X-ray photoelectron spectroscopy (XPS) and static secondary ion mass spectrometer (SSIMS) have been
applied to characterize Si(111) surface treated with 40% NH4F solution. As-treated Si(111) surface is
predominately terminated with monohydrides and free of contamination. The dynamics of etching process on
ultra-clean atomically flat hydrogen-terminated Si(111) surface in 40% NH4F solution has been examined at
various potentials including the open circuit potential (OCP) by using in situ electrochemical scanning tunneling
microscopy (ECSTM). Two distinct mechanisms are observed: (1) dihydride terminated step silicon atoms
are dissolved much faster than the defect-free monohydride terminated ones; (2) dihydrides in the corner of
{110} zigzag enclosed characteristic triangular pits lead to fast erosion of silicon atoms. Our results explain
dynamic mechanics in formation of triangular pits on atomically flat silicon (111) surface in solution.
The aim of this work was to build a thermodynamic energy band diagram for the system of n-type Si͑100͒/HF that is in dynamic equilibrium at the interface. The construction concept was based on the shift of energy levels such as Fermi energy (E F ), conduction band energy (E c ), and valence band energy (E v ) before and after the contact of silicon with HF solutions. Through measurements of the open-circuit potential and flatband voltage (V FB ), the energy band diagram for the Si/HF system was established. This diagram was useful in estimating the activation energy for the photoelectrochemical etching system. The kinetic study demonstrated that the etching rate of the silicon increases to a maximum with an increase in HF concentration from 0.5 to 2.0 M, then decreases with further increase of the HF concentration. Based on the energy band diagram established and the electrochemical kinetic data measured, we discuss in detail the etching rate of the n-Si/HF and make clear the concentration effect of HF on the photoelectrochemical reaction.
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