Yes, the original Chinese name of laser is "laser". 1964, according to the suggestion of Qian Xuesen, a famous scientist in China, "stimulated emission of light" was renamed as "laser".

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Laser power generation

If microscopic particles such as atoms or molecules have a high energy level E2 and a low energy level E 1, and the particle number densities of E2 and E 1 are N2 and N 1, there are three processes: spontaneous emission transition, stimulated emission transition and stimulated absorption transition. Stimulated emission light generated by stimulated emission transition has the same frequency, phase, propagation direction and polarization direction as incident light. So the stimulated emission of a large number of particles excited by the same coherent radiation field is coherent. The probability of stimulated emission transition and stimulated emission absorption transition is proportional to the monochromatic energy density of the incident radiation field. When the statistical weights of the two energy levels are equal, the probabilities of the two processes are equal. In the case of thermal equilibrium, N2 < N 1, so the stimulated absorption transition is dominant, and light usually attenuates due to stimulated absorption when passing through matter. The excitation of external energy can destroy the thermal balance and make N2 > N 1, which is called the population inversion state. In this case, stimulated emission transition is dominant. After the light passes through the laser working substance (active substance) with the length of L, the light intensity increases by eGl times. G is a coefficient directly proportional to (N2-N 1), which is called gain coefficient, and its size is also related to the properties of laser working medium and light wave frequency. One active substance is a laser amplifier.

If an activated substance is placed in an optical resonator composed of two parallel mirrors (at least one of which is partially transmissive) (Figure 1), high-energy particles will spontaneously emit in all directions. Among them, non-axial light waves quickly escape from the resonant cavity; The axial light wave can propagate back and forth in the cavity, and the intensity increases when it propagates in the laser material. If the unidirectional small signal gain G0l in the resonant cavity is greater than the unidirectional loss δ(G0l is the small signal gain coefficient), self-excited oscillation can occur. The motion state of atoms can be divided into different energy levels. When an atom jumps from a high energy level to a low energy level, it will release photons with corresponding energy (so-called spontaneous emission). Similarly, when a photon is incident on an energy-level system and absorbed by it, it will cause the atom to jump from a low energy level to a high energy level (so-called stimulated absorption); Then, some atoms that jump to the high energy level will jump to the low energy level and release photons (so-called stimulated radiation). These movements are not isolated, but often carried out simultaneously. When we create a condition, such as using a suitable medium, * * * cavity and enough external electric field, stimulated radiation will be amplified to be greater than stimulated absorption, then in general, photons will be emitted, thus generating laser.

Characteristics of laser

(1) directional luminescence

Ordinary light sources emit light in all directions. In order to make the emitted light spread in one direction, it is necessary to install a certain condensing device on the light source. For example, headlights and searchlights of automobiles are equipped with reflectors with light gathering function, so that the radiated light can be collected and emitted in one direction. The laser emitted by the laser is naturally emitted in one direction, and the divergence of the beam is extremely small, only about 0.00 1 radian, which is close to parallel. 1962, man irradiated the moon with laser for the first time. The distance between the earth and the moon is about 380,000 kilometers, but the laser spot on the surface of the moon is less than two kilometers. If the focusing effect is good, the seemingly parallel searchlight beam will be aimed at the moon and cover the whole moon according to its spot diameter.

(2) Very high brightness

Before the invention of laser, the brightness of high-voltage pulsed xenon lamp in artificial light source is the highest, which is equivalent to the brightness of the sun, while the laser brightness of ruby laser can exceed tens of billions of times that of xenon lamp. Because the brightness of laser is extremely high, it can illuminate distant objects. The illumination produced by ruby laser beam on the moon is about 0.02 lux (illumination unit), and the color is bright red, and the laser spot is obviously visible. If the strongest searchlight is used to illuminate the moon, the illumination produced is only about one trillionth lux, which is impossible for human eyes to detect. The main reason of high laser brightness is directional light emission. A large number of photons are emitted in a very small space, and the energy density is naturally extremely high.

(3) the color is extremely pure

The color of light is determined by the wavelength (or frequency) of light. A certain wavelength corresponds to a certain color. The wavelength distribution range of sunlight is about 0.76 micron to 0.4 micron, and the corresponding colors range from red to purple, so sunlight is not monochromatic. A light source that emits a single color light is called a monochromatic light source, and the light wave it emits has a single wavelength. Such as krypton lamp, helium lamp, neon lamp, hydrogen lamp, etc. All are monochromatic light sources, which only emit light of a certain color. Although monochromatic light source has a single wavelength, it still has a certain distribution range. For example, krypton lamp only emits red light, which is said to have the highest monochromaticity, and the wavelength distribution range is still 0.000 1 nm, so the red light emitted by krypton lamp still contains dozens of reds if carefully identified. It can be seen that the narrower the wavelength distribution range of optical radiation, the better the monochromaticity.

