Freezing

Freezing or solidification is a phase change in which a liquid turns into a solid when its temperature is lowered below its freezing point. The reverse process is melting.

All known liquids, except liquid helium, freeze when the temperature is lowered enough. Liquid helium remains liquid at atmospheric pressure even at absolute zero, and can be solidified only under pressure.^[1] For most substances, the melting and freezing points are the same temperature; however, certain substances possess differing solid–liquid transition temperatures. For example, agar displays a hysteresis in its melting and freezing temperatures. It melts at 85 °C (185 °F) and solidifies from 31 °C to 40 °C (89.6 °F to 104 °F).

Crystallization

Most liquids freeze by crystallization, formation of crystalline solid from the uniform liquid. This is a first-order thermodynamic phase transition, which means that, as long as solid and liquid coexist, the equilibrium temperature of the system remains constant and equal to the melting point. Crystallization consists of two major events, nucleation and crystal growth. Nucleation is the step wherein the molecules start to gather into clusters, on the nanometer scale, arranging in a defined and periodic manner that defines the crystal structure. The crystal growth is the subsequent growth of the nuclei that succeed in achieving the critical cluster size.

Supercooling

In spite of the second law of thermodynamics, crystallization of pure liquids usually begins at a lower temperature than the melting point, due to high activation energy of homogeneous nucleation. The creation of a nucleus implies the formation of an interface at the boundaries of the new phase. Some energy is expended to form this interface, based on the surface energy of each phase. If a hypothetical nucleus is too small, the energy that would be released by forming its volume is not enough to create its surface, and nucleation does not proceed. Freezing does not start until the temperature is low enough to provide enough energy to form stable nuclei. In presence of irregularities on the surface of the containing vessel, solid or gaseous impurities, pre-formed solid crystals, or other nucleators, heterogeneous nucleation may occur, where some energy is released by the partial destruction of the previous interface, raising the supercooling point to be near or equal to the melting point. The melting point of water at 1 atmosphere of pressure is very close to 0 °C (32 °F, 273.15 K), and in the presence of nucleating substances the freezing point of water is close to the melting point, but in the absence of nucleators water can super cool to −40 °C (−40 °F, 233 K) before freezing.^[2]^[3]^[4] Under high pressure (2,000 atmospheres) water will super cool to as low as −70 °C (−94 °F, 203 K) before freezing.^[5]

Exothermicity

Freezing is almost always an exothermic process, meaning that as liquid changes into solid, heat and pressure is released. This is often seen as counter-intuitive,^[6] since the temperature of the material does not rise during freezing, except if the liquid were supercooled. But this can be understood, since heat must be continually removed from the freezing liquid or the freezing process will stop. The energy released upon freezing is a latent heat, and is known as the enthalpy of fusion and is exactly the same as the energy required to melt the same amount of the solid.

Low-temperature helium is the only known exception to the general rule.^[7] Helium-3 has a negative enthalpy of fusion at temperatures below 0.3 K. Helium-4 also has a very slightly negative enthalpy of fusion below 0.8 K. This means that, at appropriate constant pressures, heat must be added to these substances in order to freeze them.^[8]

Vitrification

Certain materials, such as glass and glycerol, may harden without crystallizing; these are called amorphous solids. Amorphous materials as well as some polymers do not have a true freezing point, as there is no abrupt phase change at any specific temperature. Instead, there is a gradual change in their viscoelastic properties over a range of temperatures. Such materials are characterized by a glass transition that occurs at a glass transition temperature, which may be roughly defined as the "knee" point of the material's density vs. temperature graph.

Freezing of living organisms

Many living organisms are able to tolerate prolonged periods of time at temperatures below the freezing point of water. Most living organisms accumulate cryoprotectants such as anti-nucleating proteins, polyols, and glucose to protect themselves against frost damage by sharp ice crystals. Most plants, in particular, can safely reach temperatures of −4 °C to −12 °C. Certain bacteria, notably Pseudomonas syringae, produce specialized proteins that serve as potent ice nucleators, which they use to force ice formation on the surface of various fruits and plants at about −2 °C.^[9] The freezing causes injuries in the epithelia and makes the nutrients in the underlying plant tissues available to the bacteria.^[10]

Bacteria

Three species of bacteria, Carnobacterium pleistocenium, as well as Chryseobacterium greenlandensis and Herminiimonas glaciei, have reportedly been revived after surviving for thousands of years frozen in ice.

Plants

Many plants undergo a process called hardening, which allows them to survive temperatures below 0 °C for weeks to months.

Animals

The nematode Haemonchus contortus can survive 44 weeks frozen at liquid nitrogen temperatures. Other nematodes that survive at temperatures below 0 °C include Trichostrongylus colubriformis and Panagrolaimus davidi. Many species of reptiles and amphibians survive freezing. See cryobiology for a full discussion.

