Light is electromagnetic radiation within a certain portion of the electromagnetic spectrum. The word usually refers to visible light, which is the visible spectrum that is visible to the human eye and is responsible for the sense of sight. Visible light is usually defined as having wavelengths in the range of 400–700 nanometres (nm), or 4.00 × 10−7 to 7.00 × 10−7 m, between the infrared (with longer wavelengths) and the ultraviolet (with shorter wavelengths). This wavelength means a frequency range of roughly 430–750 terahertz (THz).
The main source of light on Earth is the Sun. Sunlight provides the energy that green plants use to create sugars mostly in the form of starches, which release energy into the living things that digest them. This process of photosynthesis provides virtually all the energy used by living things. Historically, another important source of light for humans has been fire, from ancient campfires to modern kerosene lamps. With the development of electric lights and power systems, electric lighting has effectively replaced firelight. Some species of animals generate their own light, a process called bioluminescence. For example, fireflies use light to locate mates, and vampire squids use it to hide themselves from prey.
The primary properties of visible light are intensity, propagation direction, frequency or wavelength spectrum, and polarization, while its speed in a vacuum, 299,792,458 metres per second, is one of the fundamental constants
of nature. Visible light, as with all types of electromagnetic
radiation (EMR), is experimentally found to always move at this speed in
a vacuum.
In physics, the term light sometimes refers to electromagnetic radiation of any wavelength, whether visible or not. In this sense, gamma rays, X-rays, microwaves and radio waves
are also light. Like all types of EM radiation, visible light
propagates as waves. However, the energy imparted by the waves is
absorbed at single locations the way particles are absorbed. The
absorbed energy of the EM waves is called a photon, and represents the
quanta of light. When a wave of light is transformed and absorbed as a
photon, the energy of the wave instantly collapses to a single location,
and this location is where the photon "arrives." This is what is called
the wave function collapse. This dual wave-like and particle-like nature of light is known as the wave–particle duality. The study of light, known as optics, is an important research area in modern physics.
Electromagnetic spectrum and visible light
Generally, EM radiation (the designation "radiation" excludes static electric, magnetic, and near fields), or EMR, is classified by wavelength into radio waves, microwaves, infrared, the visible spectrum that we perceive as light, ultraviolet, X-rays, and gamma rays.
The behavior of EMR depends on its wavelength. Higher frequencies
have shorter wavelengths, and lower frequencies have longer
wavelengths. When EMR interacts with single atoms and molecules, its
behavior depends on the amount of energy per quantum it carries.
EMR in the visible light region consists of quanta (called photons)
that are at the lower end of the energies that are capable of causing
electronic excitation within molecules, which leads to changes in the
bonding or chemistry of the molecule. At the lower end of the visible
light spectrum, EMR becomes invisible to humans (infrared) because its
photons no longer have enough individual energy to cause a lasting
molecular change (a change in conformation) in the visual molecule retinal in the human retina, which change triggers the sensation of vision.
There exist animals that are sensitive to various types of infrared, but not by means of quantum-absorption. Infrared sensing in snakes depends on a kind of natural thermal imaging,
in which tiny packets of cellular water are raised in temperature by
the infrared radiation. EMR in this range causes molecular vibration and
heating effects, which is how these animals detect it.
Above the range of visible light, ultraviolet light becomes
invisible to humans, mostly because it is absorbed by the cornea below
360 nm and the internal lens below 400 nm. Furthermore, the rods and cones located in the retina
of the human eye cannot detect the very short (below 360 nm)
ultraviolet wavelengths and are in fact damaged by ultraviolet. Many
animals with eyes that do not require lenses (such as insects and
shrimp) are able to detect ultraviolet, by quantum photon-absorption
mechanisms, in much the same chemical way that humans detect visible
light.
Various sources define visible light as narrowly as 420–680 nm to as broadly as 380–800 nm. Under ideal laboratory conditions, people can see infrared up to at least 1050 nm; children and young adults may perceive ultraviolet wavelengths down to about 310–313 nm.
