Charge trapping properties at silicon nitride/silicon oxide interface studied by variable-temperature electrostatic force microscopy

Abstract

Charge trapping properties of electrons and holes in ultrathin nitride-oxide-silicon (NOS) structures were quantitatively determined by variable-temperature electrostatic force microscopy (EFM). From charge retention characteristics obtained at temperatures between 250 and 370°C and assuming that the dominant charge decay mechanism is thermal emission followed by oxide tunneling, we find that there are considerable deep trap centers at the nitride-oxide interface. For electron, the interface trap energy and density were determined to be about 1.52eV and 1.46×1012cm−2, respectively. For hole, these are about 1.01eV and 1.08×1012cm−2, respectively. In addition, the capture cross section of electron can be extracted to be 4.8×10−16cm2. The qualitative and quantitative determination of charge trapping properties and possible charge decay mechanism reported in this work can be very useful for the characterization of oxide-nitride-silicon based charge storage devices.