Abstract
Abstract Heterogeneous SiNx based charge trap flash (CTF) which has varying N/Si ratio ( x ) along the thickness of the charge-trapping layer (CTL) shows improved program/erase (P/E) transients. In this work, we present the P/E model invoking different nature of traps in N-rich and Si-rich CTL and investigate the physical processes behind the P/E improvement observed in heterogeneous CTF. A set of coupled equations that include Poisson's and rate equations for electrons and holes are solved considering the variation of CTL physical parameters along the thickness. The electron/hole injection current is accurately computed by including quantum effects at Si/SiO2 interface and taking into account the field-dependent relaxation of the energetic injected carriers. The simulation results of our model are in close agreement with the experimentally observed characteristics for five different sets of CTF devices with standard, Si-rich and N-rich homogeneous, and discretely and linearly graded heterogeneous CTF. Our study points out that the improvement in program transient for the heterogeneous CTF devices is attributed to the variation of trap density and trap energy along the CTL thickness and not due to lateral tunneling between the traps. The improvement in erase saturation and speed is due to high electron emission from the traps in Si-rich layer near bottom oxide of heterogeneous CTL.
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