earth's atmosphere via the "optical window" region of the electromagnetic spectrum. An example of this phenomenon is when clean air scatters blue light more than red light, and so the midday sky appears blue (apart from the area around the sun which appears white because the light is not scattered as much). The optical window is also referred to as the "visible window" because it overlaps the human visible response spectrum. The near infrared (NIR) window lies just out of the human vision, as well as the medium wavelength infrared (MWIR) window, and the long-wavelength or far-infrared (LWIR or FIR) window, although other animals may perceive them.

History

 
Newton's color circle, from Opticks of 1704, showing the colors he associated with musical notes. The spectral colors from red to violet are divided by the notes of the musical scale, starting at D. The circle completes a full octave, from D to D. Newton's circle places red, at one end of the spectrum, next to violet, at the other. This reflects the fact that non-spectral purple colors are observed when red and violet light are mixed.

In the 13th century, Roger Bacon theorized that rainbows were produced by a similar process to the passage of light through glass or crystal.[7]

In the 17th century, Isaac Newton discovered that prisms could disassemble and reassemble white light, and described the phenomenon in his book Opticks. He was the first to use the word spectrum (Latin for "appearance" or "apparition") in this sense in print in 1671 in describing his experiments in optics. Newton observed that, when a narrow beam of sunlight strikes the face of a glass prism at an angle, some is reflected and some of the beam passes into and through the glass, emerging as different-colored bands. Newton hypothesized light to be made up of "corpuscles" (particles) of different colors, with the different colors of light moving at different speeds in transparent matter, red light moving more quickly than violet in glass. The result is that red light is bent (refracted) less sharply than violet as it passes through the prism, creating a spectrum of colors.

 
Newton's observation of prismatic colors (David Brewster 1855)

Newton originally divided the spectrum into six named colors: red, orange, yellow, green, blue, and violet. He later added indigo as the seventh color since he believed that seven was a perfect number as derived from the ancient Greek sophists, of there being a connection between the colors, the musical notes, the known objects in the Solar System, and the days of the week.[8] The human eye is relatively insensitive to indigo's frequencies, and some people who have otherwise-good vision cannot distinguish indigo from blue and violet. For this reason, some later commentators, including Isaac Asimov,[9] have suggested that indigo should not be regarded as a color in its own right but merely as a shade of blue or violet. Evidence indicates that what Newton meant by "indigo" and "blue" does not correspond to the modern meanings of those color words. Comparing Newton's observation of prismatic colors to a color image of the visible light spectrum shows that "indigo" corresponds to what is today called blue, whereas his "blue" corresponds to cyan.[10][11][12]

In the 18th century, Johann Wolfgang von Goethe wrote about optical spectra in his Theory of Colours. Goethe used the word spectrum (Spektrum) to designate a ghostly optical afterimage, as did Schopenhauer in On Vision and Colors. Goethe argued that the continuous spectrum was a compound phenomenon. Where Newton narrowed the beam of light to isolate the phenomenon, Goethe observed that a wider aperture produces not a spectrum but rather reddish-yellow and blue-cyan edges with white between them. The spectrum appears only when these edges are close enough to overlap.

In the early 19th century, the concept of the visible spectrum became more definite, as light outside the visible range was discovered and characterized by William Herschel (infrared) and Johann Wilhelm Ritter (ultraviolet), Thomas Young, Thomas Johann Seebeck, and others.[13] Young was the first to measure the wavelengths of different colors of light, in 1802.[14]

The connection between the visible spectrum and color vision was explored by Thomas Young and Hermann von Helmholtz in the early 19th century. Their theory of color vision correctly proposed that the eye uses three distinct receptors to perceive color.

