Titanium diboride

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Titanium diboride (TiB2) is an extremely hard ceramic which has excellent heat conductivity, oxidation stability and wear resistance. TiB2 is also a reasonable electrical conductor,[1] so it can be used as a cathode material in aluminium smelting and can be shaped by electrical discharge machining.

Titanium diboride
Identifiers
3D model (JSmol)
ChemSpider
ECHA InfoCard 100.031.771 Edit this at Wikidata
EC Number
  • 234-961-4
  • InChI=1S/B2.Ti/c1-2;
    Key: TXVDUUNOLJOZCR-UHFFFAOYSA-N
  • [B].[Ti].[B]
Properties
TiB2
Molar mass 69.489 g/mol
Appearance non lustrous metallic grey
Density 4.52 g/cm3
Melting point 3,230 °C (5,850 °F; 3,500 K)
Structure
Hexagonal, hP1
P6/mmm
a = 302.36 pm, c = 322.04 pm
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
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Physical properties

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TiB2 shares some properties with boron carbide and titanium carbide, but many of its properties are superior to those of B4C & TiC:[2]

Exceptional hardness at extreme temperature

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  • 2nd hardest material at 3000°C (diamond)
  • 3rd hardest material at 2800°C (cBN)
  • 4th hardest material at 2100°C (B4C)
  • 5th hardest material at 1000°C (B6O)

Advantages over other borides

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Other advantages

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Drawbacks

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Chemical properties

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With respect to chemical stability, TiB2 is more stable in contact with pure iron than tungsten carbide or silicon nitride.[2]

TiB2 is resistant to oxidation in air at temperatures up to 1100 °C,[2] and to hydrochloric and hydrofluoric acids, but reacts with alkalis, nitric acid and sulfuric acid.

Production

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TiB2 does not occur naturally in the earth. Titanium diboride powder can be prepared by a variety of high-temperature methods, such as the direct reactions of titanium or its oxides/hydrides, with elemental boron over 1000 °C, carbothermal reduction by thermite reaction of titanium oxide and boron oxide, or hydrogen reduction of boron halides in the presence of the metal or its halides. Among various synthesis routes, electrochemical synthesis and solid state reactions have been developed to prepare finer titanium diboride in large quantity. An example of solid state reaction is the borothermic reduction, which can be illustrated by the following reactions:

(1) 2 TiO2 + B4C + 3C → 2 TiB2 + 4 CO

(2) TiO2 + 3NaBH4 → TiB2 + 2Na(g,l) + NaBO2 + 6H2(g)[3]

The first synthesis route (1), however, cannot produce nanosized powders. Nanocrystalline (5–100 nm) TiB2 was synthesized using the reaction (2) or the following techniques:

  • Solution phase reaction of NaBH4 and TiCl4, followed by annealing the amorphous precursor obtained at 900–1100 °C.[4]
  • Mechanical alloying of a mixture of elemental Ti and B powders.[5]
  • Self-propagating high-temperature synthesis process involving addition of varying amounts of NaCl.[6]
  • Milling assisted self-propagating high-temperature synthesis (MA-SHS).[7]
  • Solvothermal reaction in benzene of metallic sodium with amorphous boron powder and TiCl4 at 400 °C:[8]
TiCl4 + 2 B + 4 Na → TiB2 + 4 NaCl

Many TiB2 applications are inhibited by economic factors, particularly the costs of densifying a high melting point material - the melting point is about 2970 °C, and, thanks to a layer of titanium dioxide that forms on the surface of the particles of a powder, it is very resistant to sintering. Admixture of about 10% silicon nitride facilitates the sintering,[9] though sintering without silicon nitride has been demonstrated as well.[1]

Thin films of TiB2 can be produced by several techniques. The electroplating of TiB2 layers possess two main advantages compared with physical vapor deposition or chemical vapor deposition: the growing rate of the layer is 200 times higher (up to 5 μm/s) and the inconveniences of covering complex shaped products are dramatically reduced.

Potential applications

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Current use of TiB2 appears to be limited to specialized applications in such areas as impact resistant armor, cutting tools, crucibles, neutron absorbers and wear resistant coatings.[10]

TiB2 is extensively used for evaporation boats for vapour coating of aluminium.[11] It is an attractive material for the aluminium industry as an inoculant to refine the grain size when casting aluminium alloys, because of its wettability by and low solubility in molten aluminium and good electrical conductivity.

Thin films of TiB2 can be used to provide wear and corrosion resistance to a cheap and/or tough substrate.[12]

References

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  1. ^ a b J. Schmidt et al. "Preparation of titanium diboride TiB2 by spark plasma sintering at slow heating rate" Sci. Technol. Adv. Mater. 8 (2007) 376 free download
  2. ^ a b c Basu, B.; Raju, G. B.; Suri, A. K. (2006-12-01). "Processing and properties of monolithic TiB2 based materials". International Materials Reviews. 51 (6): 352–374. Bibcode:2006IMRv...51..352B. doi:10.1179/174328006X102529. ISSN 0950-6608. S2CID 137562554.
  3. ^ Zoli, Luca; Galizia, Pietro; Silvestroni, Laura; Sciti, Diletta (23 January 2018). "Synthesis of group IV and V metal diboride nanocrystals via borothermal reduction with sodium borohydride". Journal of the American Ceramic Society. 101 (6): 2627–2637. doi:10.1111/jace.15401.
  4. ^ S. E. Bates et al. "Synthesis of titanium boride (TiB)2 nanocrystallites by solution-phase processing" J. Mater. Res. 10 (1995) 2599
  5. ^ A. Y. Hwang and J. K. Lee "Preparation of TiB2 powders by mechanical alloying " Mater. Lett. 54 (2002) 1
  6. ^ A. K. Khanra et al. "Effect of NaCl on the synthesis of TiB2 powder by a self-propagating high-temperature synthesis technique" Mater. Lett. 58 (2004) 733
  7. ^ Amin Nozari; et al. (2012). "Synthesis and characterization of nano-structured TiB2 processed by milling assisted SHS route". Materials Characterization. 73: 96–103. doi:10.1016/j.matchar.2012.08.003.
  8. ^ Y. Gu et al. "A mild solvothermal route to nanocrystalline titanium diboride" J. Alloy. Compd. 352 (2003) 325
  9. ^ "Titanium diboride sintered body with silicon nitride as a sintering aid and a method for manufacture thereof". Archived from the original on 2016-03-03. Retrieved 2008-07-02.
  10. ^ Ross, Lisa (Sep 24, 2024). "Top 10 Ceramic Materials with the Highest Thermal Conductivity". Advanced Ceramic Materials. Retrieved Nov 8, 2024.
  11. ^ McKinon, Ruth; Grasso, Salvatore (2017). "Flash spark plasma sintering of cold-Pressed TiB2-hBN". Journal of the European Ceramic Society. 37 (8): 2787–2794. doi:10.1016/j.jeurceramsoc.2017.01.029.
  12. ^ Wu, Zhengtao; Ye, Rongli (2022). "Reprint of: Improving oxidation and wear resistance of TiB2 films by nano-multilayering with Cr". Surface and Coatings Technology. 442: 128602. doi:10.1016/j.surfcoat.2022.128602.

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See also

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