The wavelength distribution range of the light output by the laser is very narrow, so the color is extremely pure. Take the He-Ne laser which outputs red light as an example, its wavelength distribution range can be as narrow as 2× 10-9 nm, which is two ten thousandths of the wavelength distribution range of red light emitted by krypton lamp. The monochromaticity of visible laser far exceeds that of any monochromatic light source.

In addition, laser has other characteristics: good coherence. The frequency, vibration direction and phase of laser are highly consistent, so when laser light waves overlap in space, the light intensity distribution in the overlapping area will appear stable phenomenon of alternating strength. This phenomenon is called interference of light, so laser is coherent light. The light emitted by a common light source is called incoherent light because its frequency, vibration direction and phase are inconsistent.

The flash time can be very short. Due to technical reasons, the flash time of ordinary light source can not be very short, and the flash time of photographic flash is about one thousandth of a second. The flash time of pulsed laser is very short, reaching 6 femtoseconds (1 femtosecond = 10- 15 seconds). The light source with extremely short flash time has important uses in production, scientific research and military affairs.

Be irradiated by laser

What is "stimulated radiation"? It is based on a brand-new theory put forward by the great scientist Einstein in 19 16. This theory means that there are different numbers of particles (electrons) distributed in different energy levels in the atoms that make up matter. When a high-level particle is excited by a photon, it will jump from the high-level to the low-level level. At this time, they will emit light with the same properties as the light that excites them, and in a certain state, weak light can also excite strong light. This is called "optical amplification of stimulated radiation", or laser for short. Laser has four main characteristics: high brightness, high directivity, high monochromaticity and high coherence.

At present, laser has been widely used in laser welding, laser cutting and laser drilling (including oblique holes, irregular holes, gypsum holes, tipping paper holes, steel plate holes, packaging and printing holes, etc.). ), laser quenching, laser heat treatment, laser marking, glass carving, laser fine adjustment, laser lithography, laser film making, laser film processing, laser packaging, laser circuit repair, laser wiring technology, laser cleaning, etc.

After more than 30 years of development, lasers are almost everywhere now. It has been used in all aspects of life and scientific research: laser acupuncture, laser cutting, laser welding, laser quenching, CD, laser rangefinder, laser gyroscope, laser straightener, laser scalpel, laser bomb, laser radar, laser gun, laser cannon and so on. In the near future, lasers will definitely be more widely used.

Laser weapon is a kind of directional energy weapon, which directly destroys or paralyzes the target by using directional laser beam. According to different operational purposes, laser weapons can be divided into tactical laser weapons and strategic laser weapons. The weapon system is mainly composed of laser, tracking, aiming and launching devices. At present, the commonly used lasers are chemical lasers, solid-state lasers and CO2 lasers. Laser weapons have the advantages of fast attack speed, flexible steering, accurate attack and no electromagnetic interference, but they are also vulnerable to weather and environment. Laser weapon has a history of more than 30 years, and its key technology has also made a breakthrough. The United States, Russia, France, Israel and other countries have successfully carried out various laser shooting experiments. At present, low-energy laser weapons have been put into use, mainly used for short-range interference and blinding photoelectric sensors, as well as attacking human eyes and some enhanced observation equipment; High-energy laser weapons mainly use chemical lasers. According to the current level, it is expected to be deployed and used on ground and air platforms in the next 5- 10 years for tactical air defense, theater anti-missile and anti-satellite operations.

Other characteristics of laser

Laser has many characteristics: first, laser is monochromatic, or single frequency. Some lasers can produce lasers with different frequencies at the same time, but these lasers are isolated from each other and used separately. Secondly, the laser is coherent light. The characteristic of coherent light is that all its light waves are synchronous, and the whole beam of light is like a "wave train". Thirdly, laser is highly concentrated, that is, it needs a long distance to disperse or converge.