Color perception across species

See also: Color vision § Physiology of color perception

Many species can see light within frequencies outside the human "visible spectrum". Bees and many other insects can detect ultraviolet light, which helps them find nectar in flowers. Plant species that depend on insect pollination may owe reproductive success to their appearance in ultraviolet light rather than how colorful they appear to humans. Birds, too, can see into the ultraviolet (300–400 nm), and some have sex-dependent markings on their plumage that are visible only in the ultraviolet range.[15][16] Many animals that can see into the ultraviolet range cannot see red light or any other reddish wavelengths. Bees' visible spectrum ends at about 590 nm, just before the orange wavelengths start.[17] Birds can see some red wavelengths, although not as far into the light spectrum as humans.[18] The popular belief that the common goldfish is the only animal that can see both infrared and ultraviolet light[19] is incorrect, because goldfish cannot see infrared light.[20]

Most mammals are dichromatic, and dogs and horses are often thought to be color blind. They have been shown to be sensitive to colors, though not as many as humans.[21] Some snakes can "see"[22] radiant heat at wavelengths between 5 and 30 μm to a degree of accuracy such that a blind rattlesnake can target vulnerable body parts of the prey at which it strikes,[23] and other snakes with the organ may detect warm bodies from a meter away.[24] It may also be used in thermoregulation and predator detection.[25][26] (See Infrared sensing in snakes)

Spectral colors

Main article: Spectral color
 
Color Wavelength
(nm) 		Frequency
(THz) 		Photon energy
(eV)
  violet
 380–450 670–790 2.75–3.26
  blue
 450–485 620–670 2.56–2.75
  cyan
 485–500 600–620 2.48–2.56
  green
 500–565 530–600 2.19–2.48
  yellow
 565–590 510–530 2.10–2.19
  orange
 590–625 480–510 1.98–2.10
  red
 625–750 400–480 1.65–1.98

Colors that can be produced by visible light of a narrow band of wavelengths (monochromatic light) are called pure spectral colors. The various color ranges indicated in the illustration are an approximation: The spectrum is continuous, with no clear boundaries between one color and the next.[27]

Color display spectrum

 
Approximation of spectral colors on a display results in somewhat distorted chromaticity

Color displays (e.g. computer monitors and televisions) cannot reproduce all colors discernible by a human eye. Colors outside the color gamut of the device, such as most spectral colors, can only be approximated.

Spectroscopy

 
Earth's atmosphere partially or totally blocks some wavelengths of electromagnetic radiation, but in visible light it is mostly transparent

Spectroscopy is the study of objects based on the spectrum of color they emit, absorb or reflect. Visible-light spectroscopy is an important tool in astronomy (as is spectroscopy at other wavelengths), where scientists use it to analyze the properties of distant objects. Chemical elements and small molecules can be detected in astronomical objects by observing emission lines and absorption lines. For example, Helium was first detected by analysis of the spectrum of the sun. The shift in frequency of spectral lines is used to measure the Doppler shift (redshift or blueshift) of distant objects to determine their velocities towards or away from the observer. Astronomical spectroscopy uses high-dispersion diffraction gratings to observe spectra at very high spectral resolutions.

Properties

Heat

Although non-visible infrared light is more commonly thought of as "heat radiation",[28] any frequency of light, including visible light, will heat surfaces that absorb them. A powerful source of purely visible light, such as a visible light laser, can char paper.

Biological effects

High-energy visible light (HEV light) (violet/blue light, with a wavelength of 400-450 nm)[29] has a number of biological effects, especially on the eye. Studies by Harvard Health Publishing and France's ANSES found that exposure to blue light has a negative effect on sleep and can lead to impaired vision.[30][31]

See also

 
Wikisource has original text related to this article:
Definition of the Color Indigo
 
Wikimedia Commons has media related to Visible spectrum.

