Editing Refrigeration (section)

===Fridge Gate===
The Fridge Gate method is a theoretical application of using a single logic gate to drive a refrigerator in the most energy efficient way possible without violating the laws of thermodynamics. It operates on the fact that there are two energy states in which a particle can exist: the ground state and the excited state. The excited state carries a little more energy than the ground state, small enough so that the transition occurs with high probability. There are three components or particle types associated with the fridge gate. The first is on the interior of the refrigerator, the second on the outside and the third is connected to a power supply which heats up every so often that it can reach the E state and replenish the source. In the cooling step on the inside of the refrigerator, the g state particle absorbs energy from ambient particles, cooling them, and itself jumping to the e state. In the second step, on the outside of the refrigerator where the particles are also at an e state, the particle falls to the g state, releasing energy and heating the outside particles. In the third and final step, the power supply moves a particle at the e state, and when it falls to the g state it induces an energy-neutral swap where the interior e particle is replaced by a new g particle, restarting the cycle.<ref>{{cite journal|author=Renato Renner|author-link=Renato Renner|date=9 February 2012|title=Thermodynamics: The fridge gate|journal=Nature|volume=482|issue=7384|pages=164–165|bibcode=2012Natur.482..164R|doi=10.1038/482164a|pmid=22318595|doi-access=free|s2cid=4416925}}</ref>