Metastability

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A metastable system with a weakly stable state (1), an unstable transition state (2) and a strongly stable state (3)
A metastable system with a weakly stable state (1), an unstable transition state (2) and a strongly stable state (3)

Metastability is a general scientific concept which describes state of delicate equilibrium. A system is in a metastable state when it is in equilibrium (not changing with time) but is susceptible to fall into lower-energy states with only slight interaction. It is analogous to being balanced precisely at the top of a round hill, rather than safely at the bottom of a valley.

Almost any system can demonstrate metastability, but it is most prevalent in systems of weakly interacting particles in physics and chemistry. Often, the weak interaction between particles is the only energy barrier that must be overcome for the system to reach a lower-energy state.

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[edit] In phases of matter

Metastable phases of matter include those which are supercooled or superheated. For example, supercooled water can exist in liquid form at temperatures below freezing, and will remain there until external interaction (vibration or introduction of a seed particle) causes the water to crystallize.

[edit] In aggregate matter

Small avalanches demonstrate metastability at Mount Baker Ski Area.
Small avalanches demonstrate metastability at Mount Baker Ski Area.

Sandpiles are one system which can exhibit metastability if a steep slope or tunnel is present. Sand grains form a pile thanks to friction. It is possible for an entire large sand pile to reach a point where it is stable, but the addition of a single grain causes large parts of it to collapse.

The avalanche is a well-known problem with large piles of snow and ice crystals on steep slopes. In dry conditions, snow slopes act similar to sandpiles. An entire mountainside of snow can suddenly slide due to the presence of a skier, or even a loud noise or vibration.

[edit] In electronic circuits

Metastability in electronics is usually seen as a problem. A changing circuit is supposed to "settle" into one of a small number of desired states, but if vulnerable to metastability, can get "stuck" in an undesirable state.

[edit] In computational neuroscience

Metastability in the brain is a phenomenon which is being studied in computational neuroscience to elucidate how the human mind recognizes patterns. The term "metastability" here is used rather loosely. There is no "lower energy" state, but there are semi-transient signals in the brain which persist for a while and are different than the usual equilibrium state.

[edit] In chemical systems

A metastable system with a weakly stable state (1), an unstable transition state (2) and a strongly stable state (3)
A metastable system with a weakly stable state (1), an unstable transition state (2) and a strongly stable state (3)

In chemistry, a system of atoms or molecules involving a change in phase of matter, crystal structure, or chemical bond can be in a metastable state, which lasts for a relatively long period of time. Molecular vibrations due to heat make chemical species at the energetic equivalent of the top of a round hill very short-lived. Metastable states that persist for many seconds (or years) are found in energetic valleys which are not the lowest possible valley (point 1 in illustration).

For example, diamond is a metastable form of carbon at standard temperature and pressure. It can be converted to graphite (plus leftover kinetic energy), but only after overcoming an activation energy - an intervening hill. Martensite is a metastable phase used to control the hardness of most steel. The bonds between the building blocks of polymers such as DNA, RNA and proteins are also metastable.

Being "stuck" in a thermodynamic trough without being at the lowest energy state is known as being "kinetically persistent". The particular "motion" or "kinetics" of the atoms involved has resulted in getting "stuck", despite there being preferable (lower-energy) alternatives.

The stability or metastability of a given molecule depends in part on its environment, including temperature, pressure, and the presence of catalysts or seed crystals (in the case of a solid state system). The presence of a liquid layer can help facilities transitions between crystal states. The difference between producing a stable vs. metastable entity can have important consequences. For instances, having the wrong crystal polymorph can result in failure of a drug while in storage between manufacture and administration.[1]

Reaction intermediates are very short-lived, and are actually thermodynamically unstable rather than "metastable". The IUPAC recommends referring to these as "transient" rather than "metastable".[2]

Non-equilibrium thermodynamics includes the study of chemical systems which are in unstable states.

Metastability is also used to refer to specific situations in mass spectrometry[3] and spectrochemistry[4].

See also: Chemical stability
See also: Chemical equilibrium#Metastable_mixtures

[edit] In nuclear physics

An atomic nucleus can achieve a number of different energetic states, known as nuclear isomers. Some of these states are metastable, meaning that there can be relatively long-lived nuclei of the same isotope in different energetic states.

Further information: Nuclear isomer#Metastable_isomers

[edit] See also

[edit] References

  1. ^ Process Chemistry in the Pharmaceutical Industry. Kumar G. Gadamasetti, editor. 1999, p. 375-78
  2. ^ IUPAC Gold Book
  3. ^ http://goldbook.iupac.org/M03874.html
  4. ^ http://goldbook.iupac.org/M03876.html