Structural and electronic properties of stoichiometric single-phase CrN(001) thin films grown on MgO(001) substrates by radio-frequency N plasma-assisted molecular-beam epitaxy, are investigated. In situ room-temperature scanning tunneling microscopy clearly shows the 1 ϫ 1 atomic periodicity of the crystal structure as well as long-range topographic distortions which are characteristic of a semiconductor surface. This semiconductor behavior is consistent with ex situ resistivity measurements over the range 285 K and higher, whereas below 260 K, metallic behavior is observed. The resistivity-derived band gap for the high-temperature region, 71 meV, is consistent with the tunneling spectroscopy results. The observed electronic (semiconductor/metal) transition temperature coincides with the temperature of the known coincident magnetic (para-antiferro) and structural (cubic-orthorhombic) phase transitions.For many years, CrN has received a lot of attention due to its high hardness and corrosion resistance. 1,2 In addition, CrN is also interesting due to its magnetic, optical, and electronic properties. It is known that CrN is paramagnetic (PM) with a B1 NaCl crystal structure at room temperature; at T Néel , reported in the range of 273-283 K, the material undergoes a phase transition to antiferromagnetic (aFM) with an orthorhombic P nma crystal structure. [3][4][5] found theoretically that the magnetic stress is the driving force for the lattice distortions, and thus linked the magnetic and structural transitions. So far, however, the electronic properties have been less understood.Filippetti et al. 5 reported, based on theoretical calculations, that CrN is a metal in its PM state but a weak metal in the aFM state. This agrees well with an earlier experimental work, based on CrN polycrystalline powders, which found metallic behavior with, however, an abrupt increase of the resistivity with increasing temperature at ϳ286 K. 7 On the other hand, Herle et al., 8 based on synthesized CrN powders, reported that CrN is a semiconductor with a band gap of 90 meV as measured by resistivity. Recently, Gall et al. 9 grew crystalline thin films of CrN by sputtering and reported that CrN behaves as a semiconductor (Mott-type insulator) with an optical gap of 0.7 eV. Although the electronic behavior at room temperature has become more clear, the value of the band gap as well as its detailed nature, remain to be determined; moreover, the discrepant results reported for low temperatures, remain to be resolved.In this letter, we present results concerning the unique structural and electronic properties of CrN(001). We show that high-quality epitaxial layers are grown by molecularbeam epitaxy (MBE), having crystalline (001) orientation and atomically smooth surface [as measured by scanning tunneling microscopy (STM)] and semiconducting behavior at 300 K. Bulk ex situ measurements confirm the semiconducting behavior at 300 K, but furthermore a transition to the metallic state is observed at ϳ285 K. This transition coincides with the ...