Plant growth is also affected by the color spectrum of light, a process known as photomorphogenesis.
Speed of light
The speed of light in a vacuum is defined to be exactly 299,792,458 m/s
(approx. 186,282 miles per second). The fixed value of the speed of
light in SI units results from the fact that the metre is now defined in
terms of the speed of light. All forms of electromagnetic radiation
move at exactly this same speed in vacuum.
Different physicists have attempted to measure the speed of light throughout history. Galileo
attempted to measure the speed of light in the seventeenth century. An
early experiment to measure the speed of light was conducted by Ole Rømer, a Danish physicist, in 1676. Using a telescope, Rømer observed the motions of Jupiter and one of its moons, Io.
Noting discrepancies in the apparent period of Io's orbit, he
calculated that light takes about 22 minutes to traverse the diameter of
Earth's orbit.
However, its size was not known at that time. If Rømer had known the
diameter of the Earth's orbit, he would have calculated a speed of
227,000,000 m/s.
Another, more accurate, measurement of the speed of light was performed in Europe by Hippolyte Fizeau in 1849. Fizeau directed a beam of light at a mirror several kilometers away. A rotating cog wheel
was placed in the path of the light beam as it traveled from the
source, to the mirror and then returned to its origin. Fizeau found
that at a certain rate of rotation, the beam would pass through one gap
in the wheel on the way out and the next gap on the way back. Knowing
the distance to the mirror, the number of teeth on the wheel, and the
rate of rotation, Fizeau was able to calculate the speed of light as
313,000,000 m/s.
Léon Foucault carried out an experiment which used rotating mirrors to obtain a value of 298,000,000 m/s in 1862. Albert A. Michelson
conducted experiments on the speed of light from 1877 until his death
in 1931. He refined Foucault's methods in 1926 using improved rotating
mirrors to measure the time it took light to make a round trip from Mount Wilson to Mount San Antonio in California. The precise measurements yielded a speed of 299,796,000 m/s.
The effective velocity of light in various transparent substances containing ordinary matter, is less than in vacuum. For example, the speed of light in water is about 3/4 of that in vacuum.
Two independent teams of physicists were said to bring light to a "complete standstill" by passing it through a Bose–Einstein condensate of the element rubidium, one team at Harvard University and the Rowland Institute for Science in Cambridge, Massachusetts, and the other at the Harvard–Smithsonian Center for Astrophysics, also in Cambridge.
However, the popular description of light being "stopped" in these
experiments refers only to light being stored in the excited states of
atoms, then re-emitted at an arbitrary later time, as stimulated by a
second laser pulse. During the time it had "stopped" it had ceased to be
light.
Optics
The study of light and the interaction of light and matter is termed optics. The observation and study of optical phenomena such as rainbows and the aurora borealis offer many clues as to the nature of light.
Refraction
Refraction is the bending of light rays when passing through a
surface between one transparent material and another. It is described by
Snell's Law:
where θ1 is the angle between the ray and the surface normal in the first medium, θ2 is the angle between the ray and the surface normal in the second medium, and n1 and n2 are the indices of refraction, n = 1 in a vacuum and n > 1 in a transparent substance.
When a beam of light crosses the boundary between a vacuum and
another medium, or between two different media, the wavelength of the
light changes, but the frequency remains constant. If the beam of light
is not orthogonal
(or rather normal) to the boundary, the change in wavelength results in
a change in the direction of the beam. This change of direction is
known as refraction.
The refractive quality of lenses is frequently used to manipulate light in order to change the apparent size of images. Magnifying glasses, spectacles, contact lenses, microscopes and refracting telescopes are all examples of this manipulation.
