Sodium metaborate is a chemical compound of sodium, boron, and oxygen with formula . However, the metaborate ion is trimeric in the anhydrous solid, therefore a more correct formula is or . The formula can be written also as to highlight the relation to the main oxides of sodium and boron. The name is also applied to several hydrates whose formulas can be written for various values of n.
The anhydrous and hydrates are colorless crystalline solids. The anhydrous form is hygroscopic.
The following hydrates crystallize from solutions of the proper composition in various temperature ranges:
Early reports of a monohydrate have not been confirmed.
Solid anhydrous sodium metaborate has the hexagonal crystal system with space group . It actually contains a six-membered rings with the formula , consisting of alternating boron and oxygen atoms with one negatively charged extra oxygen atom attached to each boron atom. All nine atoms lie on a plane. The six oxygen atoms are evenly divided into two distinct structural sites, with different BâÂÂO bond lengths: BâÂÂO(external) 128.0 pm and BâÂÂO(bridge) 143.3 pm. The density is 2.348 ñ 0.005 g/cm<sup>3</sup>. The approximate dimensions of the hexagonal cell are a = 1275 pm, c = 733 pm. However, the true unit cell is rhombohedral and has dimensions: a<sub>r</sub>= 776 pm, ñ = 110.6ð, Z = 6 (5.98) molecules KB0
The dihydrate crystallizes in the triclinic crystal system, but is nearly monoclinic, with both ñ and ó very close to 90ð. The cell parameters are a = 678 pm , b = 1058A pm, c = 588 pm, ñ = 91.5ð, ò = 22.5ð, ó = 89ð, Z = 4, density 1.905 g/cm<sup>3</sup>. The refractive indices at 25ðC and wavelength 589.3 nm are ñ = 1.439, ò = 1.473, ó = 1.484. The dispersion is strong, greater at red than at violet.
The transition temperature between the dihydrate and the hemihydrate is 54 ðC. However, the crystalline dihydrate will remain metastable until 106 ðC to 110 ðC, and change slowly above that temperature.
Infrared spectroscopy of the vapor from anhydrous sodium metaborate, heated to between 900 ðC and 1400 ðC, shows mostly isolated clusters with formula , and some dimers thereof. Electron diffraction studies by Akishin and Spiridonov showed a structure with linear anion and angle of 90-110ð. The atomic distances are : 120 pm, : 136 pm,: 214 pm
Sodium metaborate is prepared by the fusion of sodium carbonate and boron oxide or borax . Another way to create the compound is by the fusion of borax with sodium hydroxide at 700 ðC:
The boiling point of sodium metaborate (1434 ðC) is lower than that of boron oxide (1860 ðC) and borax (1575 ðC) In fact, while the metaborate boils without change of composition, borax gives off a vapor of sodium metaborate with a small excess of sodium oxide .
The anhydrous salt can also be prepared from the tetraborate by heating to 270 ðC in vacuum.
Although not performed industrially, hydrolysis of sodium borohydride with a suitable catalyst gives sodium metaborate and hydrogen gas:
When sodium metaborate is dissolved in water, the anion combines with two water molecules to form the tetrahydroxyborate anion .
Electrolysis of a concentrated aqueous solution of 20% with an anion exchange membrane and inert anode (such as gold, palladium, or boron-doped diamond) converts the metaborate anion to tetraborate , and the sodium salt of the later (borax) precipitates as a white powder.
Sodium metaborate can be converted to sodium borohydride by several methods, including the reaction with various reducing agents at high temperatures and pressure, or with magnesium hydride by ball milling at room temperature, followed by extraction of the with isopropylamine.
Another method is the electrolytic reduction of a concentrated sodium metaborate solution, namely
However, this method is not efficient since it competes with the reduction of hydroxide:
Nanofiltration membranes can effectively separate the borohydride from the metaborate.
Anhydrous sodium metaborate refluxed with methanol yields the corresponding sodium tetramethoxyborate (melting point: 253-258 ðC, CAS number: 18024-69-6):
The analogous reaction with ethanol yields the sodium tetraethoxyborate.
Current and proposed applications of sodium metaborate include: