Blue Explained

Blue
Wavelength:approx. 450–495
Wavelength:45–49.5 Ångström
Frequency:~670–610
Hex:0000FF
Spelling:colour
Source:HTML/CSS[1]
Cmyk:(100, 100, 0, 0)

Blue is one of the three primary colours in the RYB colour model (traditional colour theory), as well as in the RGB (additive) colour model.[2] It lies between violet and cyan on the spectrum of visible light. The term blue generally describes colours perceived by humans observing light with a dominant wavelength that's between approximately 450 and 495 nanometres. Most blues contain a slight mixture of other colours; azure contains some green, while ultramarine contains some violet. The clear daytime sky and the deep sea appear blue because of an optical effect known as Rayleigh scattering. An optical effect called the Tyndall effect explains blue eyes. Distant objects appear more blue because of another optical effect called aerial perspective.

Blue has been an important colour in art and decoration since ancient times. The semi-precious stone lapis lazuli was used in ancient Egypt for jewellery and ornament and later, in the Renaissance, to make the pigment ultramarine, the most expensive of all pigments.[3] In the eighth century Chinese artists used cobalt blue to colour fine blue and white porcelain. In the Middle Ages, European artists used it in the windows of cathedrals. Europeans wore clothing coloured with the vegetable dye woad until it was replaced by the finer indigo from America. In the 19th century, synthetic blue dyes and pigments gradually replaced organic dyes and mineral pigments. Dark blue became a common colour for military uniforms and later, in the late 20th century, for business suits. Because blue has commonly been associated with harmony, it was chosen as the colour of the flags of the United Nations and the European Union.[4]

In the United States and Europe, blue is the colour that both men and women are most likely to choose as their favourite, with at least one recent survey showing the same across several other countries, including China, Malaysia, and Indonesia.[5] Past surveys in the US and Europe have found that blue is the colour most commonly associated with harmony, confidence, masculinity, knowledge, intelligence, calmness, distance, infinity, the imagination, cold, and sadness.

Etymology and linguistics

The modern English word blue comes from Middle English or, from the Old French, a word of Germanic origin, related to the Old High German word (meaning 'shimmering, lustrous').[6] In heraldry, the word azure is used for blue.[7]

In Russian, Spanish,[8] Mongolian, Irish, and some other languages, there is no single word for blue, but rather different words for light blue (;) and dark blue (;) (see Colour term).

Several languages, including Japanese and Lakota Sioux, use the same word to describe blue and green. For example, in Vietnamese, the colour of both tree leaves and the sky is . In Japanese, the word for blue is often used for colours that English speakers would refer to as green, such as the colour of a traffic signal meaning "go". In Lakota, the word is used for both blue and green, the two colours not being distinguished in older Lakota (for more on this subject, see Blue–green distinction in language).

Linguistic research indicates that languages do not begin by having a word for the colour blue.[9] Colour names often developed individually in natural languages, typically beginning with black and white (or dark and light), and then adding red, and only much later – usually as the last main category of colour accepted in a language – adding the colour blue, probably when blue pigments could be manufactured reliably in the culture using that language.

Optics and colour theory

The term blue generally describes colours perceived by humans observing light with a dominant wavelength between approximately 450 and 495 nanometres.[10] Blues with a higher frequency and thus a shorter wavelength gradually look more violet, while those with a lower frequency and a longer wavelength gradually appear more green. Purer blues are in the middle of this range, e.g., around 470 nanometres.

Isaac Newton included blue as one of the seven colours in his first description of the visible spectrum.[11] He chose seven colours because that was the number of notes in the musical scale, which he believed was related to the optical spectrum. He included indigo, the hue between blue and violet, as one of the separate colours, though today it is usually considered a hue of blue.[12]

In painting and traditional colour theory, blue is one of the three primary colours of pigments (red, yellow, blue), which can be mixed to form a wide gamut of colours. Red and blue mixed together form violet, blue and yellow together form green. Mixing all three primary colours together produces a dark brown. From the Renaissance onward, painters used this system to create their colours (see RYB colour model).

The RYB model was used for colour printing by Jacob Christoph Le Blon as early as 1725. Later, printers discovered that more accurate colours could be created by using combinations of cyan, magenta, yellow, and black ink, put onto separate inked plates and then overlaid one at a time onto paper. This method could produce almost all the colours in the spectrum with reasonable accuracy.

On the HSV colour wheel, the complement of blue is yellow; that is, a colour corresponding to an equal mixture of red and green light. On a colour wheel based on traditional colour theory (RYB) where blue was considered a primary colour, its complementary colour is considered to be orange (based on the Munsell colour wheel).[13]

LED

In 1993, high-brightness blue LEDs were demonstrated by Shuji Nakamura of Nichia Corporation.[14] [15] [16] In parallel, Isamu Akasaki and Hiroshi Amano of Nagoya University were working on a new development which revolutionized LED lighting.[17] [18]

Nakamura was awarded the 2006 Millennium Technology Prize for his invention.[19] Nakamura, Hiroshi Amano and Isamu Akasaki were awarded the Nobel Prize in Physics in 2014 for the invention of an efficient blue LED.[20]

Lasers

See main article: Blue laser.