Laser is a kind of light source invented in 1960s. Laser is the abbreviation of stimulated emission amplification in English. There are many kinds of lasers, ranging in size from several football fields to a grain of rice or salt. Gas lasers include He-Ne lasers and argon lasers; Solid-state lasers include ruby lasers; Semiconductor lasers have laser diodes, such as CD players, DVD players and laser diodes in CD-ROMs. Each laser has its own unique method of generating laser.

Application of laser technology

Laser machining technology is a technology that uses the characteristics of the interaction between laser beam and substance, and takes cutting, welding, surface treatment, drilling, micromachining materials and identifying objects as light sources. The most traditional application field is laser processing technology. Laser technology is a comprehensive technology involving optics, mechanics, electricity, materials, detection and other disciplines. Traditionally, its research scope can be generally divided into:

Laser processing system. Comprise a laser, a light guide system, a processing machine tool, a control system and a detection system.

2. Laser processing technology. Including cutting, welding, surface treatment, drilling, marking, marking, fine tuning and other processing technologies.

Laser welding: automobile body thick plates, automobile parts, lithium batteries, pacemakers, sealed relays and other sealing devices, as well as various devices that are not allowed to weld pollution and deformation. At present, the lasers used are YAG laser, CO2 laser and semiconductor pump laser.

Laser cutting: cutting all kinds of metal parts and special materials in automobile industry, computer, electrical cabinet and woodworking tool mould industry, circular saw blade, acrylic, spring washer, copper plate of electronic parts below 2mm, partial metal mesh plate, steel pipe, tinned iron plate, lead-plated steel plate, phosphor bronze, bakelite plate, thin aluminum alloy, timely glass, silicone rubber and alumina ceramic plate 1mm or less. The lasers used are YAG laser and CO2 laser.

Laser marking: widely used in various materials and almost all industries. At present, the lasers used are YAG laser, CO2 laser and semiconductor pump laser.

Laser drilling: Laser drilling is mainly used in aerospace, automobile manufacturing, electronic instruments, chemical industry and other industries. The rapid development of laser drilling is mainly reflected in the increase of the average output power of YAG laser for drilling from 400w five years ago to 800w, reaching1000 W. At present, the more mature application of laser drilling in China is in the production of synthetic diamond and natural diamond wire drawing dies, as well as the production of gem bearings in industries such as clock instruments, aircraft blades and multilayer printed circuit boards. At present, most of the lasers used are YAG lasers and CO2 lasers, but there are also some excimer lasers, isotope lasers and semiconductor pump lasers.

Laser heat treatment: widely used in automobile industry, such as heat treatment of cylinder liner, crankshaft, piston ring, commutator, gear and other parts, as well as aerospace, machine tool industry and other mechanical industries. Laser heat treatment is widely used in China than abroad. At present, most of the lasers used are YAG laser and CO2 laser.

Laser rapid prototyping: it is formed by combining laser processing technology with computer numerical control technology and flexible manufacturing technology. Mostly used in mold and model industry. At present, most of the lasers used are YAG laser and CO2 laser.

Laser coating: widely used in aerospace, mold and electromechanical industries. At present, most of the lasers used are high-power YAG lasers and CO2 lasers.

Scientists at the University of Texas have developed the most powerful operating laser in the world. This laser generates 2000 times more energy per trillionth of a second than all power plants in the United States, and its output power exceeds 1 picowatt-equivalent to 10/5 watt. This laser was first started by 1996. Martinez said that he hopes his project can break this record in 2008, that is, make the laser power reach between 1.3 picowatts and 1.5 picowatts. McAll Martinez, the head of the super laser project, said: "We can make materials enter an extreme state, which is invisible on the earth. The phenomenon we intend to observe in Texas is equivalent to entering space to observe an exploding star. "

Application of laser in medicine

Laser system applied to dentistry

According to the different functions of laser in dental application, it can be divided into several different laser systems. An important feature of distinguishing lasers is that the wavelength of light has different effects on tissues. Visible light and near infrared spectrum have low light absorption rate and strong penetration, and can penetrate deep tooth tissues, such as argon ion laser, diode laser or Nd: YAG laser (as shown in figure 1). However, Er: YAG laser and CO laser have poor light penetration, which can only penetrate the tooth tissue by about 0.01mm.. The second important feature that distinguishes laser is the intensity (i.e. power) of laser. For example, diode laser used for diagnosis is only a few milliwatts, and sometimes it can also be used for laser display.

