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Metastability

November 15, 2023

For metastability in digital electronics, see Metastability (electronics).

In chemistry and physics, metastability denotes an intermediate energetic state within a dynamical system other than the system's state of least energy. A ball resting in a hollow on a slope is a simple example of metastability. If the ball is only slightly pushed, it will settle back into its hollow, but a stronger push may start the ball rolling down the slope. Bowling pins show similar metastability by either merely wobbling for a moment or tipping over completely. A common example of metastability in science is isomerisation. Higher energy isomers are long lived because they are prevented from rearranging to their preferred ground state by (possibly large) barriers in the potential energy.

A metastable state of weaker bond (1), a transitional 'saddle' configuration (2) and a stable state of stronger bond (3).

During a metastable state of finite lifetime, all state-describing parameters reach and hold stationary values. In isolation:

  • the state of least energy is the only one the system will inhabit for an indefinite length of time, until more external energy is added to the system (unique "absolutely stable" state);
  • the system will spontaneously leave any other state (of higher energy) to eventually return (after a sequence of transitions) to the least energetic state.

The metastability concept originated in the physics of first-order phase transitions. It then acquired new meaning in the study of aggregated subatomic particles (in atomic nuclei or in atoms) or in molecules, macromolecules or clusters of atoms and molecules. Later, it was borrowed for the study of decision-making and information transmission systems.

Metastability is common in physics and chemistry – from an atom (many-body assembly) to statistical ensembles of molecules (viscous fluids, amorphous solids, liquid crystals, minerals, etc.) at molecular levels or as a whole (see Metastable states of matter and grain piles below). The abundance of states is more prevalent as the systems grow larger and/or if the forces of their mutual interaction are spatially less uniform or more diverse.

In dynamic systems (with feedback) like electronic circuits, signal trafficking, decisional, neural and immune systems – the time-invariance of the active or reactive patterns with respect to the external influences defines stability and metastability (see brain metastability below). In these systems, the equivalent of thermal fluctuations in molecular systems is the "white noise" that affects signal propagation and the decision-making.

Statistical physics and thermodynamics edit

Non-equilibrium thermodynamics is a branch of physics that studies the dynamics of statistical ensembles of molecules via unstable states. Being "stuck" in a thermodynamic trough without being at the lowest energy state is known as having kinetic stability or being kinetically persistent. The particular motion or kinetics of the atoms involved has resulted in getting stuck, despite there being preferable (lower-energy) alternatives.

States of matter edit

Metastable states of matter (also referred as metastates) range from melting solids (or freezing liquids), boiling liquids (or condensing gases) and sublimating solids to supercooled liquids or superheated liquid-gas mixtures. Extremely pure, supercooled water stays liquid below 0 °C and remains so until applied vibrations or condensing seed doping initiates crystallization centers. This is a common situation for the droplets of atmospheric clouds.

Condensed matter and macromolecules edit

Metastable phases are common in condensed matter and crystallography. This is the case for anatase, a metastable polymorph of titanium dioxide, which despite commonly being the first phase to form in many synthesis processes due to its lower surface energy, is always metastable, with rutile being the most stable phase at all temperatures and pressures.[1] As another example, diamond is a stable phase only at very high pressures, but 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. Metastable polymorphs of silica are commonly observed. In some cases, such as in the allotropes of solid boron, acquiring a sample of the stable phase is difficult.[2]

The bonds between the building blocks of polymers such as DNA, RNA, and proteins are also metastable. Adenosine triphosphate is a highly metastable molecule, colloquially described as being "full of energy" that can be used in many ways in biology.[3]

Generally speaking, emulsions/colloidal systems and glasses are metastable. The metastability of silica glass, for example, is characterised by lifetimes on the order of 1098 years[4] (as compared with the lifetime of the universe, which is thought to be around 13.787×109 years).[5]

Sandpiles are one system which can exhibit metastability if a steep slope or tunnel is present. Sand grains form a pile due 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 similarly to sandpiles. An entire mountainside of snow can suddenly slide due to the presence of a skier, or even a loud noise or vibration.

Quantum mechanics edit

Aggregated systems of subatomic particles described by quantum mechanics (quarks inside nucleons, nucleons inside atomic nuclei, electrons inside atoms, molecules, or atomic clusters) are found to have many distinguishable states. Of these, one (or a small degenerate set) is indefinitely stable: the ground state or global minimum.