Lasers emitting in the blue region of the spectrum became widely available to the public in 2010 with the release of inexpensive high-powered 445–447 nm laser diode technology.[21] Previously the blue wavelengths were accessible only through DPSS which are comparatively expensive and inefficient, but still widely used by scientists for applications including optogenetics, Raman spectroscopy, and particle image velocimetry, due to their superior beam quality.[22] Blue gas lasers are also still commonly used for holography, DNA sequencing, optical pumping, among other scientific and medical applications.

Shades and variations

See main article: Shades of blue. Blue is the colour of light between violet and cyan on the visible spectrum. Hues of blue include indigo and ultramarine, closer to violet; pure blue, without any mixture of other colours; Azure, which is a lighter shade of blue, similar to the colour of the sky; Cyan, which is midway in the spectrum between blue and green, and the other blue-greens such as turquoise, teal, and aquamarine.

Blue also varies in shade or tint; darker shades of blue contain black or grey, while lighter tints contain white. Darker shades of blue include ultramarine, cobalt blue, navy blue, and Prussian blue; while lighter tints include sky blue, azure, and Egyptian blue (for a more complete list see the List of colours).

As a structural colour

In nature, many blue phenomena arise from structural colouration, the result of interference between reflections from two or more surfaces of thin films, combined with refraction as light enters and exits such films. The geometry then determines that at certain angles, the light reflected from both surfaces interferes constructively, while at other angles, the light interferes destructively. Diverse colours therefore appear despite the absence of colourants.[23]

Colourants

See main article: Colourants.

Artificial blues

Egyptian blue, the first artificial pigment, was produced in the third millennium BC in Ancient Egypt. It is produced by heating pulverized sand, copper, and natron. It was used in tomb paintings and funereal objects to protect the dead in their afterlife. Prior to the 1700s, blue colourants for artwork were mainly based on lapis lazuli and the related mineral ultramarine. A breakthrough occurred in 1709 when German druggist and pigment maker Johann Jacob Diesbach discovered Prussian blue. The new blue arose from experiments involving heating dried blood with iron sulphides and was initially called Berliner Blau. By 1710 it was being used by the French painter Antoine Watteau, and later his successor Nicolas Lancret. It became immensely popular for the manufacture of wallpaper, and in the 19th century was widely used by French impressionist painters.[24] Beginning in the 1820s, Prussian blue was imported into Japan through the port of Nagasaki. It was called bero-ai, or Berlin blue, and it became popular because it did not fade like traditional Japanese blue pigment, ai-gami, made from the dayflower. Prussian blue was used by both Hokusai, in his wave paintings, and Hiroshige.[25]

In 1799 a French chemist, Louis Jacques Thénard, made a synthetic cobalt blue pigment which became immensely popular with painters.

In 1824 the Societé pour l'Encouragement d'Industrie in France offered a prize for the invention of an artificial ultramarine which could rival the natural colour made from lapis lazuli. The prize was won in 1826 by a chemist named Jean Baptiste Guimet, but he refused to reveal the formula of his colour. In 1828, another scientist, Christian Gmelin then a professor of chemistry in Tübingen, found the process and published his formula. This was the beginning of new industry to manufacture artificial ultramarine, which eventually almost completely replaced the natural product.[26]

In 1878 German chemists synthesized indigo. This product rapidly replaced natural indigo, wiping out vast farms growing indigo. It is now the blue of blue jeans. As the pace of organic chemistry accelerated, a succession of synthetic blue dyes were discovered including Indanthrone blue, which had even greater resistance to fading during washing or in the sun, and copper phthalocyanine.

Dyes for textiles and food

Blue dyes are organic compounds, both synthetic and natural.[27] Woad and true indigo were once used but since the early 1900s, all indigo is synthetic. Produced on an industrial scale, indigo is the blue of blue jeans.

For food, the triarylmethane dye Brilliant blue FCF is used for candies. The search continues for stable, natural blue dyes suitable for the food industry.[27]

Pigments for painting and glass

See also: Blue pigments. Blue pigments were once produced from minerals, especially lapis lazuli and its close relative ultramarine. These minerals were crushed, ground into powder, and then mixed with a quick-drying binding agent, such as egg yolk (tempera painting); or with a slow-drying oil, such as linseed oil, for oil painting. Two inorganic but synthetic blue pigments are cerulean blue (primarily cobalt(II) stanate:) and Prussian blue (milori blue: primarily). The chromophore in blue glass and glazes is cobalt(II). Diverse cobalt(II) salts such as cobalt carbonate or cobalt(II) aluminate are mixed with the silica prior to firing. The cobalt occupies sites otherwise filled with silicon.

Inks

Methyl blue is the dominant blue pigment in inks used in pens.[28] Blueprinting involves the production of Prussian blue in situ.

Inorganic compounds

Certain metal ions characteristically form blue solutions or blue salts. Of some practical importance, cobalt is used to make the deep blue glazes and glasses. It substitutes for silicon or aluminum ions in these materials. Cobalt is the blue chromophore in stained glass windows, such as those in Gothic cathedrals and in Chinese porcelain beginning in the Tang dynasty. Copper(II) (Cu2+) also produces many blue compounds, including the commercial algicide copper(II) sulfate (CuSO4.5H2O). Similarly, vanadyl salts and solutions are often blue, e.g. vanadyl sulfate.