References

  1. ^ Starr, Cecie (2005). Biology: Concepts and Applications. Thomson Brooks/Cole. p. 94. ISBN 978-0-534-46226-0.
  2. ^ "The visible spectrum". Britannica.
  3. ^ D. H. Sliney (February 2016). "What is light? The visible spectrum and beyond". Eye. 30 (2): 222–229. doi:10.1038/eye.2015.252. ISSN 1476-5454. PMC 4763133. PMID 26768917.
  4. ^ W. C. Livingston (2001). Color and light in nature (2nd ed.). Cambridge, UK: Cambridge University Press. ISBN 0-521-77284-2.
  5. ^ Pedrotti, Frank L.; Pedrotti, Leno M.; Pedrotti, Leno S. (December 21, 2017). Introduction to Optics. Cambridge University Press. pp. 7–8. ISBN 9781108428262.
  6. ^ Nave, R. "Spectral Colors". Hyperphysics. Retrieved 2022-05-11.
  7. ^ Coffey, Peter (1912). The Science of Logic: An Inquiry Into the Principles of Accurate Thought. Longmans. p. 185. roger bacon prism.
  8. ^ Isacoff, Stuart (16 January 2009). Temperament: How Music Became a Battleground for the Great Minds of Western Civilization. Knopf Doubleday Publishing Group. pp. 12–13. ISBN 978-0-307-56051-3. Retrieved 18 March 2014.
  9. ^ Asimov, Isaac (1975). Eyes on the universe : a history of the telescope. Boston: Houghton Mifflin. p. 59. ISBN 978-0-395-20716-1.
  10. ^ Evans, Ralph M. (1974). The perception of color (null ed.). New York: Wiley-Interscience. ISBN 978-0-471-24785-2.
  11. ^ McLaren, K. (March 2007). "Newton's indigo". Color Research & Application. 10 (4): 225–229. doi:10.1002/col.5080100411.
  12. ^ Waldman, Gary (2002). Introduction to light : the physics of light, vision, and color (Dover ed.). Mineola: Dover Publications. p. 193. ISBN 978-0-486-42118-6.
  13. ^ Mary Jo Nye, ed. (2003). The Cambridge History of Science: The Modern Physical and Mathematical Sciences. Vol. 5. Cambridge University Press. p. 278. ISBN 978-0-521-57199-9.
  14. ^ John C. D. Brand (1995). Lines of light: the sources of dispersive spectroscopy, 1800–1930. CRC Press. pp. 30–32. ISBN 978-2-88449-163-1.
  15. ^ Cuthill, Innes C (1997). "Ultraviolet vision in birds". In Peter J.B. Slater (ed.). Advances in the Study of Behavior. Vol. 29. Oxford, England: Academic Press. p. 161. ISBN 978-0-12-004529-7.
  16. ^ Jamieson, Barrie G. M. (2007). Reproductive Biology and Phylogeny of Birds. Charlottesville VA: University of Virginia. p. 128. ISBN 978-1-57808-386-2.
  17. ^ Skorupski, Peter; Chittka, Lars (10 August 2010). "Photoreceptor Spectral Sensitivity in the Bumblebee, Bombus impatiens (Hymenoptera: Apidae)". PLOS ONE. 5 (8): e12049. Bibcode:2010PLoSO...512049S. doi:10.1371/journal.pone.0012049. PMC 2919406. PMID 20711523.
