Boron Carbide: A New Imitation Black Diamond

This 1.04 ct black submetallic round brilliant, initially represented as diamond, was identified as boron carbide. Photo by G. Choudhary.
Figure 1. This 1.04 ct black submetallic round brilliant, initially represented as diamond, was identified as boron carbide. Photo by G. Choudhary.
As black diamond has gained popularity in the past few years, so have aggregates of black synthetic moissanite and crystalline silicon (Spring 2011 Lab Notes, pp. 54–55). One specimen received by the Gem Testing Laboratory in Jaipur, a 1.04 ct black submetallic round brilliant (figure 1), appeared to be synthetic black moissanite but proved otherwise. The specimen was presented to the owner as a diamond.

Due to the prevalence of black synthetic moissanite in the marketplace and laboratories, we immediately checked for the typical aggregate structure under the microscope. Although a granular pattern was distinctly visible in reflected light (figure 2), it was much denser and finer than the kind usually seen in black synthetic moissanite. This raised uncertainty, so additional gemmological tests were performed. The specimen had an over-the-limit RI, an SG of 2.43, and a hardness above 9 on the Mohs scale. The low SG value ruled out the possibility of synthetic moissanite (3.22), but otherwise offered no clues as to the specimen’s identity.

Boron Carbide Black Diamond Simulant
Figure 2. Under reflected light, the boron carbide specimen displayed a dense fine granular structure typically associated with aggregates such as ceramics. Photomicrograph by G. Choudhary; magnified 48x.
Qualitative EDXRF analysis revealed Fe with traces of Si and K. Raman spectra taken from several points using 532 nm laser excitation showed major peaks at approximately 260, 320, 480, 532, 720 and 1088 cm-1, with smaller peaks at about 800,824, 874, 967, and 998 cm-1. This combination of features did not match anything in our database, but an extensive literature search revealed an exact match with the Raman spectra of boron carbide (V. Domnich et al., “Boron carbide: Structure, properties, and stability under stress”, Journal of the American Ceramic Society, Vol. 94, No. 11, 2011, pp. 3605–3628).    

Boron carbide is an advanced ceramic material with high hardness, low density, thermal stability and extreme abrasive resistance, making it suitable for nuclear, military and aerospace applications. The material is typically produced by reacting and fusing carbon with boric oxide (B2O3) in an electric arc furnace, followed by a sintering process of hot pressing in graphite dies in a vacuum or an argon atmosphere at temperatures of 1900–2200oC and pressures of 0.02–0.04 GPa for 15–45 minutes (Singhal and Singh, “Sintering of boron carbide under high pressures and temperatures”, Indian Journal of Engineering and Materials Sciences, Vol. 13, April 2006, pp. 129–134).
Although boron carbide is common in engineering and materials science—uses such as scratch-resistant coating and plating in tank armour, bulletproof vests and padlocks—this was our first encounter with it as a diamond simulant. Research also did not reveal any gemmological uses of this ceramic product. Distinguishing boron carbide from black diamond or synthetic moissanite was straightforward based on SG, but Raman spectra and reference data were needed for identification. The possibility of market penetration cannot be ruled out.

Acknowledgement: Mr Sandeep Vijay, staff gemmologist at the Gem Testing Laboratory, for conducting a thorough literature search.

Gagan Choudhary is the Deputy Director at the Gem Testing Laboratory in Jaipur, India and a regular Gems & Gemmology contributor. He can be contacted at