In nature

Sky and sea

When sunlight passes through the atmosphere, the blue wavelengths are scattered more widely by the oxygen and nitrogen molecules, and more blue comes to our eyes. This effect is called Rayleigh scattering, after Lord Rayleigh and confirmed by Albert Einstein in 1911.[29] [30]

The sea is seen as blue for largely the same reason: the water absorbs the longer wavelengths of red and reflects and scatters the blue, which comes to the eye of the viewer. The deeper the observer goes, the darker the blue becomes. In the open sea, only about 1% of light penetrates to a depth of 200 metres (see underwater and euphotic depth).

The colour of the sea is also affected by the colour of the sky, reflected by particles in the water; and by algae and plant life in the water, which can make it look green; or by sediment, which can make it look brown.[31]

The farther away an object is, the more blue it often appears to the eye. For example, mountains in the distance often appear blue. This is the effect of atmospheric perspective; the farther an object is away from the viewer, the less contrast there is between the object and its background colour, which is usually blue. In a painting where different parts of the composition are blue, green and red, the blue will appear to be more distant, and the red closer to the viewer. The cooler a colour is, the more distant it seems. Blue light is scattered more than other wavelengths by the gases in the atmosphere, hence our "blue planet".

Minerals

Some of the most desirable gems are blue, including sapphire and tanzanite. Compounds of copper(II) are characteristically blue and so are many copper-containing minerals.Azurite (with a deep blue colour, was once employed in medieval years, but it is unstable pigment, losing its colour especially under dry conditions. Lapis lazuli, mined in Afghanistan for more than three thousand years, was used for jewelry and ornaments, and later was crushed and powdered and used as a pigment. The more it was ground, the lighter the blue colour became. Natural ultramarine, made by grinding lapis lazuli into a fine powder, was the finest available blue pigment in the Middle Ages and the Renaissance. It was extremely expensive, and in Italian Renaissance art, it was often reserved for the robes of the Virgin Mary.

Plants and fungi

Intense efforts have focused on blue flowers and the possibility that natural blue colourants could be used as food dyes.[27] Commonly, blue colours in plants are anthocyanins: "the largest group of water-soluble pigments found widespread in the plant kingdom".[32] In the few plants that exploit structural colouration, brilliant colours are produced by structures within cells. The most brilliant blue colouration known in any living tissue is found in the marble berries of Pollia condensata, where a spiral structure of cellulose fibrils scattering blue light. The fruit of quandong (Santalum acuminatum) can appear blue owing to the same effect.[27]

Animals

Blue-pigmented animals are relatively rare.[33] Examples of which include butterflies of the genus Nessaea, where blue is created by pterobilin.[34] Other blue pigments of animal origin include phorcabilin, used by other butterflies in Graphium and Papilio (specifically P. phorcas and P. weiskei), and sarpedobilin, which is used by Graphium sarpedon.[35] Blue-pigmented organelles, known as "cyanosomes", exist in the chromatophores of at least two fish species, the mandarin fish and the picturesque dragonet.[36] More commonly, blueness in animals is a structural colouration; an optical interference effect induced by organized nanometre-sized scales or fibres. Examples include the plumage of several birds like the blue jay and indigo bunting,[37] the scales of butterflies like the morpho butterfly,[38] collagen fibres in the skin of some species of monkey and opossum,[39] and the iridophore cells in some fish and frogs.[40] [41]

Eyes

Blue eyes do not actually contain any blue pigment. Eye colour is determined by two factors: the pigmentation of the eye's iris[42] [43] and the scattering of light by the turbid medium in the stroma of the iris.[44] In humans, the pigmentation of the iris varies from light brown to black. The appearance of blue, green, and hazel eyes results from the Tyndall scattering of light in the stroma, an optical effect similar to what accounts for the blueness of the sky.[45] The irises of the eyes of people with blue eyes contain less dark melanin than those of people with brown eyes, which means that they absorb less short-wavelength blue light, which is instead reflected out to the viewer. Eye colour also varies depending on the lighting conditions, especially for lighter-coloured eyes.

Blue eyes are most common in Ireland, the Baltic Sea area and Northern Europe, and are also found in Eastern, Central, and Southern Europe. Blue eyes are also found in parts of Western Asia, most notably in Afghanistan, Syria, Iraq, and Iran.[46] In Estonia, 99% of people have blue eyes.[47] [48] In Denmark in 1978, only 8% of the population had brown eyes, though through immigration, today that number is about 11%. In Germany, about 75% have blue eyes.

In the United States, as of 2006, 1 out of every 6 people, or 16.6% of the total population, and 22.3% of the white population, have blue eyes, compared with about half of Americans born in 1900, and a third of Americans born in 1950. Blue eyes are becoming less common among American children. In the US, males are 3–5% more likely to have blue eyes than females.[49]

History

See also: Blue in culture.

