Flux method: Difference between revisions

Crystallization
Crystallization
Fundamentals
	Crystal; Crystal structure; Nucleation;
Concepts
	Crystallization; Crystal growth; Recrystallization; Seed crystal; Protocrystalline; Single crystal;
Methods and technology
	Boules; Bridgman–Stockbarger method; Van Arkel–de Boer process; Czochralski method; Epitaxy; Flux method; Fractional crystallization; Fractional freezing; Hydrothermal synthesis; Kyropoulos method; Laser-heated pedestal growth; Micro-pulling-down; Shaping processes in crystal growth; Skull crucible; Verneuil method; Zone melting;
	v; t; e;

Browse history interactively

← Previous edit Next edit →

Content deleted Content added

VisualWikitext

Inline

Revision as of 09:45, 5 December 2023

The flux method of crystal growth is a method where crystal starting materials are dissolved in a solvent (flux), typically a solid at room temperature, and heated until molten.^[1] Crystals of the desired compound are then precipitated out. The method is particularly suitable for crystals needing to be free from thermal strain. The flux is typically molten in a crucible made of highly stable, non-reactive material. For production of oxide crystals, metals such as platinum, tantalum, and niobium are common. Production of metallic crystals generally uses crucibles made from ceramics such as alumina, zirconia, and boron nitride^[2]. For air sensitive growths, contents are often isolated from the air, either by sealing them in a quartz ampoule or by using atmosphere controlled furnace.

The starting materials, flux and crucible are heated to form a complete solution, then cooled to a temperature where the solution is fully saturated. Further cooling allows the desired material to precipitate, decreasing the concentration of starting materials in solution. Crystal formation can begin by spontaneous nucleation or may be encouraged by the use of a seed. As material precipitates out of the solution, the amount of solute in the flux decreases and the temperature at which the solution is saturated lowers. This process repeats itself as the furnace continues to cool until the solution reaches its melting point or the reaction is stopped artificially. In flux method synthesis, divergent crystal growth kinetics may emerge, with a small number of crystallites growing at the expense of neighbouring ones, resulting in abnormal grain growth.

One advantage of this method is that the crystals grown often display natural facets, which often makes preparing crystals for measurement significantly easier. A disadvantage is that most flux method syntheses produce relatively small crystals. However, some materials such as the "115" heavy fermion superconductors (CeXIn₅, X=Co,Ir,Rh) may grow up to a few centimeters. Flux growth is preferable to a pure melt in that it avoids the situation of incongruent melting at high temperatures required to melt the substance by replacing it with a lower melting temperature flux.^[3]

External links

References

^ Byrappa, K.; Ohachi, Tadashi (Eds.) (2003). "17.2.4 Flux method". Crystal Growth Technology. Norwich, N.Y.: William Andrew Pub. p. 567. ISBN 3-540-00367-3. Components of the gem materials desired in a single crystal form are dissolved in a flux (solvent).
^ Tachibana, Makoto (2017). Beginner's Guide to Flux Crystal Growth. Tsukuba, Ibaraki Japan: Springer. pp. 82–87. ISBN 978-4-431-56586-4.
^ Fisk, Z.; Remeika, J. P. (1989-01-01), "Chapter 81 Growth of single crystals from molten metal fluxes", Handbook on the Physics and Chemistry of Rare Earths, vol. 12, Elsevier, p. 54, retrieved 2023-11-08

[1] Byrappa, K.; Ohachi, Tadashi (Eds.) (2003). "17.2.4 Flux method". Crystal Growth Technology. Norwich, N.Y.: William Andrew Pub. p. 567. ISBN 3-540-00367-3. Components of the gem materials desired in a single crystal form are dissolved in a flux (solvent).

[2] Tachibana, Makoto (2017). Beginner's Guide to Flux Crystal Growth. Tsukuba, Ibaraki Japan: Springer. pp. 82–87. ISBN 978-4-431-56586-4.

