Articles you may be interested inComplete band offset characterization of the HfO 2 / SiO 2 / Si stack using charge corrected x-ray photoelectron spectroscopy Structural and electronic properties of boron nitride thin films containing siliconAlthough an increasing volume of x-ray photoemission spectroscopic ͑XPS͒ data has been accumulated on boron and boron-rich compounds because of their unusual properties, including a unique three-center, two-electron bonding configuration, their common nonmetallic nature has been overlooked. Typically, the measured energy-state data are not clarified by surface Fermi level positions of these nonmetallic samples, which compromises the scientific contents of the data. In the present study, we revisited the XPS studies of sputter-cleaned -rhombohedral boron ( r -B), the oxidized surface of  r -B, B 6 O pellet, and polished B 2 O 3 , to illustrate the impact and resolution of this scientific issue. These samples were chosen because  r -B is the most thermodynamically stable polytype of pure boron, B 2 O 3 is its fully oxidized form, and B 6 O is the best known superhard family member of boron-rich compounds. From our XPS measurements, including those from a sputter-cleaned gold as a metal reference, we deduced that our  r -B had a surface Fermi level located at 0.7Ϯ0.1 eV from its valence-band maximum ͑VBM͒ ͑referred as E FL ) and a binding energy for its B 1s core level at 187.2 eV from VBM (E b,VBM ). The latter attribute, unlike typical XPS binding energy data that are referenced to a sample-dependent Fermi level (E b,FL ), is immune from any uncertainties and variations arising from sample doping and surface charging. For bulk B 2 O 3 , we found an E b,VBM for its B 1s core level at 190.5 eV and an E b,FL at 193.6 eV. For our  r -B subjected to a surface oxidation treatment, an overlayer structure of ϳ1.2 nm B 2 O 3 / ϳ2 nm B 2 O/B was found. By comparing the data from this sample and those from  r -B and bulk B 2 O 3 , we infer that the oxide overlayer carried some negative fixed charge and this induced on the semiconducting  r -B sample an upward surface band bending of ϳ0.6 eV. As for our B 6 O sample, we found an E FL of ϳ1.7 eV and two different chemical states having E b,VBM of 185.4 and 187.2 eV, with the former belonging to boron with no oxygen neighbor and the latter to boron with an oxygen neighbor. The methodology in this work is universally applicable to all nonmetallic samples.