In the ancient world

As early as the 7th millennium BC, lapis lazuli was mined in the Sar-i Sang mines,[50] in Shortugai, and in other mines in Badakhshan province in northeast Afghanistan.[51]

Lapis lazuli artifacts, dated to 7570 BC, have been found at Bhirrana, which is the oldest site of Indus Valley civilisation.[52] Lapis was highly valued by the Indus Valley Civilisation (7570–1900 BC).[53] [54] Lapis beads have been found at Neolithic burials in Mehrgarh, the Caucasus, and as far away as Mauritania. It was used in the funeral mask of Tutankhamun (1341–1323 BC).[55]

A term for Blue was relatively rare in many forms of ancient art and decoration, and even in ancient literature. The Ancient Greek poets described the sea as green, brown or "the colour of wine". The colour is mentioned several times in the Hebrew Bible as 'tekhelet'. Reds, blacks, browns, and ochres are found in cave paintings from the Upper Paleolithic period, but not blue. Blue was also not used for dyeing fabric until long after red, ochre, pink, and purple. This is probably due to the perennial difficulty of making blue dyes and pigments. On the other hand, the rarity of blue pigment made it even more valuable.[56]

The earliest known blue dyes were made from plants – woad in Europe, indigo in Asia and Africa, while blue pigments were made from minerals, usually either lapis lazuli or azurite, and required more.[57] Blue glazes posed still another challenge since the early blue dyes and pigments were not thermally robust. In, the blue glaze Egyptian blue was introduced for ceramics, as well as many other objects.[58] [59] The Greeks imported indigo dye from India, calling it indikon, and they painted with Egyptian blue. Blue was not one of the four primary colours for Greek painting described by Pliny the Elder (red, yellow, black, and white). For the Romans, blue was the colour of mourning, as well as the colour of barbarians. The Celts and Germans reportedly dyed their faces blue to frighten their enemies, and tinted their hair blue when they grew old.[60] The Romans made extensive use of indigo and Egyptian blue pigment, as evidenced, in part, by frescos in Pompeii.The Romans had many words for varieties of blue, including Latin: caeruleus, Latin: caesius, Latin: glaucus, Latin: cyaneus, Latin: lividus, Latin: venetus, Latin: aerius, and Latin: ferreus, but two words, both of foreign origin, became the most enduring; Latin: blavus, from the Germanic word blau, which eventually became bleu or blue; and Latin: azureus, from the Arabic word, which became azure.

Blue was widely used in the decoration of churches in the Byzantine Empire.[61] By contrast, in the Islamic world, blue was of secondary to green, believed to be the favourite colour of the Prophet Mohammed. At certain times in Moorish Spain and other parts of the Islamic world, blue was the colour worn by Christians and Jews, because only Muslims were allowed to wear white and green.

In the Middle Ages

In the art and life of Europe during the early Middle Ages, blue played a minor role. This changed dramatically between 1130 and 1140 in Paris, when the Abbe Suger rebuilt the Saint Denis Basilica. Suger considered that light was the visible manifestation of the Holy Spirit.[62] He installed stained glass windows coloured with cobalt, which, combined with the light from the red glass, filled the church with a bluish violet light. The church became the marvel of the Christian world, and the colour became known as the French: "bleu de Saint-Denis". In the years that followed even more elegant blue stained glass windows were installed in other churches, including at Chartres Cathedral and Sainte-Chapelle in Paris.

In the 12th century the Roman Catholic Church dictated that painters in Italy (and the rest of Europe consequently) to paint the Virgin Mary with blue, which became associated with holiness, humility and virtue. In medieval paintings, blue was used to attract the attention of the viewer to the Virgin Mary. Paintings of the mythical King Arthur began to show him dressed in blue. The coat of arms of the kings of France became an azure or light blue shield, sprinkled with golden fleur-de-lis or lilies. Blue had come from obscurity to become the royal colour.

Renaissance through 18th century

Blue came into wider use beginning in the Renaissance, when artists began to paint the world with perspective, depth, shadows, and light from a single source. In Renaissance paintings, artists tried to create harmonies between blue and red, lightening the blue with lead white paint and adding shadows and highlights. Raphael was a master of this technique, carefully balancing the reds and the blues so no one colour dominated the picture.

Ultramarine was the most prestigious blue of the Renaissance, being more expensive than gold. Wealthy art patrons commissioned works with the most expensive blues possible. In 1616 Richard Sackville commissioned a portrait of himself by Isaac Oliver with three different blues, including ultramarine pigment for his stockings.[63]

An industry for the manufacture of fine blue and white pottery began in the 14th century in Jingdezhen, China, using white Chinese porcelain decorated with patterns of cobalt blue, imported from Persia. It was first made for the family of the Emperor of China, then was exported around the world, with designs for export adapted to European subjects and tastes. The Chinese blue style was also adapted by Dutch craftsmen in Delft and English craftsmen in Staffordshire in the 17th-18th centuries. in the 18th century, blue and white porcelains were produced by Josiah Wedgwood and other British craftsmen.[64]

19th-20th century

The early 19th century saw the ancestor of the modern blue business suit, created by Beau Brummel (1776–1840), who set fashion at the London Court. It also saw the invention of blue jeans, a highly popular form of workers's costume, invented in 1853 by Jacob W. Davis who used metal rivets to strengthen blue denim work clothing in the California gold fields. The invention was funded by San Francisco entrepreneur Levi Strauss, and spread around the world.Recognizing the emotional power of blue, many artists made it the central element of paintings in the 19th and 20th centuries. They included Pablo Picasso, Pavel Kuznetsov and the Blue Rose art group, and Kandinsky and Der Blaue Reiter (The Blue Rider) school.[65] Henri Matisse expressed deep emotions with blue, "A certain blue penetrates your soul."[66] In the second half of the 20th century, painters of the abstract expressionist movement use blues to inspire ideas and emotions. Painter Mark Rothko observed that colour was "only an instrument;" his interest was "in expressing human emotions tragedy, ecstasy, doom, and so on".[67]

In society and culture

See also: Blue in culture.