Light sources
There are many sources of light. A body at a given temperature emits a characteristic spectrum of black-body radiation. A simple thermal source is sunlight, the radiation emitted by the chromosphere of the Sun
at around 6,000 kelvins (5,730 degrees Celsius; 10,340 degrees
Fahrenheit) peaks in the visible region of the electromagnetic spectrum
when plotted in wavelength units and roughly 44% of sunlight energy that reaches the ground is visible. Another example is incandescent light bulbs,
which emit only around 10% of their energy as visible light and the
remainder as infrared. A common thermal light source in history is the
glowing solid particles in flames, but these also emit most of their radiation in the infrared, and only a fraction in the visible spectrum.
The peak of the blackbody spectrum is in the deep infrared, at about 10 micrometer
wavelength, for relatively cool objects like human beings. As the
temperature increases, the peak shifts to shorter wavelengths, producing
first a red glow, then a white one, and finally a blue-white colour as
the peak moves out of the visible part of the spectrum and into the
ultraviolet. These colours can be seen when metal is heated to "red hot"
or "white hot". Blue-white thermal emission is not often seen, except in stars (the commonly seen pure-blue color in a gas flame or a welder's
torch is in fact due to molecular emission, notably by CH radicals
(emitting a wavelength band around 425 nm, and is not seen in stars or
pure thermal radiation).
Atoms emit and absorb light at characteristic energies. This produces "emission lines" in the spectrum of each atom. Emission can be spontaneous, as in light-emitting diodes, gas discharge lamps (such as neon lamps and neon signs, mercury-vapor lamps, etc.), and flames (light from the hot gas itself—so, for example, sodium in a gas flame emits characteristic yellow light). Emission can also be stimulated, as in a laser or a microwave maser.
Deceleration of a free charged particle, such as an electron, can produce visible radiation: cyclotron radiation, synchrotron radiation, and bremsstrahlung
radiation are all examples of this. Particles moving through a medium
faster than the speed of light in that medium can produce visible Cherenkov radiation. Certain chemicals produce visible radiation by chemoluminescence. In living things, this process is called bioluminescence. For example, fireflies produce light by this means, and boats moving through water can disturb plankton which produce a glowing wake.
Certain substances produce light when they are illuminated by more energetic radiation, a process known as fluorescence. Some substances emit light slowly after excitation by more energetic radiation. This is known as phosphorescence. Phosphorescent materials can also be excited by bombarding them with subatomic particles. Cathodoluminescence is one example. This mechanism is used in cathode ray tube television sets and computer monitors.
Certain other mechanisms can produce light:
- Bioluminescence
- Cherenkov radiation
- Electroluminescence
- Scintillation
- Sonoluminescence
- Triboluminescence
When the concept of light is intended to include very-high-energy
photons (gamma rays), additional generation mechanisms include:
- Particle–antiparticle annihilation
- Radioactive decay
Units and measures
Light is measured with two main alternative sets of units: radiometry consists of measurements of light power at all wavelengths, while photometry
measures light with wavelength weighted with respect to a standardised
model of human brightness perception. Photometry is useful, for
example, to quantify Illumination (lighting) intended for human use.
The photometry units are different from most systems of physical
units in that they take into account how the human eye responds to
light. The cone cells
in the human eye are of three types which respond differently across
the visible spectrum, and the cumulative response peaks at a wavelength
of around 555 nm. Therefore, two sources of light which produce the same
intensity (W/m2) of visible light do not necessarily appear
equally bright. The photometry units are designed to take this into
account, and therefore are a better representation of how "bright" a
light appears to be than raw intensity. They relate to raw power by a quantity called luminous efficacy,
and are used for purposes like determining how to best achieve
sufficient illumination for various tasks in indoor and outdoor
settings. The illumination measured by a photocell
sensor does not necessarily correspond to what is perceived by the
human eye, and without filters which may be costly, photocells and charge-coupled devices (CCD) tend to respond to some infrared, ultraviolet or both.