The laser used for treatment is usually a moderate intensity laser of several watts. The effect of laser on tissue also depends on the way of laser pulse emission. Typical continuous pulse emission methods are argon ion laser, diode laser, CO2 laser and laser. Some Er: YAG lasers or many Nd: YAG lasers emit in short pulses. The intensity (i.e. power) of short-pulse laser can reach more than 1 1,000 watts. These high intensity and high light absorption lasers are only suitable for removing hard tissues.

Application of laser in the diagnosis of dental caries

1. Demineralization and shallow caries

2. Recessive dental caries

Application of laser in treatment

1. Cut

2. Filler polymerization and pit treatment

Laser cosmetic surgery

(1) Laser is widely used in beauty industry. Laser produces monochromatic light with high energy, accurate focus and certain penetrating power, which acts on human tissues to produce high fever, thus cutting or destroying target tissues. Pulsed laser with different wavelengths can treat various vascular dermatoses and pigmentation, such as nevus OTA, nevus flammeus, freckles, senile plaque, telangiectasia, tattoo removal, eyeliner washing, eyebrow washing and scar treatment. In recent years, some new laser instruments, such as high-energy ultra-pulse CO2 laser, erbium laser, etc., have achieved good results in wrinkle removal, peeling and skin replacement, snoring treatment, tooth whitening and so on, which has opened up more and more broad fields for laser surgery.

(2) Laser surgery has incomparable advantages over traditional surgery. First of all, laser surgery does not require hospitalization, with small incision, no bleeding during operation, light trauma and no scars. For example, the traditional surgical treatment of bags under the eyes has many shortcomings, such as wide peeling range, more bleeding during operation, slow healing after operation and easy scarring. The application of high-energy ultra-pulse CO2 laser in the treatment of eye bags has the advantages of no bleeding, no suture, no influence on normal work, light edema at the surgical site, quick recovery and no scar left, which is incomparable to traditional surgery. Some endoscopic operations that cannot be performed due to excessive bleeding can be completed by laser cutting instead. (Note: There is a certain range of adaptation)

(3) Laser has achieved remarkable results in the treatment of vascular dermatosis and pigmentation. The treatment of port wine nevus with pulsed dye laser has obvious curative effect, little damage to surrounding tissues and almost no scar. Its appearance has become a revolution in the history of treatment of port wine stains, because in the history of treatment of port wine stains, radiation, freezing, electrocautery, surgery and other methods have a high incidence of scars, and pigment loss or deposition often occurs. Laser treatment of vascular dermatosis is the selective absorption of oxygen-containing hemoglobin to a certain wavelength of laser, which leads to the high destruction of vascular tissue. It has high accuracy and safety, and will not affect the surrounding adjacent organizations. Therefore, laser treatment of telangiectasia is also effective.

In addition, due to the appearance of variable pulse laser, great breakthroughs have been made in removing unsatisfactory tattoos and treating various pigmented skin diseases such as OTA nevus and senile plaques. According to the theory of selective photothermal effect (that is, lasers with different wavelengths can selectively act on skin lesions of different colors), this kind of laser uses its powerful instantaneous power, highly concentrated radiation energy, pigment selectivity and extremely short pulse width to concentrate laser energy on pigment particles, vaporize and crush them directly, and excrete them through lymphatic tissues without affecting the surrounding normal tissues, which is deeply rooted in people's hearts because of its exact curative effect, safety and reliability, no scar and little pain.

(4) Laser surgery initiated a new era of medical beauty. High-energy ultra-pulse CO2 laser peeling and skin changing has opened up a new technology in cosmetic surgery. It uses high-energy, ultra-short pulse laser to vaporize the damaged skin tissue instantly, without damaging the surrounding tissues, with almost no bleeding during the treatment, and can accurately control the depth of action. Its effect has been fully affirmed by the international medical plastic surgery field, and it is known as "creating a new era of medical beauty"; In addition, there is a high-energy ultra-pulse CO2 laser instrument to treat bags under the eyes, snoring, and even laser whitening teeth. With its safe and accurate curative effect and simple and quick treatment, it has created one miracle after another in the field of medical beauty. Laser cosmetology has made medical cosmetology take a big step forward and given the connotation of medical cosmetology renewal.