Human gametes and 2-, 4- and 8-cell embryos can survive freezing and are viable for up to 10 years, a process known as cryopreservation.

Experimental attempts to freeze human beings for later revival are known as cryonics.

Food preservation

Freezing is a common method of food preservation that slows both food decay and the growth of micro-organisms. Besides the effect of lower temperatures on reaction rates, freezing makes water less available for bacterial growth.

References

^ London, F. (1 February 1936). "On Condensed Helium at Absolute Zero". Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences. 153 (880). The Royal Society: 576–583. JSTOR 96571.
^ Lundheim R. (2002). "Physiological and ecological significance of biological ice nucleators". Philos Trans R Soc Lond B Biol Sci. 357 (1423): 937–943. doi:10.1098/rstb.2002.1082. PMC 1693005. PMID 12171657.
^ Franks F. (2003). "Nucleation of ice and its management in ecosystems" (PDF). Philos Transact a Math Phys Eng Sci. 361 (1804): 557–574. Bibcode:2003RSPTA.361..557F. doi:10.1098/rsta.2002.1141. PMID 12662454.
^ pipe freezing
^ Jeffery, CA; Austin, PH (1997). "Homogeneous nucleation of supercooled water: Results from a new equation of state". Journal of Geophysical Research. 102 (D21): 25269–25280. Bibcode:1997JGR...10225269J. doi:10.1029/97JD02243. {{cite journal}}: More than one of |author= and |last1= specified (help); Unknown parameter |month= ignored (help)
^ What is an exothermic reaction? Scientific American, 1999
^ Atkins, Peter; Jones, Loretta (2008), Chemical Principles: The Quest for Insight (4th ed.), W. H. Freeman and Company, p. 236, ISBN 0-7167-7355-4
^ Ott, J. Bevan; Boerio-Goates, Juliana (2000), Chemical Thermodynamics: Advanced Applications, Academic Press, pp. 92–93, ISBN 0-12-530985-6
^ Maki LR, Galyan EL, Chang-Chien MM, Caldwell DR (1974). "Ice nucleation induced by pseudomonas syringae". Applied Microbiology. 28 (3): 456–459. PMC 186742. PMID 4371331.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ Zachariassen KE, Kristiansen E (2000). "Ice nucleation and antinucleation in nature". Cryobiology. 41 (4): 257–279. doi:10.1006/cryo.2000.2289. PMID 11222024.

External links

Video of an intermetallic compound solidifying/freezing

[1] London, F. (1 February 1936). "On Condensed Helium at Absolute Zero". Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences. 153 (880). The Royal Society: 576–583. JSTOR 96571.

[2] Lundheim R. (2002). "Physiological and ecological significance of biological ice nucleators". Philos Trans R Soc Lond B Biol Sci. 357 (1423): 937–943. doi:10.1098/rstb.2002.1082. PMC 1693005. PMID 12171657.

[3] Franks F. (2003). "Nucleation of ice and its management in ecosystems" (PDF). Philos Transact a Math Phys Eng Sci. 361 (1804): 557–574. Bibcode:2003RSPTA.361..557F. doi:10.1098/rsta.2002.1141. PMID 12662454.

[4] pipe freezing

[5] Jeffery, CA; Austin, PH (1997). "Homogeneous nucleation of supercooled water: Results from a new equation of state". Journal of Geophysical Research. 102 (D21): 25269–25280. Bibcode:1997JGR...10225269J. doi:10.1029/97JD02243. {{cite journal}}: More than one of |author= and |last1= specified (help); Unknown parameter |month= ignored (help)

[6] What is an exothermic reaction? Scientific American, 1999

[7] Atkins, Peter; Jones, Loretta (2008), Chemical Principles: The Quest for Insight (4th ed.), W. H. Freeman and Company, p. 236, ISBN 0-7167-7355-4

[8] Ott, J. Bevan; Boerio-Goates, Juliana (2000), Chemical Thermodynamics: Advanced Applications, Academic Press, pp. 92–93, ISBN 0-12-530985-6

[9] Maki LR, Galyan EL, Chang-Chien MM, Caldwell DR (1974). "Ice nucleation induced by pseudomonas syringae". Applied Microbiology. 28 (3): 456–459. PMC 186742. PMID 4371331.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[10] Zachariassen KE, Kristiansen E (2000). "Ice nucleation and antinucleation in nature". Cryobiology. 41 (4): 257–279. doi:10.1006/cryo.2000.2289. PMID 11222024.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

To From	Solid	Liquid	Gas	Plasma
Solid		Melting	Sublimation
Liquid	Freezing		Vaporization
Gas	Deposition	Condensation		Ionization
Plasma			Recombination