  18. ^ Varela, F. J.; Palacios, A. G.; Goldsmith T. M. (1993) "Color vision of birds", pp. 77–94 in Vision, Brain, and Behavior in Birds, eds. Zeigler, Harris Philip and Bischof, Hans-Joachim. MIT Press. ISBN 9780262240369
  19. ^ . Skeptive. 2013. Archived from the original on December 24, 2013. Retrieved September 28, 2013.
  20. ^ Neumeyer, Christa (2012). "Chapter 2: Color Vision in Goldfish and Other Vertebrates". In Lazareva, Olga; Shimizu, Toru; Wasserman, Edward (eds.). How Animals See the World: Comparative Behavior, Biology, and Evolution of Vision. Oxford Scholarship Online. ISBN 978-0-19-533465-4.
  21. ^ Kasparson, A. A; Badridze, J; Maximov, V. V (2013). "Colour cues proved to be more informative for dogs than brightness". Proceedings of the Royal Society B: Biological Sciences. 280 (1766): 20131356. doi:10.1098/rspb.2013.1356. PMC 3730601. PMID 23864600.
  22. ^ Newman, EA; Hartline, PH (1981). "Integration of visual and infrared information in bimodal neurons in the rattlesnake optic tectum". Science. 213 (4509): 789–91. Bibcode:1981Sci...213..789N. doi:10.1126/science.7256281. PMC 2693128. PMID 7256281.
  23. ^ Kardong, KV; Mackessy, SP (1991). "The strike behavior of a congenitally blind rattlesnake". Journal of Herpetology. 25 (2): 208–211. doi:10.2307/1564650. JSTOR 1564650.
  24. ^ Fang, Janet (14 March 2010). "Snake infrared detection unravelled". Nature News. doi:10.1038/news.2010.122.
  25. ^ Krochmal, Aaron R.; George S. Bakken; Travis J. LaDuc (15 November 2004). "Heat in evolution's kitchen: evolutionary perspectives on the functions and origin of the facial pit of pitvipers (Viperidae: Crotalinae)". Journal of Experimental Biology. 207 (Pt 24): 4231–4238. doi:10.1242/jeb.01278. PMID 15531644.
  26. ^ Greene HW. (1992). "The ecological and behavioral context for pitviper evolution", in Campbell JA, Brodie ED Jr. Biology of the Pitvipers. Texas: Selva. ISBN 0-9630537-0-1.
  27. ^ Bruno, Thomas J. and Svoronos, Paris D. N. (2005). CRC Handbook of Fundamental Spectroscopic Correlation Charts. CRC Press. ISBN 9781420037685
  28. ^ "Infrared Radiation". Infrared Radiation. Van Nostrand's Scientific Encyclopedia. John Wiley & Sons, Inc. 2007. doi:10.1002/0471743984.vse4181.pub2. ISBN 978-0471743989.
  29. ^ Dykas, Carol (June 2004). "How to Protect Patients from Harmful Sunlight". 2020mag.com.
  30. ^ "LEDs & blue light | Anses - Agence nationale de sécurité Sanitaire de l'alimentation, de l'environnement et du travail". anses.fr. Retrieved 2020-01-29.
  31. ^ . Harvard Health Publications. May 1, 2012. Archived from the original on February 2, 2015.