Light pressure
Light exerts physical pressure on objects in its path, a phenomenon
which can be deduced by Maxwell's equations, but can be more easily
explained by the particle nature of light: photons strike and transfer
their momentum. Light pressure is equal to the power of the light beam
divided by c, the speed of light. Due to the magnitude of c, the effect of light pressure is negligible for everyday objects. For example, a one milliwatt laser pointer exerts a force of about 3.3 piconewtons on the object being illuminated; thus, one could lift a U.S. penny with laser pointers, but doing so would require about 30 billion 1-mW laser pointers. However, in nanometer scale applications such as nanoelectromechanical systems
(|NEMS), the effect of light pressure is more significant, and
exploiting light pressure to drive NEMS mechanisms and to flip
nanometer scale physical switches in integrated circuits is an active
area of research. At larger scales, light pressure can cause asteroids to spin faster, acting on their irregular shapes as on the vanes of a windmill. The possibility of making solar sails that would accelerate spaceships in space is also under investigation.
Although the motion of the Crookes radiometer
was originally attributed to light pressure, this interpretation is
incorrect; the characteristic Crookes rotation is the result of a
partial vacuum. This should not be confused with the Nichols radiometer, in which the (slight) motion caused by torque (though not enough for full rotation against friction) is directly caused by light pressure.
As a consequence of light pressure, Einstein
in 1909 predicted the existence of "radiation friction" which would
oppose the movement of matter. He wrote, “radiation will exert pressure
on both sides of the plate. The forces of pressure exerted on the two
sides are equal if the plate is at rest. However, if it is in motion,
more radiation will be reflected on the surface that is ahead during the
motion (front surface) than on the back surface. The backward acting
force of pressure exerted on the front surface is thus larger than the
force of pressure acting on the back. Hence, as the resultant of the two
forces, there remains a force that counteracts the motion of the plate
and that increases with the velocity of the plate. We will call this
resultant 'radiation friction' in brief.”
Historical theories about light, in chronological order
Classical Greece and Hellenism
In the fifth century BC, Empedocles postulated that everything was composed of four elements; fire, air, earth and water. He believed that Aphrodite
made the human eye out of the four elements and that she lit the fire
in the eye which shone out from the eye making sight possible. If this
were true, then one could see during the night just as well as during
the day, so Empedocles postulated an interaction between rays from the
eyes and rays from a source such as the sun.
In about 300 BC, Euclid wrote Optica,
in which he studied the properties of light. Euclid postulated that
light travelled in straight lines and he described the laws of
reflection and studied them mathematically. He questioned that sight is
the result of a beam from the eye, for he asks how one sees the stars
immediately, if one closes one's eyes, then opens them at night. If the
beam from the eye travels infinitely fast this is not a problem.
In 55 BC, Lucretius, a Roman who carried on the ideas of earlier Greek atomists,
wrote that "The light & heat of the sun; these are composed of
minute atoms which, when they are shoved off, lose no time in shooting
right across the interspace of air in the direction imparted by the
shove." (from On the nature of the Universe). Despite being similar to later particle theories, Lucretius's views were not generally accepted. Ptolemy (c. 2nd century) wrote about the refraction of light in his book Optics.
Classical India
In ancient India, the Hindu schools of Samkhya and Vaisheshika,
from around the early centuries AD developed theories on light.
According to the Samkhya school, light is one of the five fundamental
"subtle" elements (tanmatra) out of which emerge the gross elements. The atomicity of these elements is not specifically mentioned and it appears that they were actually taken to be continuous.
On the other hand, the Vaisheshika school gives an atomic theory of the physical world on the non-atomic ground of ether, space and time. The basic atoms are those of earth (prthivi), water (pani), fire (agni), and air (vayu) Light rays are taken to be a stream of high velocity of tejas (fire) atoms. The particles of light can exhibit different characteristics depending on the speed and the arrangements of the tejas atoms.
The Vishnu Purana refers to sunlight as "the seven rays of the sun".
The Indian Buddhists, such as Dignāga in the 5th century and Dharmakirti
in the 7th century, developed a type of atomism that is a philosophy
about reality being composed of atomic entities that are momentary
flashes of light or energy. They viewed light as being an atomic entity
equivalent to energy.