Uniforms

In the 17th century. The Prince-Elector of Brandenburg, Frederick William I of Prussia, chose Prussian blue as the new colour of Prussian military uniforms, because it was made with Woad, a local crop, rather than Indigo, which was produced by the colonies of Brandenburg's rival, England. It was worn by the German army until World War I, with the exception of the soldiers of Bavaria, who wore sky-blue.[68]

In 1748, the Royal Navy adopted a dark shade of blue for the uniform of officers.[69] It was first known as marine blue, now known as navy blue.[70] The militia organized by George Washington selected blue and buff, the colours of the British Whig Party. Blue continued to be the colour of the field uniform of the US Army until 1902, and is still the colour of the dress uniform.[71]

In the 19th century, police in the United Kingdom, including the Metropolitan Police and the City of London Police also adopted a navy blue uniform. Similar traditions were embraced in France and Austria.[72] It was also adopted at about the same time for the uniforms of the officers of the New York City Police Department.

Religion

Sports

In sports, blue is widely represented in uniforms in part because the majority of national teams wear the colours of their national flag. For example, the national men's football team of France are known as Les Bleus (the Blues). Similarly, Argentina, Italy, and Uruguay wear blue shirts.[87] The Asian Football Confederation and the Oceania Football Confederation use blue text on their logos. Blue is well represented in baseball (Blue Jays), basketball, and American football, and Ice hockey. The Indian national cricket team wears blue uniform during One day international matches, as such the team is also referred to as "Men in Blue".[88]

Politics

Unlike red or green, blue was not strongly associated with any particular country, religion or political movement. As the colour of harmony, it was chosen as the colour for the flags of the United Nations, the European Union, and NATO.[89] In politics, blue is often used as the colour of conservative parties, contrasting with the red associated with left-wing parties.[90] Some conservative parties that use the colour blue include the Conservative Party (UK),[91] Conservative Party of Canada,[92] Liberal Party of Australia,[93] Liberal Party of Brazil, and Likud of Israel. However, in some countries, blue is not associated main conservative party. In the United States, the liberal Democratic Party is associated with blue, while the conservative Republican Party with red. US states which have been won by the Democratic Party in four consecutive presidential elections are termed "blue states", while those that have been won by the Republican Party are termed "red states".[94] South Korea also uses this colour model, with the Democratic Party on the left using blue[95] and the People Power Party on the right using red.