All other states besides the ground state (or those degenerate with it) have higher energies.[6] Of all these other states, the metastable states are the ones having lifetimes lasting at least 102 to 103 times longer than the shortest lived states of the set.[7]

A metastable state is then long-lived (locally stable with respect to configurations of 'neighbouring' energies) but not eternal (as the global minimum is). Being excited – of an energy above the ground state – it will eventually decay to a more stable state, releasing energy. Indeed, above absolute zero, all states of a system have a non-zero probability to decay; that is, to spontaneously fall into another state (usually lower in energy). One mechanism for this to happen is through tunnelling.

Nuclear physics edit

Some energetic states of an atomic nucleus (having distinct spatial mass, charge, spin, isospin distributions) are much longer-lived than others (nuclear isomers of the same isotope), e.g. technetium-99m.[8] The isotope tantalum-180m, although being a metastable excited state, is long-lived enough that it has never been observed to decay, with a half-life calculated to be least 4.5×1016 years,[9][10] over 3 million times the current age of the universe.

Atomic and molecular physics edit

Some atomic energy levels are metastable. Rydberg atoms are an example of metastable excited atomic states. Transitions from metastable excited levels are typically those forbidden by electric dipole selection rules. This means that any transitions from this level are relatively unlikely to occur. In a sense, an electron that happens to find itself in a metastable configuration is trapped there. Since transitions from a metastable state are not impossible (merely less likely), the electron will eventually decay to a less energetic state, typically by an electric quadrupole transition, or often by non-radiative de-excitation (e.g., collisional de-excitation).

This slow-decay property of a metastable state is apparent in phosphorescence, the kind of photoluminescence seen in glow-in-the-dark toys that can be charged by first being exposed to bright light. Whereas spontaneous emission in atoms has a typical timescale on the order of 10−8 seconds, the decay of metastable states can typically take milliseconds to minutes, and so light emitted in phosphorescence is usually both weak and long-lasting.

Chemistry edit

See also: Chemical stability and Chemical equilibrium § Metastable mixtures

In chemical systems, a system of atoms or molecules involving a change in chemical bond can be in a metastable state, which lasts for a relatively long period of time. Molecular vibrations and thermal motion 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). A common type of metastability is isomerism.

The stability or metastability of a given chemical system depends on its environment, particularly temperature and pressure. 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.[11] The map of which state is the most stable as a function of pressure, temperature and/or composition is known as a phase diagram. In regions where a particular state is not the most stable, it may still be metastable. Reaction intermediates are relatively short-lived, and are usually thermodynamically unstable rather than metastable. The IUPAC recommends referring to these as transient rather than metastable.[12]

Metastability is also used to refer to specific situations in mass spectrometry[13] and spectrochemistry.[14]

Electronic circuits edit

A digital circuit is supposed to be found in a small number of stable digital states within a certain amount of time after an input change. However if an input changes at the wrong moment a digital circuit which employs feedback (even a simple circuit such as a flip-flop) can enter a metastable state and take an unbounded length of time to finally settle into a fully stable digital state.