Descartes
René Descartes (1596–1650) held that light was a mechanical property of the luminous body, rejecting the "forms" of Ibn al-Haytham and Witelo as well as the "species" of Bacon, Grosseteste, and Kepler. In 1637 he published a theory of the refraction
of light that assumed, incorrectly, that light travelled faster in a
denser medium than in a less dense medium. Descartes arrived at this
conclusion by analogy with the behavior of sound waves.
Although Descartes was incorrect about the relative speeds, he was
correct in assuming that light behaved like a wave and in concluding
that refraction could be explained by the speed of light in different
media.
Descartes is not the first to use the mechanical analogies but
because he clearly asserts that light is only a mechanical property of
the luminous body and the transmitting medium, Descartes' theory of
light is regarded as the start of modern physical optics.
Particle theory
Pierre Gassendi (1592–1655), an atomist, proposed a particle theory of light which was published posthumously in the 1660s. Isaac Newton studied Gassendi's work at an early age, and preferred his view to Descartes' theory of the plenum. He stated in his Hypothesis of Light of 1675 that light was composed of corpuscles
(particles of matter) which were emitted in all directions from a
source. One of Newton's arguments against the wave nature of light was
that waves were known to bend around obstacles, while light traveled
only in straight lines. He did, however, explain the phenomenon of the diffraction of light (which had been observed by Francesco Grimaldi) by allowing that a light particle could create a localized wave in the aether.
Newton's theory could be used to predict the reflection of light, but could only explain refraction by incorrectly assuming that light accelerated upon entering a denser medium because the gravitational pull was greater. Newton published the final version of his theory in his Opticks of 1704. His reputation helped the particle theory of light to hold sway during the 18th century. The particle theory of light led Laplace
to argue that a body could be so massive that light could not escape
from it. In other words, it would become what is now called a black hole.
Laplace withdrew his suggestion later, after a wave theory of light
became firmly established as the model for light (as has been explained,
neither a particle or wave theory is fully correct). A translation of
Newton's essay on light appears in The large scale structure of space-time, by Stephen Hawking and George F. R. Ellis.
The fact that light could be polarized was for the first time qualitatively explained by Newton using the particle theory. Étienne-Louis Malus in 1810 created a mathematical particle theory of polarization. Jean-Baptiste Biot
in 1812 showed that this theory explained all known phenomena of light
polarization. At that time the polarization was considered as the proof
of the particle theory.
Wave theory
To explain the origin of colors, Robert Hooke (1635-1703) developed a "pulse theory" and compared the spreading of light to that of waves in water in his 1665 work Micrographia ("Observation IX"). In 1672 Hooke suggested that light's vibrations could be perpendicular to the direction of propagation. Christiaan Huygens (1629-1695) worked out a mathematical wave theory of light in 1678, and published it in his Treatise on light in 1690. He proposed that light was emitted in all directions as a series of waves in a medium called the Luminiferous ether. As waves are not affected by gravity, it was assumed that they slowed down upon entering a denser medium.
The wave theory predicted that light waves could interfere with each other like sound waves (as noted around 1800 by Thomas Young). Young showed by means of a diffraction experiment that light behaved as waves. He also proposed that different colors were caused by different wavelengths
of light, and explained color vision in terms of three-colored
receptors in the eye. Another supporter of the wave theory was Leonhard Euler. He argued in Nova theoria lucis et colorum (1746) that diffraction could more easily be explained by a wave theory. In 1816 André-Marie Ampère gave Augustin-Jean Fresnel an idea that the polarization of light can be explained by the wave theory if light were a transverse wave.
Later, Fresnel independently worked out his own wave theory of light, and presented it to the Académie des Sciences in 1817. Siméon Denis Poisson
added to Fresnel's mathematical work to produce a convincing argument
in favor of the wave theory, helping to overturn Newton's corpuscular
theory.
