Can cooling lasers extract energy and reach absolute zero?

In summary, the Doppler effect is a phenomenon that causes an atom to experience a force in one direction or the other depending on its velocity. This force can be used to stop an atom from moving.
  • #1
Pseudo Epsilon
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i mean to say how does this method extract energy, I've read the wiki but in my head it seems as though you can only extract as much energy you put in and why can't we use this to get to absolute zero?
 
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  • #2
If the laser is slightly red-detuning from an atomic transitions, meaning that the energy of one photon is less than necessary for the transition, you still have a non-zero probability of the atom absorbing that photon. But the emitted photon will be at the energy of the transition, and therefore part of the energy of the atom will be transferred to the emitted photons. By a clever use of the Doppler effect, and laser beams coming from 6 directions (in 3D), you can get a pretty cold gas of atoms.

There are inherent limits to how low this can cool down atoms, the most fundamental being the "recoil temperature", corresponding to the recoil of atom originally at rest will get following the emission of one photon.
 
  • #3
why does the doppler efect have to do with it?
 
  • #5
Consider one laser propagating along the +z direction. By conservation of momentum, when an atom absorbs a photon of that laser, its momentum along +z increases. After emission, the atom's momentum changes, but because emission is isotropic, the average effect will correspond to a force directed along +z.

The absorption-emission of photons I described is called photon scattering. The rate at which this scattering occurs depends on the detuning of the laser: the closer it is to resonance, the higher the scattering rate. So an atom traveling in the -z direction of that red-detuned laser will see the light as closer to resonance because of the Doppler effect. The force on the atom will be bigger.

Now take two lasers with the same red detuning, one propagation along +z and the other along -z. An atom at rest will scatter photons at the same rate from both lasers. But if it is traveling in the -z direction, it will scatter more photons from the +z laser than from the -z, so it will feel a pressure towards +z, that is, a stopping force. The converse happens if it is traveling in the other direction. Therefore, both lasers act to stop the atom, because of the Doppler effect.
 

1. How do cooling lasers work?

Cooling lasers work by using a process called laser cooling, which involves using light to control the temperature of a material or system. This is achieved by using specific wavelengths of light to slow down and trap particles, resulting in a decrease in their kinetic energy and thus a reduction in temperature.

2. What is the purpose of cooling lasers?

The purpose of cooling lasers is to cool down materials or systems to extremely low temperatures, typically close to absolute zero. This is useful for many scientific experiments, such as studying quantum mechanics and creating Bose-Einstein condensates, as well as for practical applications like creating more efficient computer processors.

3. How do scientists control the temperature using cooling lasers?

To control the temperature using cooling lasers, scientists use a technique called optical molasses. This involves directing multiple laser beams at the material or system from different directions, creating a force that slows down the particles and traps them in a small region. By adjusting the intensity and direction of the laser beams, scientists can control the temperature of the material or system.

4. Are there different types of cooling lasers?

Yes, there are different types of cooling lasers that use different methods to achieve laser cooling. The most common types are Doppler cooling, which uses the Doppler effect to slow down particles, and Sisyphus cooling, which uses a series of laser pulses to trap and cool particles. There are also more advanced techniques like evaporative cooling and sympathetic cooling.

5. What are the limitations of cooling lasers?

The main limitation of cooling lasers is that they can only cool down certain types of particles, such as atoms and ions. They are not effective for cooling larger objects or materials with complex structures. Additionally, achieving extremely low temperatures requires very precise and expensive equipment, making it difficult to scale up for practical applications.

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