Laser cooling

Laser cooling is to use the interaction between laser and atoms to slow down the motion of atoms, so as to obtain ultra-low temperature atoms. In the early days, the main purpose of this important technology was to accurately measure various atomic parameters for high-resolution laser spectrum and ultra-high-precision quantum frequency standard (atomic clock), but later it became the key experimental method to realize atomic Bose-Einstein condensation. Although people noticed that light had radiation pressure on atoms as early as the beginning of the 20th century, it was not until the invention of laser that the technology of changing the speed of atoms by using light pressure was developed. It is found that when an atom moves in a pair of laser beams with a frequency slightly lower than the energy level difference of the atomic transition and propagating in opposite directions, due to the Doppler effect, the atom tends to absorb photons in the opposite direction to the atom, but the probability of absorbing photons propagating in the same direction is small. The absorbed photons will spontaneously radiate isotropically. On average, the net effect of two lasers is to produce a damping force opposite to the direction of atomic motion, thus slowing down the movement of atoms (that is, cooling down). 1985, Phillips of the National Institute of Standards and Technology and Steven Chu of Stanford University first realized the experiment of laser cooling atoms, and obtained the extremely low temperature (24μK) sodium gas. They further used a three-dimensional laser beam to form magneto-optical theory, trapped atoms in a small area of space and cooled them, and obtained "optical viscose" with lower temperature. Since then, many new laser cooling methods have appeared. Among them, the most famous ones are "velocity selective coherent population limitation" and "Raman cooling". The former was put forward by Claude Cohen-Tannoji of Paris Teachers College, while the latter was put forward by Zhu. They used this technology to obtain extremely low temperatures below the photon recoil limit. Since then, people have developed a series of cooling technologies combining magnetic field and laser, including polarization gradient cooling and magnetic induction cooling. Zhu, Cohen Danoki and Phillips also won the 1997 Nobel Prize in Physics. Laser cooling has many applications, such as atomic optics, atomic etching, atomic clock, optical lattice, optical tweezers, Bose-Einstein condensation, atomic laser, high-resolution spectroscopy, and basic research on the interaction between light and matter.

Laser spectrum

Laser spectroscopy is a spectral technology with laser as light source. Compared with ordinary light sources, laser light source has the characteristics of good monochromaticity, high brightness, strong directivity and strong coherence, and is an ideal light source to study the interaction between light and matter, so as to identify the structure, composition, state and change of matter and its system. The appearance of laser greatly improves the sensitivity and resolution of the original spectral technology. Because of the extremely high intensity and narrow pulse width of laser, it is possible to observe the multiphoton process, nonlinear photochemical process and relaxation process of molecules after excitation, and they have developed into new spectral technologies respectively. Laser spectroscopy has become a research field closely related to physics, chemistry, biology and materials science.

Laser sensor

Laser sensor is a kind of sensor that uses laser technology to measure. It consists of a laser, a laser detector and a measuring circuit. Laser sensor is a new type of measuring instrument, which has the advantages of non-contact long-distance measurement, high speed, high precision, large measuring range and strong anti-photoelectric interference ability.

laser radar

Lidar refers to a radar that uses laser as a radiation source. Lidar is a combination of laser technology and radar technology. It consists of transmitter, antenna, receiver, tracking frame and information processing. Emitters are various types of lasers, such as carbon dioxide lasers, Nd-doped yttrium aluminum garnet lasers, semiconductor lasers and solid-state lasers with adjustable wavelengths. The antenna is an optical telescope; The receiver adopts various forms of photodetectors, such as photomultiplier tubes, semiconductor photodiodes, avalanche photodiodes, infrared and visible light multi-detector devices, etc. Lidar works in two modes: pulse or continuous wave. Detection methods are divided into direct detection and heterodyne detection.

Laser beam weapon

Laser weapon is a kind of directional energy weapon, which directly destroys or paralyzes the target by using directional laser beam. According to different operational purposes, laser weapons can be divided into tactical laser weapons and strategic laser weapons. The weapon system is mainly composed of laser, tracking, aiming and launching devices. At present, the commonly used lasers are chemical lasers, solid-state lasers and CO2 lasers. Laser weapons have the advantages of fast attack speed, flexible steering, accurate attack and no electromagnetic interference, but they are also vulnerable to weather and environment. Laser weapon has a history of more than 30 years, and its key technology has also made a breakthrough. The United States, Russia, France, Israel and other countries have successfully carried out various laser shooting experiments. At present, low-energy laser weapons have been put into use, mainly used for short-range interference and blinding photoelectric sensors, as well as attacking human eyes and some enhanced observation equipment; High-energy laser weapons mainly use chemical lasers. According to the current level, it is expected to be deployed and used on ground and air platforms in the next 5- 10 years for tactical air defense, theater anti-missile and anti-satellite operations.