Computational neuroscience edit

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

See also edit

References edit

  1. ^ Hanaor, Dorian A. H.; Sorrell, Charles C. (2011-02-01). "Review of the anatase to rutile phase transformation". Journal of Materials Science. 46 (4): 855–874. Bibcode:2011JMatS..46..855H. doi:10.1007/s10853-010-5113-0. ISSN 1573-4803. S2CID 97190202. Retrieved 2019-10-08.
  2. ^ van Setten; Uijttewaal; de Wijs; de Groot (2007). "Thermodynamic stability of boron: the role of defects and zero point motion" (PDF). Journal of the American Chemical Society. 129 (9): 2458–2465. doi:10.1021/ja0631246. PMID 17295480. S2CID 961904.
  3. ^ Haldane, J. B. S. (1964). "Eighteen: Genesis of Life". In D. R., Bates (ed.). The Planet Earth (2nd ed.). Germany: Pergamon Press. p. 332. ISBN 1483135993. Retrieved May 29, 2017. This is a highly stable molecule. About 11,500 calories of free energy are liberated when it is hydrolized to phosphate and adenosine-diphosphate (ADP).
  4. ^ M.I. Ojovan, W.E. Lee, S.N. Kalmykov. An introduction to nuclear waste immobilisation. Third edition, Elsevier, Amsterdam, p.323 (2019)
  5. ^ Planck Collaboration (2020). "Planck 2018 results. VI. Cosmological parameters". Astronomy & Astrophysics. 641. page A6 (see PDF page 15, Table 2: "Age/Gyr", last column). arXiv:1807.06209. Bibcode:2020A&A...641A...6P. doi:10.1051/0004-6361/201833910. S2CID 119335614.
  6. ^ Hobson, Art (2017). Tales of the Quantum: Understanding Physics' Most Fundamental Theory. Oxford University Press. ISBN 9780190679637.
  7. ^ Hodgman, S. S.; Dall, R. G.; Byron, L. J.; Baldwin, K. G. H.; Buckman, S. J.; Truscott, A. G. (2009-07-31). "Metastable helium: a new determination of the longest atomic excited-state lifetime". Physical Review Letters. 103 (5): 053002. Bibcode:2009PhRvL.103e3002H. doi:10.1103/PhysRevLett.103.053002. hdl:10440/978. ISSN 0031-9007. PMID 19792494.
  8. ^ "Technetium-99m". Hyperphysics.
  9. ^ Conover, Emily (2016-10-03). "Rarest nucleus reluctant to decay". Retrieved 2016-10-05.
  10. ^ Lehnert, Björn; Hult, Mikael; Lutter, Guillaume; Zuber, Kai (2017). "Search for the decay of nature's rarest isotope 180mTa". Physical Review C. 95 (4): 044306. arXiv:1609.03725. Bibcode:2017PhRvC..95d4306L. doi:10.1103/PhysRevC.95.044306. S2CID 118497863.
  11. ^ Process Chemistry in the Pharmaceutical Industry. Kumar G. Gadamasetti, editor. 1999, pp. 375–378
  12. ^ "IUPAC Gold Book – transient (chemical) species". doi:10.1351/goldbook.T06451. {{cite journal}}: Cite journal requires |journal= (help)
  13. ^ "IUPAC Gold Book – metastable ion in mass spectrometry". doi:10.1351/goldbook.M03874. {{cite journal}}: Cite journal requires |journal= (help)
  14. ^ "IUPAC Gold Book – metastable state in spectrochemistry". doi:10.1351/goldbook.M03876. {{cite journal}}: Cite journal requires |journal= (help)

