Laser induced surface nitriding of niobium: phase evolution and superconducting behaviour

Abstract

Laser nitriding represents a versatile approach for tailoring the surface properties of metals. Up to now, its effect on the superconducting response of niobium nitrides remains largely unexplored. In this work, the nitriding process of niobium by laser irradiation under a controlled nitrogen atmosphere up to 2.50 bar, using a nanosecond pulsed laser with wavelength of 1064 nm has been investigated. By independently tuning the nitrogen pressure, the two-dimensional accumulated fluence (F2D) and the laser irradiance, a laser-processing map for the formation of either a combination of β-Nb2N (hexagonal) and γ-Nb4N3 x (tetragonal) phases or only the β-phase has been established. Systematic analysis by X-ray diffraction, scanning electron microscopy and electron backscatter diffraction revealed that the nitrogen-rich γ-phase forms in the near-surface layer through melting when F2D exceeds a certain value (> 50 \,kJ/cm2 at 2.50 bar). A β-layer is observed underneath, and further inside, there is a band of embedded β-grains in the Nb matrix. Their size gradually decreases with increasing distance to surface, suggesting thermal gradients and a diffusion formation mechanism. When the γ-phase becomes predominant, a significant increase in the superconducting critical temperature is observed, up to Tc ≈ 15\,K, and magnetic irreversibility. For low F2D values (≈ 7.5 \,kJ/cm2 at 1.50-2.50 bar), the formation of a uniform nitride layer composed of sub-micron-sized β-Nb2N grains results in a ca. fourfold enhancement in surface microhardness. These findings provide fundamental insights into laser-induced nitriding of niobium to engineer mechanically robust and superconducting Nb-N layers.