March 06, 2023
visible, spectrum, color, spectrum, redirects, here, dear, hunter, album, color, spectrum, visible, spectrum, portion, electromagnetic, spectrum, that, visible, human, electromagnetic, radiation, this, range, wavelengths, called, visible, light, simply, light,. Color spectrum redirects here For The Dear Hunter album see The Color Spectrum The visible spectrum is the portion of the electromagnetic spectrum that is visible to the human eye Electromagnetic radiation in this range of wavelengths is called visible light or simply light A typical human eye will respond to wavelengths from about 380 to about 750 nanometers 1 In terms of frequency this corresponds to a band in the vicinity of 400 790 terahertz These boundaries are not sharply defined and may vary per individual 2 Under optimal conditions these limits of human perception can extend to 310 nm ultraviolet and 1100 nm near infrared 3 4 The optical spectrum is sometimes considered to be the same as the visible spectrum but some authors define the term more broadly to include the ultraviolet and infrared parts of the electromagnetic spectrum as well 5 White light is dispersed by a prism into the colors of the visible spectrum Laser beams with visible spectrum The spectrum does not contain all the colors that the human visual system can distinguish Unsaturated colors such as pink or purple variations like magenta for example are absent because they can only be made from a mix of multiple wavelengths Colors containing only one wavelength are also called pure colors or spectral colors 6 Visible wavelengths pass largely unattenuated through the Earth s atmosphere via the optical window region of the electromagnetic spectrum An example of this phenomenon is when clean air scatters blue light more than red light and so the midday sky appears blue apart from the area around the sun which appears white because the light is not scattered as much The optical window is also referred to as the visible window because it overlaps the human visible response spectrum The near infrared NIR window lies just out of the human vision as well as the medium wavelength infrared MWIR window and the long wavelength or far infrared LWIR or FIR window although other animals may perceive them Contents 1 History 2 Color perception across species 3 Spectral colors 4 Color display spectrum 5 Spectroscopy 6 Properties 6 1 Heat 6 2 Biological effects 7 See also 8 ReferencesHistory Edit Newton s color circle from Opticks of 1704 showing the colors he associated with musical notes The spectral colors from red to violet are divided by the notes of the musical scale starting at D The circle completes a full octave from D to D Newton s circle places red at one end of the spectrum next to violet at the other This reflects the fact that non spectral purple colors are observed when red and violet light are mixed In the 13th century Roger Bacon theorized that rainbows were produced by a similar process to the passage of light through glass or crystal 7 In the 17th century Isaac Newton discovered that prisms could disassemble and reassemble white light and described the phenomenon in his book Opticks He was the first to use the word spectrum Latin for appearance or apparition in this sense in print in 1671 in describing his experiments in optics Newton observed that when a narrow beam of sunlight strikes the face of a glass prism at an angle some is reflected and some of the beam passes into and through the glass emerging as different colored bands Newton hypothesized light to be made up of corpuscles particles of different colors with the different colors of light moving at different speeds in transparent matter red light moving more quickly than violet in glass The result is that red light is bent refracted less sharply than violet as it passes through the prism creating a spectrum of colors Newton s observation of prismatic colors David Brewster 1855 Newton originally divided the spectrum into six named colors red orange yellow green blue and violet He later added indigo as the seventh color since he believed that seven was a perfect number as derived from the ancient Greek sophists of there being a connection between the colors the musical notes the known objects in the Solar System and the days of the week 8 The human eye is relatively insensitive to indigo s frequencies and some people who have otherwise good vision cannot distinguish indigo from blue and violet For this reason some later commentators including Isaac Asimov 9 have suggested that indigo should not be regarded as a color in its own right but merely as a shade of blue or violet Evidence indicates that what Newton meant by indigo and blue does not correspond to the modern meanings of those color words Comparing Newton s observation of prismatic colors to a color image of the visible light spectrum shows that indigo corresponds to what is today called blue whereas his blue corresponds to cyan 10 11 12 In the 18th century Johann Wolfgang von Goethe wrote about optical spectra in his Theory of Colours