Quench

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For other uses, see Quenching (disambiguation) or Quench (Band).

A quench refers to a rapid cooling. In polymer chemistry and materials science, quenching is used to prevent low-temperature processes such as phase transformations from occurring by only providing a narrow window of time in which the reaction is both thermodynamically favorable and kinetically accessible. For instance, it can reduce crystallinity and thereby increase toughness of both alloys and plastics (produced through polymerization).

In metallurgy, it is most commonly used to harden steel by introducing martensite, in which case the steel must be rapidly cooled through its eutectoid point, the temperature at which austenite becomes unstable. In steel alloyed with metals such as nickel and manganese, the eutectoid temperature becomes much lower, but the kinetic barriers to phase transformation remain the same. This allows quenching to start at a lower temperature, making the process much easier. High-speed steel also has added tungsten, which serves to raise kinetic barriers and give the illusion that the material has been cooled more rapidly than it really has. Even cooling such alloys slowly in air has most of the desired effects of quenching.

In fluorescence, it refers to any process which decreases the fluorescence intensity of a given substance. A variety of processes can result in quenching, such as excited state reactions, energy transfer, complex formation and colissional quenching.

Molecular oxygen and the iodide ion are common chemical quenchers.

In superconducting magnet technology, quench refers to a thermal runaway of the superconducing magnet. The energy stored in the magnet is released leading to an increase in the magnet's temperature.

In a high voltage spark gap, fuse, or circuit breaker, quenching refers to the successful extinguishing an electric arc. Quenching is accomplished by temporarily removing current (possibly during an AC zero crossing, or by physically stretching or rapidly cooling the arc's channel). Once quenched, the dielectric strength of the gap recovers sufficiently to prevent immediate reignition of the arc.