See also

Works cited

Further reading

External links

Notes and References

  1. Web site: CSS Color Module Level 3 . live . https://web.archive.org/web/20101223001703/http://www.w3.org/TR/css3-color/#html4 . 23 December 2010 . W3C .
  2. Book: Defonseka, Chris . Polymeric Composites with Rice Hulls: An Introduction . 20 May 2019 . Walter de Gruyter GmbH & Co KG . 978-3-11-064320-6.
  3. Web site: Pigments through the Ages - History - Ultramarine . 22 April 2023 . WebExhibits .
  4. Michel Pastoureau, Bleu – Histoire d'une couleur
  5. Web site: Why is blue the world's favorite color? YouGov . 16 April 2023 . today.yougov.com . en-us.
  6. Webster's Seventh New Collegiate Dictionary (1970).
  7. Book: A New Dictionary of Heraldry . 1987 . . 978-0-906670-44-6 . Friar . Stephen . London . 40, 343.
  8. Lillo . Julio . González-Perilli . Fernando . Prado-León . Lilia . Melnikova . Anna . Álvaro . Leticia . Collado . José A. . Moreira . Humberto . 2018 . Basic Color Terms (BCTs) and Categories (BCCs) in Three Dialects of the Spanish Language: Interaction Between Cultural and Universal Factors . Frontiers in Psychology . 9 . 761 . 10.3389/fpsyg.2018.00761 . 29867702 . 5968181 . 1664-1078. free .
  9. Tim Howard . Why Isn't the Sky Blue? . Radiolab at WNYC Studios . 20 May 2012 . 27 April 2018 . https://web.archive.org/web/20181025072538/https://www.wnycstudios.org/story/211213-sky-isnt-blue . 25 October 2018 . Linguist: Guy Deutscher; Professor: Jules Davidoff.
  10. Web site: Wavelength of Blue and Red Light . 25 June 2022 . Center for Science Education.
  11. Web site: 2015 . The Science of Color . 25 June 2022 . library.si.edu.
  12. Arthur C. Hardy and Fred H. Perrin. The Principles of Optics. McGraw-Hill Book Co., Inc., New York. 1932.
  13. Web site: Sandra Espinet . Glossary Term: Color wheel . 25 June 2022 . Sanford-artedventures.com . 7 September 2008 . https://web.archive.org/web/20080907184837/http://www.sanford-artedventures.com/study/g_color_wheel.html . dead .
  14. Candela-Class High-Brightness InGaN/AlGaN Double-Heterostructure Blue-Light-Emitting-Diodes . Nakamura . S. . Mukai . T. . Senoh . M. . . 1994 . 64 . 1687 . 1994ApPhL..64.1687N . 10.1063/1.111832 . 13 . 0003-6951.
  15. Web site: Nakamura . Shuji . Development of the Blue Light-Emitting Diode . SPIE Newsroom . 28 September 2015.
  16. Iwasa, Naruhito; Mukai, Takashi and Nakamura, Shuji "Light-emitting gallium nitride-based compound semiconductor device" Issue date: 26 November 1996
  17. Web site: 12 January 2023 . Professor Shuji Nakamura was key to the Invention of Blu-Ray Technology . https://web.archive.org/web/20230324123538/https://ssleec.ucsb.edu/news/2023/01/12/professor-shuji-nakamura-was-key-invention-blu-ray-technology . 24 March 2023 . 4 June 2023 . University of California, Santa Barbara.
  18. Web site: Dr. Shuji Nakamura. https://web.archive.org/web/20190411125926/https://www.nae.edu/128641/Dr-Shuji-Nakamura-. National Academy of Engineering. 11 April 2019. 4 June 2023.
  19. https://www.news.ucsb.edu/2006/012148/2006-millennium-technology-prize 2006 Millennium technology prize awarded to UCSB's Shuji Nakamura
  20. News: Overbye . Dennis . Dennis Overbye . Nobel Prize in Physics . 7 October 2014 . .
  21. Web site: Laserglow – Blue, Red, Yellow, Green Lasers . live . https://web.archive.org/web/20110916051206/http://www.laserglow.com/GPO . 16 September 2011 . 20 September 2011 . Laserglow.com.
  22. Web site: Laserglow – Optogenetics . live . https://web.archive.org/web/20110915023159/http://www.laserglow.com/page/optogenetics . 15 September 2011 . 20 September 2011 . Laserglow.com.
  23. Web site: September 1998 . Iridescence in Lepidoptera . https://web.archive.org/web/20140407082122/http://emps.exeter.ac.uk/physics-astronomy/research/emag/themes/natural-photonics/iridescenceinlepidoptera/ . 7 April 2014 . 27 April 2012 . Natural Photonics (originally in Physics Review Magazine) . University of Exeter.
  24. Michel Pastoureau, Bleu – Histoire d'une couleur, pp. 114–16
  25. Roger Keyes, Japanese Woodblock Prints: A Catalogue of the Mary A. Ainsworth Collection, R, Allen Memorial Art Museum, Oberlin College, 1984, p. 42, plate #140, p. 91 and catalogue entry #439, p. 185. for more on the story of Prussian blue in Japanese prints, see also the website of the Victoria and Albert Museum, London.
  26. Maerz and Paul (1930). A Dictionary of Color New York: McGraw Hill p. 206
  27. Newsome . Andrew G. . Culver . Catherine A. . Van Breemen . Richard B. . 2014 . Nature's Palette: The Search for Natural Blue Colorants . Journal of Agricultural and Food Chemistry . 62 . 28 . 6498–6511 . 10.1021/jf501419q . 24930897.
  28. Book: Placke . Mina . Ullmann's Encyclopedia of Industrial Chemistry . Fischer . Norbert . Colditz . Michael . Kunkel . Ernst . Bohne . Karl-Heinz . 2016 . 978-3-527-30673-2 . 1–12 . Drawing and Writing Materials . 10.1002/14356007.a09_037.pub2.
  29. Web site: Why is the sky Blue? . live . https://web.archive.org/web/20151102085211/http://math.ucr.edu/home/baez/physics/General/BlueSky/blue_sky.html . 2 November 2015 . ucr.edu.
