of waves of
photons (
light) by a prism]]
The science of photonics includes the generation, emission, transmission, modulation, signal processing, switching, amplification, detection and sensing of light. The term photonics thereby emphasizes that photons are neither particles nor waves — they are different in that they have both particle and wave nature. It covers all technical applications of light over the whole spectrum from ultraviolet over the visible to the near-, mid- and far-infrared. Most applications, however, are in the range of the visible and near infrared light. The term photonics developed as an outgrowth of the first practical semiconductor light emitters invented in the early 1960s and optical fibers developed in the 1970s.
History of photonics
The word 'photonics' appeared in the late 1960s to describe a research field whose goal was to use light to perform functions that traditionally fell within the typical domain of electronics, such as telecommunications, information processing, etc.
Photonics as a field began with the invention of the laser in 1960. Other developments followed: including the laser diode in the 1970s, optical fibers for transmitting information, and the Erbium-doped fiber amplifier. These inventions formed the basis for the telecommunications revolution of the late 20th century and provided the infrastructure for the Internet.
Though coined earlier, the term photonics came into common use in the 1980s as fiber-optic data transmission was adopted by telecommunications network operators. At that time, the term was used widely at Bell Laboratories. Its use was confirmed when the IEEE Lasers and Electro-Optics Society established an archival journal named Photonics Technology Letters at the end of the 1980s.
During the period leading up to the dot-com crash circa 2001, photonics as a field focused largely on telecommunications. However, photonics covers a huge range of science and technology applications, including: laser manufacturing, biological and chemical sensing, medical diagnostics and therapy, display technology, and optical computing.
Various non-telecom photonics applications exhibit strong growth, particularly since the dot-com crash, partly because many companies have been looking for new application areas. Further growth of photonics is likely if current silicon photonics developments are successful.
Relationship to other fields
Classical optics
Photonics is closely related to
optics. However optics preceded the discovery that light is quantized (when
Albert Einstein explained the
photoelectric effect in 1905). Optics tools include the refracting lens, the reflecting mirror, and various optical components known prior to 1900. Key tenets of classical optics, such as
Huygens Principle,
Maxwell's Equations, and wave equations, do not depend on quantum properties of light.
Modern optics
Photonics is related to
quantum optics,
optomechanics,
electro-optics,
optoelectronics and
quantum electronics. However each area has slightly different connotations by scientific and government communities and in the marketplace. Quantum optics often connotes fundamental research, whereas photonics is used to connote applied research and development.
The term photonics more specifically connotes:
The particle properties of light,
The potential of creating signal processing device technologies using photons,
The practical application of optics, and
An analogy to electronics.
The term optoelectronics connotes devices or circuits that comprise both electrical and optical functions, i.e., a thin-film semiconductor device. The term electro-optics came into earlier use and specifically encompasses nonlinear electrical-optical interactions applied, e.g., as bulk crystal modulators such as the Pockels cell, but also includes advanced imaging sensors typically used for surveillance by civilian or government organizations.
Emerging fields
Photonics also relates to the emerging science of
quantum information in those cases where it employs photonic methods. Other emerging fields include
opto-atomics, in which devices integrate both photonic and atomic devices for applications such as precision timekeeping, navigation, and metrology;
polaritonics, which differs from photonics in that the fundamental information carrier is a
polariton, which is a mixture of photons and
phonons, and operates in the range of frequencies from 300
gigahertz to approximately 10
terahertz.
Applications
, a sea mouse, showing colorful spines, a remarkable example of photonic engineering by a living organism]]
Applications of photonics are ubiquitous. Included are all areas from everyday life to the most advanced science, e.g. light detection, telecommunications, information processing, lighting, metrology, spectroscopy, holography, medicine (surgery, vision correction, endoscopy, health monitoring), military technology, laser material processing, visual art, biophotonics, agriculture, and robotics.
Just as applications of electronics have expanded dramatically since the first transistor was invented in 1948, the unique applications of photonics continue to emerge. Economically important applications for semiconductor photonic devices include optical data recording, fiber optic telecommunications, laser printing (based on xerography), displays, and optical pumping of high-power lasers. The potential applications of photonics are virtually unlimited and include chemical synthesis, medical diagnostics, on-chip data communication, laser defense, and fusion energy, to name several interesting additional examples.
Consumer equipment: barcode scanner, printer, CD/DVD/Blu-ray devices, remote control devices
Telecommunications: optical fiber communications, optical down converter to microwave
Medicine: correction of poor eyesight, laser surgery, surgical endoscopy, tattoo removal
Industrial manufacturing: the use of lasers for welding, drilling, cutting, and various methods of surface modification
Construction: laser leveling, laser rangefinding, smart structures
Aviation: photonic gyroscopes lacking mobile parts
Military: IR sensors, command and control, navigation, search and rescue, mine laying and detection
Entertainment: laser shows, beam effects, holographic art
Information processing
Metrology: time and frequency measurements, rangefinding
Photonic computing: clock distribution and communication between computers, printed circuit boards, or within optoelectronic integrated circuits; in the future: quantum computing
Overview of photonics research
The science of photonics includes investigation of the
emission,
transmission,
amplification,
detection, and
modulation of light.
