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We report the growth of AlBN/β‐Nb 2 N nitride epitaxial heterostructures in which the AlBN is ferroelectric, and β‐Nb 2 N with metallic resistivity ≈40 μ at 300 K becomes superconducting below T C ≈ 0.5 K. Using nitrogen plasma molecular beam epitaxy, we grow hexagonal β‐Nb 2 N films on c‐plane Al 2 O 3 substrates, followed by wurtzite AlBN. The AlBN is in epitaxial registry and rotationally aligned with the β‐Nb 2 N, and the hexagonal lattices of both nitride layers make angles of 30° with the hexagonal lattice of the Al 2 O 3 substrate. The B composition of the AlBN layer is varied from 0 to 14.7%. It is found to depend weakly on the B flux, but increases strongly with decreasing growth temperature, indicating a reaction rate‐controlled growth. The increase in B content causes a non‐monotonic change in the a‐lattice constant and a monotonic decrease in the c‐lattice constant of AlBN. Sharp, abrupt epitaxial AlBN/β‐Nb 2 N/Al 2 O 3 heterojunction interfaces and close symmetry matching are observed by transmission electron microscopy. The observation of ferroelectricity and superconductivity in epitaxial nitride heterostructures opens avenues for novel electronic and quantum devices.
Savant et al. (Thu,) studied this question.
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