November 15, 2023
metastability, metastability, digital, electronics, electronics, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, new. For metastability in digital electronics see Metastability electronics This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Metastability news newspapers books scholar JSTOR April 2011 Learn how and when to remove this template message In chemistry and physics metastability denotes an intermediate energetic state within a dynamical system other than the system s state of least energy A ball resting in a hollow on a slope is a simple example of metastability If the ball is only slightly pushed it will settle back into its hollow but a stronger push may start the ball rolling down the slope Bowling pins show similar metastability by either merely wobbling for a moment or tipping over completely A common example of metastability in science is isomerisation Higher energy isomers are long lived because they are prevented from rearranging to their preferred ground state by possibly large barriers in the potential energy A metastable state of weaker bond 1 a transitional saddle configuration 2 and a stable state of stronger bond 3 During a metastable state of finite lifetime all state describing parameters reach and hold stationary values In isolation the state of least energy is the only one the system will inhabit for an indefinite length of time until more external energy is added to the system unique absolutely stable state the system will spontaneously leave any other state of higher energy to eventually return after a sequence of transitions to the least energetic state The metastability concept originated in the physics of first order phase transitions It then acquired new meaning in the study of aggregated subatomic particles in atomic nuclei or in atoms or in molecules macromolecules or clusters of atoms and molecules Later it was borrowed for the study of decision making and information transmission systems Metastability is common in physics and chemistry from an atom many body assembly to statistical ensembles of molecules viscous fluids amorphous solids liquid crystals minerals etc at molecular levels or as a whole see Metastable states of matter and grain piles below The abundance of states is more prevalent as the systems grow larger and or if the forces of their mutual interaction are spatially less uniform or more diverse In dynamic systems with feedback like electronic circuits signal trafficking decisional neural and immune systems the time invariance of the active or reactive patterns with respect to the external influences defines stability and metastability see brain metastability below In these systems the equivalent of thermal fluctuations in molecular systems is the white noise that affects signal propagation and the decision making Contents 1 Statistical physics and thermodynamics 1 1 States of matter 1 2 Condensed matter and macromolecules 2 Quantum mechanics 2 1 Nuclear physics 2 2 Atomic and molecular physics 2 3 Chemistry 3 Electronic circuits 4 Computational neuroscience 5 See also 6 ReferencesStatistical physics and thermodynamics editNon equilibrium thermodynamics is a branch of physics that studies the dynamics of statistical ensembles of molecules via unstable states Being stuck in a thermodynamic trough without being at the lowest energy state is known as having kinetic stability or being kinetically persistent The particular motion or kinetics of the atoms involved has resulted in getting stuck despite there being preferable lower energy alternatives States of matter edit Metastable states of matter also referred as metastates range from melting solids or freezing liquids boiling liquids or condensing gases and sublimating solids to supercooled liquids or superheated liquid gas mixtures Extremely pure supercooled water stays liquid below 0 C and remains so until applied vibrations or condensing seed doping initiates crystallization centers This is a common situation for the droplets of atmospheric clouds Condensed matter and macromolecules edit Metastable phases are common in condensed matter and crystallography This is the case for anatase a metastable polymorph of titanium dioxide which despite commonly being the first phase to form in many synthesis processes due to its lower surface energy is always metastable with rutile being the most stable phase at all temperatures and pressures 1 As another example diamond is a stable phase only at very high pressures but 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 Metastable polymorphs of silica are commonly observed In some cases such as in the allotropes of solid boron acquiring a sample of the stable phase is difficult 2 The bonds between the building blocks of polymers such as DNA RNA and proteins are also metastable Adenosine triphosphate is a highly metastable molecule colloquially described as being full of energy that can be used in many ways in biology 3 Generally speaking emulsions colloidal systems and glasses are metastable The metastability of silica glass for example is characterised by lifetimes on the order of 1098 years 4 as compared with the lifetime of the universe which is thought to be around 13 787 109 years 5 Sandpiles are one system which can exhibit metastability if a steep slope or tunnel is present Sand grains form a pile due 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 similarly to sandpiles An entire mountainside of snow can suddenly slide due to the presence of a skier or even a loud noise or vibration Quantum mechanics editAggregated systems of subatomic particles described by quantum mechanics quarks inside nucleons nucleons inside atomic nuclei electrons inside atoms molecules or atomic clusters are found to have many distinguishable states Of these one or a small degenerate set is indefinitely stable the ground state or global minimum All other states besides the ground state or those degenerate with it have higher energies 6 Of all these other states the metastable states are the ones having lifetimes lasting at least 102 to 103 times longer than the shortest lived states of the set 7 A metastable state is then long lived locally stable with respect to configurations of neighbouring energies but not eternal as the global minimum is Being excited of an energy above the ground state it will eventually