Effect of cubic and hexagonal boron nitride additions on the microstructure and properties of bulk MgB2 superconductors

MgB2 is a promising material for intermediate temperature applications where conventional low temperature superconductors cannot be used, especially if the range of magnetic fields over which is has acceptable current carrying performance can be expanded. However, its applicability is limited by poor properties at elevated magnetic fields. Carbon-based dopants can be used to dramatically improve the high-field performance of MgB2, but at the cost of a reduction in the superconducting transition temperature (T (c)) that limits the operation temperature to 20 K or below. Here we report an enhancement of superconducting performance of MgB2 with the addition of cubic and hexagonal boron nitride (BN), without any significant reduction in T (c). Ex-situ bulk samples of MgB2 with two forms of BN addition were manufactured by the field assisted sintering technique after high energy ball milling of powder mixtures. We find that hexagonal BN (hBN) nanoparticles mixed homogenously with MgB2 powder react much more easily to produce Mg-N-B impurities than larger cubic BN (cBN) particles (similar to 10 mu m) under the same processing conditions. The addition of 1 wt% hBN or 5 wt% cBN combined with 6 h of milling has been demonstrated to improve the critical current density (J (c)) of MgB2 over the entire magnetic field range. It is proposed that the nano-sized Mg-N-B impurities, that typically reside at MgB2 grain boundaries, increase pinning strength by introducing additional flux pinning centres. In addition, excess Mg may benefit the low-field performance by improving the connectivity. This work shows the significance of microstructural characterization on inhomogeneous superconducting materials to analyse their performance.

Automated summary

The addition of hexagonal and cubic boron nitride can enhance the superconducting performance of MgB2 without reducing the superconducting transition temperature. Hexagonal boron nitride nanoparticles mixed with MgB2 powder easily react to produce Mg-N-B impurities, while larger cubic boron nitride particles do not. Adding 1 wt% hexagonal boron nitride or 5 wt% cubic boron nitride, after 6 hours of milling, has been shown to improve the critical current density of MgB2 over the entire magnetic field range.