Sodium borate

Sodium borate is a generic name for any salt of sodium with an anion consisting of boron and oxygen, and possibly hydrogen, or any hydrate thereof. It can be seen as a hydrated sodium salt of the appropriate boroxy acid, although the latter may not be a stable compound.

Many sodium borates have important industrial and household applications; the best known being borax, (Na⁺)₂[B₄O₅(OH)₄]²⁻·8H₂O = Na₂B₄H₂₀O₁₇.

The ternary phase diagram of the Na₂O–B₂O₃–H₂O phase diagram in the 0–100 °C temperature range contains 13 unique hydrated crystalline sodium borates, including five important industrial products.^[1]

Sodium borates, as well as boroxy acids, are often described as mixtures xNa₂O·yB₂O₃·zH₂O = Na_2xB_2yH_2zO_x+3y+z, with x, y, and z chosen to fit the elemental formula, or a multiple thereof. Thus, for example, borax Na₂B₄H₂₀O₁₇ would be 1Na₂O·2B₂O₃·10H₂O, and boric acid B(OH)₃ would be 0Na₂O·1B₂O₃·1H₂O = 2[B(OH)₃].

The elemental formula was often interpreted as a z-hydrate of an "anhydrous" salt without any hydrogen, namely Na_2xB_2yO_3y·zH₂O. However, later research uncovered that many borates have hydroxyl groups HO⁻ bound covalently to the boron atoms in the anion. Thus borax, for example, is still often described as a decahydrate Na₂B₄O₇·10H₂O, with the implied anion [B₄O₇]²⁻, whereas the correct formula is Na₂B₄O₅(OH)₄·8H₂O, with anion [B₄O₅(OH)₄]²⁻.

The following table gives some of the crystalline sodium borates in this family.^[2] The column x/(x+y) is the formal mole fraction of Na₂O in the "anhydrous" version.

Some of the borates above may have more than one isomeric or crystalline form. Some may decompose when dissolved in water. Note that the anion of the "anhydrous borax" is different from that of its "hydrates".

Some of the anhydrous borates above can be crystallized from molten mixtured of sodium oxide and boric oxide.^[6]

Some sodium borates hower cannot be analyzed as combinations xNa₂O·yB₂O₃·zH₂O of the three ordinary oxides. The most important example is sodium perborate, originally described as NaBO₃·H₂O but actually (Na⁺)₂[B₂O₄(OH)₄]²⁻. The anion of this compound has two peroxide bridges −O−O− which make it oxygen-rich compared to the general family above.

References

1. Doinita Neiner, Yulia V. Sevryugina, Larry S. Harrower, and David M. Schubert (2017): "Structure and Properties of Sodium Enneaborate, Na₂[B₈O₁₁(OH)₄]·B(OH)₃·2H₂O". Inorganic Chemistry, volume 56, issue 12, pages 7175–7181. doi:10.1021/acs.inorgchem.7b00823
2. Nelson P. Nies and Richard W. Hulbert (1967): "Solubility isotherms in the system sodium oxide-boric oxide-water. Revised solubility-temperature curves of boric acid, borax, sodium pentaborate, and sodium metaborate". Journal of Chemical and Engineering Data, volume 12, issue 3, pages 303–313. doi:10.1021/je60034a005
3. S. Stella Mary, S. Shahil Kirupavathy, P. Mythili, R. Gopalakrishnan (2008): "Growth and characterization of sodium pentaborate [Na(H₄B₅O₁₀)] single crystals". Spectrochimica Acta Part A, volume 71, issue 4, 15 pages 1311-1316. doi:10.1016/j.saa.2008.04.021
4. Taha Cagri Senocak, Taha Alper Yilmaz, Hasan Feyzi Budak, Gokhan Gulten, Ahmet Melik Yilmaz, Kadri Vefa Ezirmik, Yasar Totikc (2022): "Influence of sodium pentaborate (B₅H₁₀NaO₁₃) additive in plasma electrolytic oxidation process on WE43 magnesium alloys". Materials Today Communications, volume 30, article 103157. doi:10.1016/j.mtcomm.2022.103157
5. Silvio Menchetti and Cesare Sabelli (1977): "The crystal structure of synthetic sodium pentaborate monohydrate". Acta Crystallographica Section B, volume B33, pages 3730-3733. doi:10.1107/S0567740877011959
6. Charles Hutchens Burgess and Alfred Holt (1905): "Some physical characters of the sodium borates, with a new and rapid method for the determination of melting points." Proceedings of the Royal Society of London, volume 74, pages 285–295.doi:10.1098/rspl.1904.0112