White
light dispersed by a
prism into the colors of the optical spectrum.
The
visible spectrum is the portion of the
electromagnetic spectrum that is
visible to (can be detected by) 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 750 nm. In terms of frequency, this corresponds to a band in the vicinity of 790–400
terahertz. A light-adapted eye generally has its maximum sensitivity at around 555
nm (540 THz), in the
green region of the optical spectrum (see:
luminosity function). The spectrum does not, however, contain all the
colors that the human eyes and brain can distinguish.
Unsaturated colors such as
pink, or
purple variations such as
magenta, are absent, for example, because they can only be made by a mix of multiple wavelengths.
Visible wavelengths also pass through the "
optical window", the region of the electromagnetic spectrum that passes largely unattenuated through the
Earth's atmosphere. Clean air
scatters blue light more than wavelengths toward the red, which is why the mid-day sky appears blue. The human eye's response is defined by subjective testing (see
CIE), but atmospheric windows are defined by physical measurement.
The "visible window" is so called because it overlaps the human visible response spectrum. The
near infrared (NIR) windows lie just out of human response window, and the Medium Wavelength IR (MWIR) and Long Wavelength or Far Infrared (LWIR or FIR) are far beyond the human response region.
Many
species can see wavelengths that fall outside the "visible spectrum".
Bees and many other
insects can see light in the
ultraviolet, 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 us. Birds too can see into the ultraviolet (300-400 nm), and some have sex-dependent markings on their plumage, which are only visible in the ultraviolet range.
History
Newton's color circle, from
Opticks of 1704, showing the colors correlated 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.
Two of the earliest explanations of the optical spectrum came from
Isaac Newton, when he wrote his
Opticks, and from
Goethe, in his
Theory of Colours, although earlier observations had been made by
Roger Bacon who first recognized the visible spectrum in a glass of water, four centuries before Newton discovered that prisms could disassemble and reassemble white light.
Newton first used the word
spectrum (
Latin for "appearance" or "apparition") 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 that light was made up of "
corpuscles" (particles) of different colors, and that the different colors of light moved at different speeds in transparent matter, with red light moving more quickly in glass than violet. The result is that red light bends (
refracted) less sharply than violet as it passes through the prism, creating a spectrum of colors.
Newton divided the spectrum into seven named colors:
red,
orange,
yellow,
green,
blue,
indigo, and
violet. (Some schoolchildren memorize this order using the mnemonic
ROY G. BIV.) He chose seven colors out of a belief, derived from the
ancient Greek sophists, that there was a connection between the colors, the musical notes, the known objects in the
solar system, and the days of the week. The human eye is relatively insensitive to indigo's frequencies, and some otherwise well-sighted people cannot distinguish indigo from blue and violet. For this reason some commentators, including
Isaac Asimov, have suggested that indigo should not be regarded as a color in its own right but merely as a shade of blue or violet.
Johann Wolfgang von 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 only appears 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—
ultraviolet and
infrared—was discovered and characterized by
William Herschel,
Johann Wilhelm Ritter,
Thomas Young,
Thomas Johann Seebeck, and others.
Young was the first to measure the wavelengths of different colors of light, in 1802.
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.
Spectral colors
Colors that can be produced by visible light of a
single wavelength (monochromatic light) are referred to as the
pure spectral colors.
Although the spectrum is continuous, with no clear boundaries between one color and the next, the ranges may be used as an approximation.
Spectroscopy
Spectroscopy is the study of objects based on the spectrum of color they emit or absorb. Spectroscopy is an important investigative tool in
astronomy where scientists use it to analyze the properties of distant objects. Typically,
astronomical spectroscopy uses high-dispersion
diffraction gratings to observe spectra at very high spectral resolutions.
Helium was first detected by analyzing the spectrum of the
Sun.
Chemical elements can be detected in astronomical objects by
emission lines and
absorption lines. The shifting of spectral lines can be used to measure the
red shift or
blue shift of distant or fast-moving objects. The first
exoplanets
were discovered by analyzing the
Doppler shift of stars at a resolution that revealed variations in
radial velocity as small as a few
meters per second. The presence of planets was revealed by their
gravitational influence on the motion of the stars.
Color display spectrum
Color displays (e.g.,
computer monitors and
televisions) mix
red,
green, and
blue color to create colors within their respective
color triangles, and so can only approximately represent spectral colors, which are in general outside any color triangle.
See also
