Physics:Flux method

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The flux method is a crystal growth method where starting materials are dissolved in a solvent (flux), and are precipitated out to form crystals of a desired compound. The flux lowers the melting point of the desired compound, analogous to a wet chemistry recrystallization.[1] The flux is molten in a highly stable crucible that does not react with the flux. Metal crucibles, such as platinum, titanium, and niobium are used for the growth of oxide crystals. Ceramic crucibles, such as alumina, zirconia, and boron nitride are used for the growth of metallic crystals.[2] For air-sensitive growths, contents are sealed in ampoules or placed in atmosphere controlled furnaces.

Choice of flux

Oxide fluxes are often combined to reduce volatility, viscosity, and reactivity towards the crucibles. Metallic fluxes aren't typically combined,[3] as they do not suffer from the same volatility, viscosity, and reactivity issues. An ideal flux should have the following properties:[2]

  • Good solubility for desired compound at growth temperatures.
  • Low melting point.
  • Large gap between melting and boiling point.
  • Easily removed from crystals.
  • Unreactive with crucible and starting materials at growth temperatures.
Common Fluxes
Metallic Flux Oxide Flux
Flux Melting Point (°C) Boiling Point (°C) Flux Melting Point (°C) Boiling Point (°C)
Aluminum 660 2470 Lead(II) Oxide 888 1477
Bismuth 271 1564 Lead(II) Fluoride 824 1293
Gallium 30 2400 Bismuth (III) Oxide 817 1890
Indium 157 2072 Lithium Oxide 1438 2600
Tin 232 2602 Molybdenum Trioxide 802 1152
Lead 328 1749 Potassium Fluoride 858 1502

Furnace procedure

The growth (starting materials, flux, and crucible) are heated to form a complete liquid solution. The growth is cooled to a temperature where the solution is fully saturated. Further cooling causes crystals to precipitate from the solution, lowering the concentration of starting materials in solution, and lowering the temperature where the solution is fully saturated. The process is repeated, decreasing temperature and precipitating more crystals. The process is then stopped at a desired temperature, and the growth is removed from the furnace. Practically, the flux method is done by placing the growth into a programmable furnace:[citation needed]

  1. Ramp - The furnace is heated from an initial temperature to a maximum temperature, where the growth forms a complete liquid solution.
  2. Dwell - The furnace is maintained at the maximum temperature to homogenize the solution.
  3. Cool - The furnace is cooled to a desired temperature over a specified rate or time.
  4. Removal - The growth is removed from the furnace. The growth can be quenched, centrifuged, or simply removed if already at room temperature.

Additional steps may be added to this basic temperature profile, such as additional dwells or different cooling rates over different points of the cool. Crystallization can occur through spontaneous nucleation, encouragement with a seed, or through mechanical stress.[citation needed]

Flux separation

A crystal grown from gallium flux, with flux attached to the surface

After crystallization, often some solidified flux remains on the surface or inside the desired crystal. This flux may cause defects in the crystal due to the different thermal expansivities of the flux and crystal.[4] A solvent (typically an acid or a base) can dissolve the flux, but it's difficult to find a solvent that doesn't also dissolve the crystal. The flux can be removed mechanically using a blade or drill. If the crystal and flux have significantly different boiling points, the flux may be removed with evaporation. Flux can also be removed through recrystallization through use of a seed in the liquid phase, leaving the flux behind as the crystals accumulate.

The removal of excess flux is important to assess a crystals properties, as the flux can affect measurements. For example, tin and lead super conduct at low temperatures,[5] if a sample has tin or lead flux superconductivity can be observed even if the desired crystal is not a superconductor.

See also

External links

References

  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. 2.0 2.1 Tachibana, Makoto (2017) (in en). Beginner's Guide to Flux Crystal Growth. Tsukuba, Ibaraki Japan: Springer. pp. 61–87. ISBN 978-4-431-56586-4. 
  3. Kanatzidis, Mercouri G.; Pöttgen, Rainer; Jeitschko, Wolfgang (2005-11-04). "The Metal Flux: A Preparative Tool for the Exploration of Intermetallic Compounds" (in en). Angewandte Chemie International Edition 44 (43): 6996–7023. doi:10.1002/anie.200462170. ISSN 1433-7851. https://onlinelibrary.wiley.com/doi/10.1002/anie.200462170. 
  4. Wolf, Thomas (July 2012). "Flux separation methods for flux-grown single crystals" (in en). Philosophical Magazine 92 (19–21): 2458–2465. doi:10.1080/14786435.2012.685193. ISSN 1478-6435. Bibcode2012PMag...92.2458W. http://www.tandfonline.com/doi/abs/10.1080/14786435.2012.685193. 
  5. Buzea, Cristina; Robbie, Kevin (2005-01-01). "Assembling the puzzle of superconducting elements: a review". Superconductor Science and Technology 18 (1): R1–R8. doi:10.1088/0953-2048/18/1/R01. ISSN 0953-2048. https://iopscience.iop.org/article/10.1088/0953-2048/18/1/R01. 

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