A laser is a device that uses light flashes to excite the atoms

In summary, a laser is a device that uses light flashes to excite atoms and create a population inversion in a gain material. This process, called pumping, results in an optical gain due to stimulated emission. The emitted photons vibrate at a particular frequency and are reflected off a half silvered mirror. The laser is designed to have most of the energy targeted towards a specific energy level, and although atoms may have multiple electrons in their outer shell, the laser works because the excitation process is tailored to the desired level. The emission spectrum of a laser is broadened due to the uncertainty principle and the finite lifetime of the upper state of the atoms in the gain medium. This broadening is typically about 8 MHz and is a result of
  • #1
garytse86
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A laser is a device that uses light flashes to excite the atoms so you get electrons with energy levels about 2 or 3 levels above the ground state. They emit photons, which vibrate at a particular frequency, they get reflected off the half silvered mirror, to excite electrons and make them emit pohtons at the same frequency. So the wavelength of the laser is just one, nothing else, but surely an atom has got more than one electron in the outer shell, wouldn't this cause a problem because either the atom would emit photons with different frequencies, because two particles in the same atom cannot be at the same state, according to the exclusion principle.
 
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  • #2
There are two issues here.
The second, having to do with the exclusion principle, is irrelevant, since each atom has only one electron in the upper state. The laser works because there are a lot of atoms, in the medium of interest, which have been excited.
The first issue, about possible other excited states, is a function of how the excitation takes place. Lasers are designed so that most of the energy, used in the excitation, is tailored to the particlular level desired.
 
  • #3
A laser works by establishing a population inversion in some gain material. The process of creating a population inversion is called pumping. Lasers can be pumped with bright flashlamps, other lasers, chemicals, electricity etc.

When a population inversion is established, the material gives an optical gain. This is due to the process of stimulated emission resulting in an avalanche effect. Feedback increases this effect.

Lasers do not emit at a distinct frequency, the emission spectrum is broadened due to the uncertainty principle and the finite lifetime of the upper state of the atoms in the gain medium. Typical broadening is about 8 MHz.

Two electron systems do exhibit some energy splitting on their own, however in a medium with lots of atoms, energy levels broaden into energy bands. This manifests itself as the spectrum broadening mention above.
 

What is a laser?

A laser is a device that uses light flashes to excite the atoms in a medium, causing them to emit coherent light in a specific direction and wavelength.

How does a laser work?

A laser works by using a medium, such as a gas, liquid, or solid, to create a population inversion of atoms. This means that more atoms are in an excited state than in a ground state. When an external energy source, such as an electrical current or another laser, is introduced, it causes the excited atoms to release energy in the form of photons. These photons bounce back and forth between mirrors within the laser, amplifying and aligning in a specific direction to create a powerful beam of light.

What are the main components of a laser?

The main components of a laser include a medium, such as a gas, liquid, or solid, an energy source, such as an electrical current or another laser, mirrors to reflect and amplify the light, and a cavity to contain and direct the light in a specific direction.

What are some common applications of lasers?

Lasers have a wide range of applications in various industries, including telecommunications, medicine, manufacturing, and research. Some common uses of lasers include cutting and welding materials, performing delicate surgeries, reading barcodes, and measuring distances in surveying and construction.

What are the advantages of using a laser over other light sources?

Compared to other light sources, lasers have several advantages, including high intensity, coherence (which means the light waves are all in phase with each other), and directionality. These qualities make lasers useful in applications where precision and control are important, such as in surgery and manufacturing processes.

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