[3] Fisk, Z.; Remeika, J. P. (1989-01-01), "Chapter 81 Growth of single crystals from molten metal fluxes", Handbook on the Physics and Chemistry of Rare Earths, vol. 12, Elsevier, p. 54, retrieved 2023-11-08

[1]

[2]

[3]

@@ Line 1: / Line 1: @@
 {{Crystallization}}
 {{Refimprove|date=January 2021}}
-The '''flux method''' of [[crystal growth]] is a method where crystal starting materials are dissolved in a [[solvent]] ([[flux (metallurgy)|flux]]), typically a solid at room temperature, and heated until molten.<ref>{{cite book |last1=Byrappa |first1=K. |last2=Ohachi |first2=Tadashi (Eds.) |title=Crystal Growth Technology |date=2003 |publisher=William Andrew Pub. |location=Norwich, N.Y. |isbn=3-540-00367-3 |page=567 |chapter=17.2.4 Flux method |quote=Components of the gem materials desired in a single crystal form are dissolved in a flux (solvent).}}</ref> Crystals of the desired compound are then precipitated out. The method is particularly suitable for crystals needing to be free from thermal strain. The flux is typically molten in a [[crucible]] made of highly stable, non-reactive material. For production of oxide crystals, metals such as [[platinum]], [[tantalum]], and [[niobium]] are common. Production of metallic crystals generally uses crucibles made from ceramics such as [[alumina]], [[zirconia]], and [[boron nitride]]. For air sensitive growths, contents are often isolated from the air, either by sealing them in a quartz ampoule or by using atmosphere controlled furnace.
+The '''flux method''' of [[crystal growth]] is a method where crystal starting materials are dissolved in a [[solvent]] ([[flux (metallurgy)|flux]]), typically a solid at room temperature, and heated until molten.<ref>{{cite book |last1=Byrappa |first1=K. |last2=Ohachi |first2=Tadashi (Eds.) |title=Crystal Growth Technology |date=2003 |publisher=William Andrew Pub. |location=Norwich, N.Y. |isbn=3-540-00367-3 |page=567 |chapter=17.2.4 Flux method |quote=Components of the gem materials desired in a single crystal form are dissolved in a flux (solvent).}}</ref> Crystals of the desired compound are then precipitated out. The method is particularly suitable for crystals needing to be free from thermal strain. The flux is typically molten in a [[crucible]] made of highly stable, non-reactive material. For production of oxide crystals, metals such as [[platinum]], [[tantalum]], and [[niobium]] are common. Production of metallic crystals generally uses crucibles made from ceramics such as [[alumina]], [[zirconia]], and [[boron nitride]]<ref>{{Cite book |last=Tachibana |first=Makoto |title=Beginner's Guide to Flux Crystal Growth |publisher=Springer |year=2017 |isbn=978-4-431-56586-4 |location=Tsukuba, Ibaraki Japan |pages=82-87 |language=en}}</ref>. For air sensitive growths, contents are often isolated from the air, either by sealing them in a quartz ampoule or by using atmosphere controlled furnace.
 The starting materials, flux and crucible are heated to form a complete [[Solution (chemistry)|solution]], then cooled to a temperature where the solution is [[Supersaturation|fully saturated]]. Further cooling allows the desired material to precipitate, decreasing the concentration of starting materials in solution. Crystal formation can begin by spontaneous nucleation or may be encouraged by the use of a [[seed crystal|seed]]. As material precipitates out of the solution, the amount of solute in the flux decreases and the temperature at which the solution is saturated lowers. This process repeats itself as the furnace continues to cool until the solution reaches its melting point or the reaction is stopped artificially. In flux method synthesis, divergent crystal growth kinetics may emerge, with a small number of crystallites growing at the expense of neighbouring ones, resulting in [[abnormal grain growth]].

Revision as of 09:45, 5 December 2023

See also

External links

References