  30. Glenn S. Smith . July 2005 . Human color vision and the unsaturated blue color of the daytime sky . live . American Journal of Physics . 73 . 7 . 590–597 . 10.1119/1.1858479 . 2005AmJPh..73..590S . https://web.archive.org/web/20110715050855/http://www.patarnott.com/atms749/pdf/blueSkyHumanResponse.pdf . 15 July 2011 . Near sunrise and sunset, most of the light we see comes in nearly tangent to the Earth's surface, so that the light's path through the atmosphere is so long that much of the blue and even green light is scattered out, leaving the sun rays and the clouds it illuminates red. Therefore, when looking at the sunset and sunrise, the colour red is more perceptible than any of the other colours..
  31. Web site: Anne Marie Helmenstine . Why Is the Ocean Blue? . live . https://web.archive.org/web/20121118203351/http://chemistry.about.com/od/waterchemistry/f/why-is-the-ocean-blue.htm . 18 November 2012 . About.com Education.
  32. Book: Nuno Mateas, Victor de Freitas . Anthocyanins: Biosynthesis, Functions, and Applications . 2008 . Springer . 978-0-387-77334-6 . Gould . K. . 283 . Anthrocyanins as Food Colorants . Davies . K. . Winefield . C..
  33. Umbers . Kate D. L. . 2013 . On the Perception, Production and Function of Blue Colouration in Animals . Journal of Zoology . 289 . 4 . 229–242 . 10.1111/jzo.12001. free .
  34. Vane-Wright . Richard I. . 22 February 1979 . The coloration, identification and phylogeny of Nessaea butterflies (Lepidoptera: Nymphalidae) . Bulletin of the British Museum (Natural History) . Entomology Series . 38 . 2 . 27–56 . 8 February 2018.
  35. Book: Simonis . Priscilla . Photonic Crystals - Introduction, Applications and Theory . Serge . Berthier . 30 March 2012 . InTech . 978-953-51-0431-5 . Massaro . Alessandro . English . Chapter number 1 How Nature produces blue color . 8 February 2018 . https://www.researchgate.net/publication/258042644.
  36. Goda, Makoto . Fujii, Ryozo . 1995 . Blue Chromatophores in Two Species of Callionymid Fish . Zoological Science . 12 . 6 . 811–813 . 10.2108/zsj.12.811 . 86385679. free .
  37. Web site: 11 August 2015 . How Birds Make Colorful Feathers .
  38. Potyrailo . Radislav A. . Bonam . Ravi K. . Hartley . John G. . Starkey . Timothy A. . Vukusic . Peter . Vasudev . Milana . Bunning . Timothy . Naik . Rajesh R. . Tang . Zhexiong . Palacios . Manuel A. . Larsen . Michael . 2015 . Towards outperforming conventional sensor arrays with fabricated individual photonic vapour sensors inspired by Morpho butterflies . Nature Communications . 6 . 7959 . 2015NatCo...6.7959P . 10.1038/ncomms8959 . 4569698 . 26324320 . Le Tarte . Laurie A. . Grande . James C. . Zhong . Sheng . Deng . Tao.
  39. Prum RO, Torres RH . May 2004 . Structural Colouration of Mammalian Skin: Convergent Evolution of Coherently Scattering Dermal Collagen Arrays . https://ghostarchive.org/archive/20221009/http://jeb.biologists.org/content/207/12/2157.full.pdf . 9 October 2022 . live . The Journal of Experimental Biology . 207 . Pt 12 . 2157–2172 . 10.1242/jeb.00989 . 15143148 . 1808/1599 . 8268610.
  40. Ariel Rodríguez . Nicholas I. Mundy . Roberto Ibáñez . Heike Pröhl . 2020 . Being red, blue and green: the genetic basis of coloration differences in the strawberry poison frog (Oophaga pumilio) . BMC Genomics . 21 . 1 . 301 . 10.1186/s12864-020-6719-5 . 7158012 . 32293261 . free .
  41. Makoto Goda . Ryozo Fujii . 1998 . The Blue Coloration of the Common Surgeonfish, Paracanthurus hepatus—II. Color Revelation and Color Changes . Zoological Science . 15 . 3 . 323–333 . 10.2108/zsj.15.323 . 18465994 . 5860272. free .
  42. Wielgus AR, Sarna T . 2005 . Melanin in human irides of different color and age of donors . Pigment Cell Res. . 18 . 6 . 454–64 . 10.1111/j.1600-0749.2005.00268.x . 16280011.
  43. Prota G, Hu DN, Vincensi MR, McCormick SA, Napolitano A . 1998 . Characterization of melanins in human irides and cultured uveal melanocytes from eyes of different colors . Exp. Eye Res. . 67 . 3 . 293–99 . 10.1006/exer.1998.0518 . 9778410. free .
  44. Book: Fox, Denis Llewellyn . Biochromy: Natural Coloration of Living Things . University of California Press . 1979 . 978-0-520-03699-4 . 9 . https://web.archive.org/web/20151003232604/https://books.google.com/books?id=c2xyxwlm2UkC&pg=PA9 . 3 October 2015 . live.
  45. Mason . Clyde W. . 1924 . Blue Eyes . Journal of Physical Chemistry . 28 . 5 . 498–501 . 10.1021/j150239a007.
  46. Web site: Pigmentation, the Pilous System, and Morphology of the Soft Parts . https://web.archive.org/web/20110726095519/http://carnby.altervista.org/troe/08-05.htm . 26 July 2011 . altervista.org.
  47. statement by Hans Eiberg from the Department of Cellular and Molecular Medicine at the University of Copenhagen
  48. Web site: Weise . Elizabeth . 5 February 2008 . More than meets the blue eye: You may all be related . https://web.archive.org/web/20120910205153/http://www.usatoday.com/news/health/2008-02-05-blue-eyes_N.htm . 10 September 2012 . 23 December 2011 . USA TODAY.
  49. Web site: Douglas Belkin . 17 October 2006 . Don't it make my blue eyes brown Americans are seeing a dramatic color change . live . https://web.archive.org/web/20120223022627/http://www.boston.com/yourlife/articles/2006/10/17/dont_it_make_my_blue_eyes_brown/ . 23 February 2012 . The Boston Globe.
  50. David Bomford and Ashok Roy, A Closer Look- Colour (2009), National Gallery Company, London,
