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Nouveau texte de la page, après la modification (new_wikitext) | <br>Lasers are light sources concentrated by a mirror. The beam is then magnified to create the strongest light. This is referred to as laser. This article will explain the fundamental characteristics of a laser as well as the ways in that it can be used. It also covers how the beam is made, and how it is assessed. In this article, we'll explore some of the common kinds of lasers that are used in different applications. This will allow you to make a an informed choice in purchasing the right laser.<br><br><br>Theodore Maiman developed the first practical laser in 1922. However, lasers were not widely known until the 1960s, when the public began to realize their importance. The development of laser technology was showcased in James Bond's 1964 film Goldfinger. It featured industrial lasers that cut through objects and spy agents. The New York Times reported that Charles Townes was awarded the Nobel Prize in Physics in 1964. His work had been vital in the development of this technology. According to the newspaper, the first laser could carry all radio and television programs simultaneously as well as be used to track missiles.<br><br><br>The source of energy for the production of the laser is an excitation medium. The energy in the gain medium is what produces the laser's output. The excitation medium is typically the source of light that excites the atoms in the gain medium. To further stimulate the beam, an electrical field or light source could be employed. The energy source is strong enough to produce the desired light. The laser produced a steady and strong output when using a CO2 laser.<br><br><br>The excitation medium needs to generate enough pressure to allow the material to release light in order to produce the laser beam. During this process, the laser emits an energy beam. The laser then concentrates that energy into a small fuel pellet that melts at [http://lms.microsys.com.tw/blog/index.php?entryid=23242 high power green laser] temperatures, mimicking star's internal temperatures. Laser fusion is a technique which can generate a significant amount of energy. This technology is being researched by the Lawrence Livermore National Laboratory.<br><br><br>A laser's diameter is a measure of the width at the end of the laser housing. There are many ways to determine the size of a laser beam. For Gaussian beams, the diameter is defined as the distance between two points in an arbitrary distribution of identical intensity. The wavelength represents the maximum distance a ray can travel. In this case the wavelength of a beam is the distance between two points of the marginal distribution.<br><br><br>Laser fusion produces a beam of light by shining intense laser light onto tiny fuel pellets. This creates enormously high temperatures and large quantities of energy. This technology is currently being developed by Lawrence Livermore National Laboratory. A laser has the potential to create heat in many conditions. You can use it to generate electricity in a variety of ways, such as as a tool for cutting materials. In fact it can be an enormous benefit for medical professionals.<br><br><br>Lasers are devices that use mirrors to create light. The mirrors in a laser reflect light particles of a specific wavelength and bounce off them. A cascade effect can be created when electrons in semiconductors emit more photons. The wavelength of light is an important parameter in a laser. The wavelength of a photon is the distance between two points of a sphere.<br><br><br>The wavelength of laser beams is determined by wavelength and polarisation. The distance that the light travels is measured in length. The spectral spectrum of a laser is the radian frequency. The energy spectrum is a spherical version of light with an centered wavelength. The spectral spectrum is the distance that is between the optics of focusing as well as the expelled light. The angle of incidence is the distance from which light can leave a lens.<br><br><br>The laser beam's diameter is measured on its exit side. The atmospheric pressure and wavelength determine the size. The intensity of the beam is influenced by the angle at which it diverges. A narrower beam will produce more energy. Microscopy is a fan of a wider laser beam. It is easier to achieve higher precision with a wider range of lasers. There are many different wavelengths in the fiber.<br><br> |
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+<br>Lasers are light sources concentrated by a mirror. The beam is then magnified to create the strongest light. This is referred to as laser. This article will explain the fundamental characteristics of a laser as well as the ways in that it can be used. It also covers how the beam is made, and how it is assessed. In this article, we'll explore some of the common kinds of lasers that are used in different applications. This will allow you to make a an informed choice in purchasing the right laser.<br><br><br>Theodore Maiman developed the first practical laser in 1922. However, lasers were not widely known until the 1960s, when the public began to realize their importance. The development of laser technology was showcased in James Bond's 1964 film Goldfinger. It featured industrial lasers that cut through objects and spy agents. The New York Times reported that Charles Townes was awarded the Nobel Prize in Physics in 1964. His work had been vital in the development of this technology. According to the newspaper, the first laser could carry all radio and television programs simultaneously as well as be used to track missiles.<br><br><br>The source of energy for the production of the laser is an excitation medium. The energy in the gain medium is what produces the laser's output. The excitation medium is typically the source of light that excites the atoms in the gain medium. To further stimulate the beam, an electrical field or light source could be employed. The energy source is strong enough to produce the desired light. The laser produced a steady and strong output when using a CO2 laser.<br><br><br>The excitation medium needs to generate enough pressure to allow the material to release light in order to produce the laser beam. During this process, the laser emits an energy beam. The laser then concentrates that energy into a small fuel pellet that melts at [http://lms.microsys.com.tw/blog/index.php?entryid=23242 high power green laser] temperatures, mimicking star's internal temperatures. Laser fusion is a technique which can generate a significant amount of energy. This technology is being researched by the Lawrence Livermore National Laboratory.