decay to a more stable state releasing energy Indeed above absolute zero all states of a system have a non zero probability to decay that is to spontaneously fall into another state usually lower in energy One mechanism for this to happen is through tunnelling Nuclear physics edit Some energetic states of an atomic nucleus having distinct spatial mass charge spin isospin distributions are much longer lived than others nuclear isomers of the same isotope e g technetium 99m 8 The isotope tantalum 180m although being a metastable excited state is long lived enough that it has never been observed to decay with a half life calculated to be least 4 5 1016 years 9 10 over 3 million times the current age of the universe Atomic and molecular physics edit Some atomic energy levels are metastable Rydberg atoms are an example of metastable excited atomic states Transitions from metastable excited levels are typically those forbidden by electric dipole selection rules This means that any transitions from this level are relatively unlikely to occur In a sense an electron that happens to find itself in a metastable configuration is trapped there Since transitions from a metastable state are not impossible merely less likely the electron will eventually decay to a less energetic state typically by an electric quadrupole transition or often by non radiative de excitation e g collisional de excitation This slow decay property of a metastable state is apparent in phosphorescence the kind of photoluminescence seen in glow in the dark toys that can be charged by first being exposed to bright light Whereas spontaneous emission in atoms has a typical timescale on the order of 10 8 seconds the decay of metastable states can typically take milliseconds to minutes and so light emitted in phosphorescence is usually both weak and long lasting Chemistry edit See also Chemical stability and Chemical equilibrium Metastable mixtures In chemical systems a system of atoms or molecules involving a change in chemical bond can be in a metastable state which lasts for a relatively long period of time Molecular vibrations and thermal motion 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 A common type of metastability is isomerism The stability or metastability of a given chemical system depends on its environment particularly temperature and pressure 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 11 The map of which state is the most stable as a function of pressure temperature and or composition is known as a phase diagram In regions where a particular state is not the most stable it may still be metastable Reaction intermediates are relatively short lived and are usually thermodynamically unstable rather than metastable The IUPAC recommends referring to these as transient rather than metastable 12 Metastability is also used to refer to specific situations in mass spectrometry 13 and spectrochemistry 14 Electronic circuits editA digital circuit is supposed to be found in a small number of stable digital states within a certain amount of time after an input change However if an input changes at the wrong moment a digital circuit which employs feedback even a simple circuit such as a flip flop can enter a metastable state and take an unbounded length of time to finally settle into a fully stable digital state Computational neuroscience editMetastability in the brain is a phenomenon studied in computational neuroscience to elucidate how the human brain recognizes patterns Here the term metastability is used rather loosely There is no lower energy state but there are semi transient signals in the brain that persist for a while and are different than the usual equilibrium state See also editFalse vacuum Hysteresis MetastateReferences edit Hanaor Dorian A H Sorrell Charles C 2011 02 01 Review of the anatase to rutile phase transformation Journal of Materials Science 46 4 855 874 Bibcode 2011JMatS 46 855H doi 10 1007 s10853 010 5113 0 ISSN 1573 4803 S2CID 97190202 Retrieved 2019 10 08 van Setten Uijttewaal de Wijs de Groot 2007 Thermodynamic stability of boron the role of defects and zero point motion PDF Journal of the American Chemical Society 129 9 2458 2465 doi 10 1021 ja0631246 PMID 17295480 S2CID 961904 Haldane J B S 1964 Eighteen Genesis of Life In D R Bates ed The Planet Earth 2nd ed Germany Pergamon Press p 332 ISBN 1483135993 Retrieved May 29 2017 This is a highly stable molecule About 11 500 calories of free energy are liberated when it is hydrolized to phosphate and adenosine diphosphate ADP M I Ojovan W E Lee S N Kalmykov An introduction to nuclear waste immobilisation Third edition Elsevier Amsterdam p 323 2019 Planck Collaboration 2020 Planck 2018 results VI Cosmological parameters Astronomy amp Astrophysics 641 page A6 see PDF page 15 Table 2 Age Gyr last column arXiv 1807 06209 Bibcode 2020A amp A 641A 6P doi 10 1051 0004 6361 201833910 S2CID 119335614 Hobson Art 2017 Tales of the Quantum Understanding Physics Most Fundamental Theory Oxford University Press ISBN 9780190679637 Hodgman S S Dall R G Byron L J Baldwin K G H Buckman S J Truscott A G 2009 07 31 Metastable helium a new determination of the longest atomic excited state lifetime Physical Review Letters 103 5 053002 Bibcode 2009PhRvL 103e3002H doi 10 1103 PhysRevLett 103 053002 hdl 10440 978 ISSN 0031 9007 PMID 19792494 Technetium 99m Hyperphysics Conover Emily 2016 10 03 Rarest nucleus reluctant to decay Retrieved 2016 10 05 Lehnert Bjorn Hult Mikael Lutter Guillaume Zuber Kai 2017 Search for the decay of nature s rarest isotope 180mTa Physical Review C 95 4 044306 arXiv 1609 03725 Bibcode 2017PhRvC 95d4306L doi 10 1103 PhysRevC 95 044306 S2CID 118497863 Process Chemistry in the Pharmaceutical Industry Kumar G Gadamasetti editor 1999 pp 375 378 IUPAC Gold Book transient chemical species doi 10 1351 goldbook T06451 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help IUPAC Gold Book metastable ion in mass spectrometry doi 10 1351 goldbook M03874 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help IUPAC Gold Book metastable state in spectrochemistry doi 10 1351 goldbook M03876 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Retrieved from https en wikipedia org w index php title Metastability amp oldid 1184021003, wikipedia, wiki, book, books, library,

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