Origin and Quantitative Description of the NESSIAS Effect at Si Nanostructures

Abstract

The electronic structure of low nanoscale (LNS) intrinsic silicon (i-Si) embedded in SiO2 vs. Si3N4 shifts away from vs. towards the vacuum level Evac, as described by the Nanoscale Electronic Structure Shift Induced by Anions at Surfaces (NESSIAS). Here, we fully explain the NESSIAS based on the quantum chemical properties of the elements involved. Deriving an analytic parameter Lambda to predict the highest occupied molecular orbital energy of Si nanocrystals (NCs), we use various hybrid-DFT methods and NC sizes to verify the accuracy of Lambda. We report on first experimental data of Si nanowells (NWells) embedded in SiO2 vs. Si3N4 by X-ray absorption spectroscopy in total fluorescence yield mode (XAS-TFY) which are complemented by ultraviolet photoelectron spectroscopy (UPS), characterizing their conduction band and valence band edge energies EC and EV, respectively. Scanning the valence band sub-structure by UPS over NWell thickness, we derive an accurate estimate of EV shifted purely by spatial confinement, and thus the actual EV shift due to NESSIAS. For 1.9 nm thick NWells in SiO2 vs. Si3N4, we get offsets of Delta EC = 0.56 eV and Delta EV = 0.89 eV, demonstrating a type II homojunction in LNS i-Si. This p/n junction generated by the NESSIAS eliminates any deteriorating impact of impurity dopants, offering undoped ultrasmall Si electronic devices with much reduced physical gate lengths and CMOS-compatible materials.