<br><br><br>A laser's diameter is a measure of the width at the end of the laser housing. There are many ways to determine the size of a laser beam. For Gaussian beams, the diameter is defined as the distance between two points in an arbitrary distribution of identical intensity. The wavelength represents the maximum distance a ray can travel. In this case the wavelength of a beam is the distance between two points of the marginal distribution.<br><br><br>Laser fusion produces a beam of light by shining intense laser light onto tiny fuel pellets. This creates enormously high temperatures and large quantities of energy. This technology is currently being developed by Lawrence Livermore National Laboratory. A laser has the potential to create heat in many conditions. You can use it to generate electricity in a variety of ways, such as as a tool for cutting materials. In fact it can be an enormous benefit for medical professionals.<br><br><br>Lasers are devices that use mirrors to create light. The mirrors in a laser reflect light particles of a specific wavelength and bounce off them. A cascade effect can be created when electrons in semiconductors emit more photons. The wavelength of light is an important parameter in a laser. The wavelength of a photon is the distance between two points of a sphere.<br><br><br>The wavelength of laser beams is determined by wavelength and polarisation. The distance that the light travels is measured in length. The spectral spectrum of a laser is the radian frequency. The energy spectrum is a spherical version of light with an centered wavelength. The spectral spectrum is the distance that is between the optics of focusing as well as the expelled light. The angle of incidence is the distance from which light can leave a lens.<br><br><br>The laser beam's diameter is measured on its exit side. The atmospheric pressure and wavelength determine the size. The intensity of the beam is influenced by the angle at which it diverges. A narrower beam will produce more energy. Microscopy is a fan of a wider laser beam. It is easier to achieve higher precision with a wider range of lasers. There are many different wavelengths in the fiber.<br><br>
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Lignes ajoutées lors de la modification (added_lines) | <br>Lasers are light sources concentrated by a mirror. The beam is then magnified to create the strongest light. This is referred to as laser. This article will explain the fundamental characteristics of a laser as well as the ways in that it can be used. It also covers how the beam is made, and how it is assessed. In this article, we'll explore some of the common kinds of lasers that are used in different applications. This will allow you to make a an informed choice in purchasing the right laser.<br><br><br>Theodore Maiman developed the first practical laser in 1922. However, lasers were not widely known until the 1960s, when the public began to realize their importance. The development of laser technology was showcased in James Bond's 1964 film Goldfinger. It featured industrial lasers that cut through objects and spy agents. The New York Times reported that Charles Townes was awarded the Nobel Prize in Physics in 1964. His work had been vital in the development of this technology. According to the newspaper, the first laser could carry all radio and television programs simultaneously as well as be used to track missiles.<br><br><br>The source of energy for the production of the laser is an excitation medium. The energy in the gain medium is what produces the laser's output. The excitation medium is typically the source of light that excites the atoms in the gain medium. To further stimulate the beam, an electrical field or light source could be employed. The energy source is strong enough to produce the desired light. The laser produced a steady and strong output when using a CO2 laser.<br><br><br>The excitation medium needs to generate enough pressure to allow the material to release light in order to produce the laser beam. During this process, the laser emits an energy beam. The laser then concentrates that energy into a small fuel pellet that melts at [http://lms.microsys.com.tw/blog/index.php?entryid=23242 high power green laser] temperatures, mimicking star's internal temperatures. Laser fusion is a technique which can generate a significant amount of energy. This technology is being researched by the Lawrence Livermore National Laboratory.<br><br><br>A laser's diameter is a measure of the width at the end of the laser housing. There are many ways to determine the size of a laser beam. For Gaussian beams, the diameter is defined as the distance between two points in an arbitrary distribution of identical intensity. The wavelength represents the maximum distance a ray can travel. In this case the wavelength of a beam is the distance between two points of the marginal distribution.<br><br><br>Laser fusion produces a beam of light by shining intense laser light onto tiny fuel pellets. This creates enormously high temperatures and large quantities of energy. This technology is currently being developed by Lawrence Livermore National Laboratory. A laser has the potential to create heat in many conditions. You can use it to generate electricity in a variety of ways, such as as a tool for cutting materials. In fact it can be an enormous benefit for medical professionals.<br><br><br>Lasers are devices that use mirrors to create light. The mirrors in a laser reflect light particles of a specific wavelength and bounce off them. A cascade effect can be created when electrons in semiconductors emit more photons. The wavelength of light is an important parameter in a laser. The wavelength of a photon is the distance between two points of a sphere.<br><br><br>The wavelength of laser beams is determined by wavelength and polarisation. The distance that the light travels is measured in length. The spectral spectrum of a laser is the radian frequency. The energy spectrum is a spherical version of light with an centered wavelength. The spectral spectrum is the distance that is between the optics of focusing as well as the expelled light. The angle of incidence is the distance from which light can leave a lens.<br><br><br>The laser beam's diameter is measured on its exit side. The atmospheric pressure and wavelength determine the size. The intensity of the beam is influenced by the angle at which it diverges. A narrower beam will produce more energy. Microscopy is a fan of a wider laser beam. It is easier to achieve higher precision with a wider range of lasers. There are many different wavelengths in the fiber.<br><br>
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