Goethe used the word spectrum Spektrum to designate a ghostly optical afterimage as did Schopenhauer in On Vision and Colors Goethe argued that the continuous spectrum was a compound phenomenon Where Newton narrowed the beam of light to isolate the phenomenon Goethe observed that a wider aperture produces not a spectrum but rather reddish yellow and blue cyan edges with white between them The spectrum appears only when these edges are close enough to overlap In the early 19th century the concept of the visible spectrum became more definite as light outside the visible range was discovered and characterized by William Herschel infrared and Johann Wilhelm Ritter ultraviolet Thomas Young Thomas Johann Seebeck and others 13 Young was the first to measure the wavelengths of different colors of light in 1802 14 The connection between the visible spectrum and color vision was explored by Thomas Young and Hermann von Helmholtz in the early 19th century Their theory of color vision correctly proposed that the eye uses three distinct receptors to perceive color Color perception across species EditSee also Color vision Physiology of color perception Many species can see light within frequencies outside the human visible spectrum Bees and many other insects can detect ultraviolet light which helps them find nectar in flowers Plant species that depend on insect pollination may owe reproductive success to their appearance in ultraviolet light rather than how colorful they appear to humans Birds too can see into the ultraviolet 300 400 nm and some have sex dependent markings on their plumage that are visible only in the ultraviolet range 15 16 Many animals that can see into the ultraviolet range cannot see red light or any other reddish wavelengths Bees visible spectrum ends at about 590 nm just before the orange wavelengths start 17 Birds can see some red wavelengths although not as far into the light spectrum as humans 18 The popular belief that the common goldfish is the only animal that can see both infrared and ultraviolet light 19 is incorrect because goldfish cannot see infrared light 20 Most mammals are dichromatic and dogs and horses are often thought to be color blind They have been shown to be sensitive to colors though not as many as humans 21 Some snakes can see 22 radiant heat at wavelengths between 5 and 30 mm to a degree of accuracy such that a blind rattlesnake can target vulnerable body parts of the prey at which it strikes 23 and other snakes with the organ may detect warm bodies from a meter away 24 It may also be used in thermoregulation and predator detection 25 26 See Infrared sensing in snakes Spectral colors EditMain article Spectral color Color Wavelength nm Frequency THz Photon energy eV violet 380 450 670 790 2 75 3 26 blue 450 485 620 670 2 56 2 75 cyan 485 500 600 620 2 48 2 56 green 500 565 530 600 2 19 2 48 yellow 565 590 510 530 2 10 2 19 orange 590 625 480 510 1 98 2 10 red 625 750 400 480 1 65 1 98Colors that can be produced by visible light of a narrow band of wavelengths monochromatic light are called pure spectral colors The various color ranges indicated in the illustration are an approximation The spectrum is continuous with no clear boundaries between one color and the next 27 Color display spectrum Edit Approximation of spectral colors on a display results in somewhat distorted chromaticity Color displays e g computer monitors and televisions cannot reproduce all colors discernible by a human eye Colors outside the color gamut of the device such as most spectral colors can only be approximated Spectroscopy Edit Earth s atmosphere partially or totally blocks some wavelengths of electromagnetic radiation but in visible light it is mostly transparent Spectroscopy is the study of objects based on the spectrum of color they emit absorb or reflect Visible light spectroscopy is an important tool in astronomy as is spectroscopy at other wavelengths where scientists use it to analyze the properties of distant objects Chemical elements and small molecules can be detected in astronomical objects by observing emission lines and absorption lines For example Helium was first detected by analysis of the spectrum of the sun The shift in frequency of spectral lines is used to measure the Doppler shift redshift or blueshift of distant objects to determine their velocities towards or away from the observer Astronomical spectroscopy uses high dispersion diffraction gratings to observe spectra at very high spectral resolutions Properties EditHeat Edit Although non visible infrared light is more commonly thought of as heat radiation 28 any frequency of light including visible light will heat surfaces that absorb them A powerful source of purely visible light such as a visible light laser can char paper Biological effects Edit High energy visible light HEV light violet blue light with a wavelength of 400 450 nm 29 has a number of biological effects especially on the eye Studies by Harvard Health Publishing and France s ANSES found that exposure to blue light has a negative effect on sleep