  51. Book: Moorey, Peter Roger . Ancient Mesopotamian Materials and Industries: the Archaeological Evidence . Eisenbrauns . 1999 . 978-1-57506-042-2 . 86–87.
  52. Web site: Excavation Bhirrana ASI Nagpur . 21 August 2020 . excnagasi.in.
  53. Sarkar . Anindya . Mukherjee . Arati Deshpande . Bera . M. K. . Das . B. . Juyal . Navin . Morthekai . P. . Deshpande . R. D. . Shinde . V. S. . Rao . L. S. . 25 May 2016 . Oxygen isotope in archaeological bioapatites from India: Implications to climate change and decline of Bronze Age Harappan civilization . Scientific Reports . en . 6 . 1 . 26555 . 2016NatSR...626555S . 10.1038/srep26555 . 2045-2322 . 4879637 . 27222033 . free . 4425978.
  54. DIKSHIT . K.N. . 2012 . The Rise of Indian Civilization: Recent Archaeological Evidence from the Plains of 'Lost' River Saraswati and Radio-Metric Dates . Bulletin of the Deccan College Research Institute . 72/73 . 1–42 . 0045-9801 . 43610686.
  55. Alessandro Bongioanni & Maria Croce
  56. See .
  57. Book: Moorey, Peter Roger . Ancient mesopotamian materials and industries: the archaeological evidence . Eisenbrauns . 1999 . 978-1-57506-042-2 . 8687.
  58. Chase, W.T. 1971, "Egyptian blue as a pigment and ceramic material." In: R. Brill (ed.) Science and Archaeology. Cambridge, Mass: MIT Press.
  59. J. Baines, "Color Terminology and Color Classification in Ancient Egyptian Color Terminology and Polychromy", in The American Anthropologist, volume 87, 1985, pp. 282–97.
  60. Caesar, The Gallic Wars, V., 14, 2. Cited by Miche Pastourou, p. 178.
  61. L. Brehier, Les mosaiques a fond d'azur, in Etudes Byzantines, volume III, Paris, 1945. pp. 46ff.
  62. Lours, Mathieu, "Le Vitrail", Editions Jean-Paul Gisserot, Paris (2021)
  63. Travis, Time, "The Victoria and Albert Book of Colour Design" (2020), p. 185
  64. Travis, Tim, "The Victoria and Albert Museum Book of Colour in Design" (2020), p. 200-201
  65. Wassily Kandinsky, M. T. Sadler (Translator) Concerning the Spiritual in Art. Dover Publ. (Paperback). 80 pp. .
  66. French: "Un certain bleu pénètre votre âme." Cited in .
  67. Mark Rothko 1903–1970. Tate Gallery Publishing, 1987.
  68. Heller (2010) p.31
  69. Heller (2010) p.32
  70. J.R. Hill, The Oxford Illustrated History of the Royal Navy, Oxford University Press, 1995.
  71. Web site: Walter H. Bradford . Wearing Army Blue: a 200-year Tradition . https://web.archive.org/web/20141119095538/http://www.army.mil/symbols/uniforms/history.html . 19 November 2014 . army.mil.
  72. Jean Tulard, Jean-François Fayard, Alfred Fierro, Histoire et dictionnaire de la Révolution française, 1789–1799, Éditions Robert Laffont, collection Bouquins, Paris, 1987.
  73. [Book of Numbers|Numbers]
  74. http://www.tekhelet.com Tekhelet.com
  75. Mishneh Torah, Tzitzit 2:1; Commentary on Numbers 15:38.
  76. Numbers Rabbah 14:3; Hullin 89a.
  77. [Book of Exodus|Exodus]
  78. [Book of Numbers|Numbers]
  79. Heller, "Psychologie de la Colour - Effets et Symboliques", (2009),p. 32
  80. Web site: Your question answered . https://web.archive.org/web/20060904024808/http://campus.udayton.edu/mary/questions/faq/faq12.html . 4 September 2006 . udayton.edu.
  81. Web site: The Spirit of Notre Dame . live . https://web.archive.org/web/20111230134831/http://www.nd.edu/~wcawley/corson/schoolcolors.htm . 30 December 2011 . 31 December 2011 . Nd.edu.
  82. Web site: Board Question #31244 | The 100 Hour Board . live . https://web.archive.org/web/20120331124840/http://theboard.byu.edu/questions/31244/ . 31 March 2012 . 31 December 2011 . Theboard.byu.edu.
  83. Stevens, Samantha. The Seven Rays: a Universal Guide to the Archangels. Toronto: Insomniac Press, 2004. . p. 24.
  84. Sikh Rehat Maryada: Section Three, Chapter IV, Article V, r.
  85. Web site: Nishan Sahib Khanda Sikh Symbols Sikh Museum History Heritage Sikhs. www.sikhmuseum.com.
  86. Web site: Magical Properties of Colors . 24 December 2020 . Wicca Living . en-US.
  87. Web site: FIFA World Cup 2010 – Historical Football Kits . live . https://web.archive.org/web/20120107043904/http://www.historicalkits.co.uk/international/tournaments/fifa_world_cup_2010/fifa-world-cup-2010.html . 7 January 2012 . 31 December 2011 . Historicalkits.co.uk.
  88. News: 3 July 2016 . This Is The Reason Why Indian Cricket Team Wears A Blue Jersey During ODIs .
  89. Heller, "Psychologie de la Couleur" pp. 36-37
  90. Book: Stone, Terry Lee . Color design workbook : a real-world guide to using color in graphic design . 2006 . Gloucester, Mass. : Rockport Publishers . Internet Archive . 978-1-59253-192-9.
  91. Web site: 20 April 2006 . Why is the Conservative Party blue? . 23 April 2018 . BBC News.
  92. Web site: Official Logos . 13 February 2024 . Conservative Party of Canada . en-US.
  93. Web site: What are the colours of the Australian political parties? - Parliamentary Education Office . 13 February 2024 . peo.gov.au . en.
  94. News: Battaglio . Stephen . 3 November 2016 . When red meant Democratic and blue was Republican. A brief history of TV electoral maps . Los Angeles Times . 28 November 2018.
  95. Web site: 8 March 2023 . 더불어민주당 . 13 February 2024 . https://web.archive.org/web/20230308211933/https://theminjoo.kr/introduce/logo . 8 March 2023 .