By the year 1821, Fresnel was able to show via mathematical methods
that polarisation could be explained by the wave theory of light and
only if light was entirely transverse, with no longitudinal vibration
whatsoever.
The weakness of the wave theory was that light waves, like sound
waves, would need a medium for transmission. The existence of the
hypothetical substance luminiferous aether proposed by Huygens in 1678 was cast into strong doubt in the late nineteenth century by the Michelson–Morley experiment.
Newton's corpuscular theory implied that light would travel
faster in a denser medium, while the wave theory of Huygens and others
implied the opposite. At that time, the speed of light
could not be measured accurately enough to decide which theory was
correct. The first to make a sufficiently accurate measurement was Léon Foucault, in 1850.
His result supported the wave theory, and the classical particle theory
was finally abandoned, only to partly re-emerge in the 20th century.
Electromagnetic theory
In 1845, Michael Faraday discovered that the plane of polarization of linearly polarized light is rotated when the light rays travel along the magnetic field direction in the presence of a transparent dielectric, an effect now known as Faraday rotation. This was the first evidence that light was related to electromagnetism. In 1846 he speculated that light might be some form of disturbance propagating along magnetic field lines.
Faraday proposed in 1847 that light was a high-frequency
electromagnetic vibration, which could propagate even in the absence of a
medium such as the ether.
Faraday's work inspired James Clerk Maxwell
to study electromagnetic radiation and light. Maxwell discovered that
self-propagating electromagnetic waves would travel through space at a
constant speed, which happened to be equal to the previously measured
speed of light. From this, Maxwell concluded that light was a form of
electromagnetic radiation: he first stated this result in 1862 in On Physical Lines of Force. In 1873, he published A Treatise on Electricity and Magnetism, which contained a full mathematical description of the behavior of electric and magnetic fields, still known as Maxwell's equations. Soon after, Heinrich Hertz
confirmed Maxwell's theory experimentally by generating and detecting
radio waves in the laboratory, and demonstrating that these waves
behaved exactly like visible light, exhibiting properties such as
reflection, refraction, diffraction, and interference. Maxwell's theory
and Hertz's experiments led directly to the development of modern radio,
radar, television, electromagnetic imaging, and wireless
communications.
In the quantum theory, photons are seen as wave packets
of the waves described in the classical theory of Maxwell. The quantum
theory was needed to explain effects even with visual light that
Maxwell's classical theory could not (such as spectral lines).
Quantum theory
In 1900 Max Planck, attempting to explain black body radiation
suggested that although light was a wave, these waves could gain or
lose energy only in finite amounts related to their frequency. Planck
called these "lumps" of light energy "quanta" (from a Latin word for
"how much"). In 1905, Albert Einstein used the idea of light quanta to
explain the photoelectric effect, and suggested that these light quanta had a "real" existence. In 1923 Arthur Holly Compton showed that the wavelength shift seen when low intensity X-rays scattered from electrons (so called Compton scattering) could be explained by a particle-theory of X-rays, but not a wave theory. In 1926 Gilbert N. Lewis named these light quanta particles photons.
Eventually the modern theory of quantum mechanics came to picture light as (in some sense) both a particle and a wave, and (in another sense), as a phenomenon which is neither
a particle nor a wave (which actually are macroscopic phenomena, such
as baseballs or ocean waves). Instead, modern physics sees light as
something that can be described sometimes with mathematics appropriate
to one type of macroscopic metaphor (particles), and sometimes another
macroscopic metaphor (water waves), but is actually something that
cannot be fully imagined. As in the case for radio waves and the X-rays
involved in Compton scattering, physicists have noted that
electromagnetic radiation tends to behave more like a classical wave at
lower frequencies, but more like a classical particle at higher
frequencies, but never completely loses all qualities of one or the
other. Visible light, which occupies a middle ground in frequency, can
easily be shown in experiments to be describable using either a wave or
particle model, or sometimes both.
In February 2018, scientists reported, for the first time, the discovery of a new form of light, which may involve polaritons, that could be useful in the development of quantum computers.