Light sources
Light sources used in photonics are usually more sophisticated than
light bulbs. Photonics commonly uses semiconductor light sources like
light-emitting diodes (LEDs),
superluminescent diodes, and
lasers. Other light sources include
fluorescent lamps,
cathode ray tubes (CRTs), and
plasma screens. Note that while CRTs, plasma screens, and
organic light-emitting diode displays generate their own light,
liquid crystal displays (LCDs) like
TFT screens require a
backlight of either
cold cathode fluorescent lamps or, more often today, LEDs.
Characteristic for research on semiconductor light sources is the frequent use of III-V semiconductors instead of the classical semiconductors like silicon and germanium. This is due to the special properties of III-V semiconductors that allow for the implementation of light emitting devices. Examples for material systems used are gallium arsenide (GaAs) and aluminium gallium arsenide (AlGaAs) or other compound semiconductors. They are also used in conjunction with silicon to produce hybrid silicon lasers.
Transmission media
Light can be transmitted through any
transparent medium.
Glass fiber or
plastic optical fiber can be used to guide the light along a desired path. In
optical communications optical fibers allow for
transmission distances of more than 100 km without amplification depending on the bit rate and modulation format used for transmission. A very advanced research topic within photonics is the investigation and fabrication of special structures and "materials" with engineered optical properties. These include
photonic crystals,
photonic crystal fibers and
metamaterials.
Amplifiers
Optical amplifiers are used to amplify an optical signal. Optical amplifiers used in optical communications are
erbium-doped fiber amplifiers,
semiconductor optical amplifiers,
Raman amplifiers and
optical parametric amplifiers. A very advanced research topic on optical amplifiers is the research on
quantum dot semiconductor optical amplifiers.
Detection
Photodetectors detect light. Photodetectors range from very fast
photodiodes for communications applications over medium speed charge coupled devices (
CCDs) for
digital cameras to very slow
solar cells that are used for
energy harvesting from
sunlight. There are also many other photodetectors based on thermal,
chemical, quantum,
photoelectric and other effects.
Modulation
Modulation of a light source is used to encode information on a light source. Modulation can be achieved by the light source directly. One of the easiest examples is to use a
flashlight to send
Morse code. Another method is to take the light from a light source and modulate it in an external
optical modulator.
An additional topic covered by modulation research is the modulation format. On-off keying has been the commonly used modulation format in optical communications. In the last years more advanced modulation formats like phase-shift keying or even orthogonal frequency-division multiplexing have been investigated to counteract effects like dispersion that degrade the quality of the transmitted signal.
Photonic systems
Photonics also includes research on photonic systems. This term is often used for
optical communication systems. This area of research focuses on the implementation of photonic systems like high speed photonic networks. This also includes research on
optical regenerators, which improve optical signal quality.
See also
;Related topics
Biophotonics
Holography
Microphotonics
Nano-optics
Optics
Optronics
Photonic crystal
Photonic crystal fiber
Photonics mast
Quantum optics
Solar cell
Photonic computer
;Industry consortia
European Photonics Industry Consortium
Photonics21 - a voluntary association of industrial enterprises and other stakeholders in the field of photonics in Europe.
References
External links
;International Optical Societies:
EOS - European Optical Society
EPIC - The European Photonics Industry Consortium
OSA - Optical Society of America
IEEE Photonics Society
SPIE - The International Society for Optical Engineering
;National Optical Societies
OP-TEC - National Science Foundation's National Center for Optics and Photonics Education
Photonics Cluster Netherlands - The Internet Portal of the Dutch Photonics Society
;Regional Photonics Associations
CPIA - Colorado Photonics Industry Association
;Periodicals
Photonics Spectra
Laser Focus World
Electro Optics
Optics & Photonics Focus
Optics & Laser Europe
Nature Photonics
Photonics news
Industrial Laser Solutions
Photonics Online
;Research Networks
EURO-FOS - Europe's Research Network on Photonic Systems
ePIXnet - European Network of Excellence on Photonic Integrated Components and Circuits
BONE - Building the Future Optical Network in Europe
Category:Optics
![The cosmic microwave background spectrum measured by the FIRAS instrument on the COBE satellite is the most-precisely measured black body spectrum in nature.[3] The data points and error bars on this graph are obscured by the theoretical curve.](http://web.archive.org./web/20110825031740im_/http://cdn7.wn.com/pd/00/79/b4c763b16f2e6fe14a8e66d990f5_grande.jpg "The cosmic microwave background spectrum measured by the FIRAS instrument on the COBE satellite is the most-precisely measured black body spectrum in nature.[3] The data points and error bars on this graph are obscured by the theoretical curve.")
![The cosmic microwave background spectrum measured by the FIRAS instrument on the COBE satellite is the most-precisely measured black body spectrum in nature.[3] The data points and error bars on this graph are obscured by the theoretical curve.](http://web.archive.org./web/20110825031740im_/http://cdn6.wn.com/pd/00/79/b4c763b16f2e6fe14a8e66d990f5_thumb.jpg "The cosmic microwave background spectrum measured by the FIRAS instrument on the COBE satellite is the most-precisely measured black body spectrum in nature.[3] The data points and error bars on this graph are obscured by the theoretical curve.")