and can lead to impaired vision 30 31 See also Edit Wikisource has original text related to this article Definition of the Color Indigo Wikimedia Commons has media related to Visible spectrum High energy visible light Electromagnetic absorption by waterReferences Edit Starr Cecie 2005 Biology Concepts and Applications Thomson Brooks Cole p 94 ISBN 978 0 534 46226 0 The visible spectrum Britannica D H Sliney February 2016 What is light The visible spectrum and beyond Eye 30 2 222 229 doi 10 1038 eye 2015 252 ISSN 1476 5454 PMC 4763133 PMID 26768917 W C Livingston 2001 Color and light in nature 2nd ed Cambridge UK Cambridge University Press ISBN 0 521 77284 2 Pedrotti Frank L Pedrotti Leno M Pedrotti Leno S December 21 2017 Introduction to Optics Cambridge University Press pp 7 8 ISBN 9781108428262 Nave R Spectral Colors Hyperphysics Retrieved 2022 05 11 Coffey Peter 1912 The Science of Logic An Inquiry Into the Principles of Accurate Thought Longmans p 185 roger bacon prism Isacoff Stuart 16 January 2009 Temperament How Music Became a Battleground for the Great Minds of Western Civilization Knopf Doubleday Publishing Group pp 12 13 ISBN 978 0 307 56051 3 Retrieved 18 March 2014 Asimov Isaac 1975 Eyes on the universe a history of the telescope Boston Houghton Mifflin p 59 ISBN 978 0 395 20716 1 Evans Ralph M 1974 The perception of color null ed New York Wiley Interscience ISBN 978 0 471 24785 2 McLaren K March 2007 Newton s indigo Color Research amp Application 10 4 225 229 doi 10 1002 col 5080100411 Waldman Gary 2002 Introduction to light the physics of light vision and color Dover ed Mineola Dover Publications p 193 ISBN 978 0 486 42118 6 Mary Jo Nye ed 2003 The Cambridge History of Science The Modern Physical and Mathematical Sciences Vol 5 Cambridge University Press p 278 ISBN 978 0 521 57199 9 John C D Brand 1995 Lines of light the sources of dispersive spectroscopy 1800 1930 CRC Press pp 30 32 ISBN 978 2 88449 163 1 Cuthill Innes C 1997 Ultraviolet vision in birds In Peter J B Slater ed Advances in the Study of Behavior Vol 29 Oxford England Academic Press p 161 ISBN 978 0 12 004529 7 Jamieson Barrie G M 2007 Reproductive Biology and Phylogeny of Birds Charlottesville VA University of Virginia p 128 ISBN 978 1 57808 386 2 Skorupski Peter Chittka Lars 10 August 2010 Photoreceptor Spectral Sensitivity in the Bumblebee Bombus impatiens Hymenoptera Apidae PLOS ONE 5 8 e12049 Bibcode 2010PLoSO 512049S doi 10 1371 journal pone 0012049 PMC 2919406 PMID 20711523 Varela F J Palacios A G Goldsmith T M 1993 Color vision of birds pp 77 94 in Vision Brain and Behavior in Birds eds Zeigler Harris Philip and Bischof Hans Joachim MIT Press ISBN 9780262240369 True or False The common goldfish is the only animal that can see both infra red and ultra violet light Skeptive 2013 Archived from the original on December 24 2013 Retrieved September 28 2013 Neumeyer Christa 2012 Chapter 2 Color Vision in Goldfish and Other Vertebrates In Lazareva Olga Shimizu Toru Wasserman Edward eds How Animals See the World Comparative Behavior Biology and Evolution of Vision Oxford Scholarship Online ISBN 978 0 19 533465 4 Kasparson A A Badridze J Maximov V V 2013 Colour cues proved to be more informative for dogs than brightness Proceedings of the Royal Society B Biological Sciences 280 1766 20131356 doi 10 1098 rspb 2013 1356 PMC 3730601 PMID 23864600 Newman EA Hartline PH 1981 Integration of visual and infrared information in bimodal neurons in the rattlesnake optic tectum Science 213 4509 789 91 Bibcode 1981Sci 213 789N doi 10 1126 science 7256281 PMC 2693128 PMID 7256281 Kardong KV Mackessy SP 1991 The strike behavior of a congenitally blind rattlesnake Journal of Herpetology 25 2 208 211 doi 10 2307 1564650 JSTOR 1564650 Fang Janet 14 March 2010 Snake infrared detection unravelled Nature News doi 10 1038 news 2010 122 Krochmal Aaron R George S Bakken Travis J LaDuc 15 November 2004 Heat in evolution s kitchen evolutionary perspectives on the functions and origin of the facial pit of pitvipers Viperidae Crotalinae Journal of Experimental Biology 207 Pt 24 4231 4238 doi 10 1242 jeb 01278 PMID 15531644 Greene HW 1992 The ecological and behavioral context for pitviper evolution in Campbell JA Brodie ED Jr Biology of the Pitvipers Texas Selva ISBN 0 9630537 0 1 Bruno Thomas J and Svoronos Paris D N 2005 CRC Handbook of Fundamental Spectroscopic Correlation Charts CRC Press ISBN 9781420037685 Infrared Radiation Infrared Radiation Van Nostrand s Scientific Encyclopedia John Wiley amp Sons Inc 2007 doi 10 1002 0471743984 vse4181 pub2 ISBN 978 0471743989 Dykas Carol June 2004 How to Protect Patients from Harmful Sunlight 2020mag com LEDs amp blue light Anses Agence nationale de securite Sanitaire de l alimentation de l environnement et du travail anses fr Retrieved 2020 01 29 Blue light has a dark side Harvard Health Publications May 1 2012 Archived from the original on February 2 2015 Retrieved from https en wikipedia org w index php title Visible spectrum amp oldid 1135074532, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.