Modeling of Barrier-Engineered Charge-Trapping nand Flash Devices
IEEE Transactions on Device and Materials Reliability(2010)
摘要
Barrier-engineered charge-trapping NAND Flash (BE-CTNF) devices are extensively examined by theoretical modeling and experimental validation. A general analytical tunneling current equation for multilayer barrier is derived using the Wentzel-Kramers-Brillouin approximation. The rigorously derived analytical form is valid for both electron and hole tunnelings, as well as for any barrier composition. With this, the time evolution (Vt-time) of any BE-CTNF device during programming/erasing can be accurately simulated. The model is validated by experimental results from bandgap-engineered silicon-oxide-nitride-oxide-silicon and various structures using an Al2O3 top-capping layer. Using this model, various structures of BE-CTNF with high-κ tunneling or blocking dielectric are investigated. Finally, the impacts of barrier engineering on incremental-step pulse programming are examined.
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关键词
nand circuits,approximation theory,electron traps,flash memories,tunnelling,al2o3 top-capping layer,wentzel-kramers-brillouin approximation,analytical tunneling current equation,bandgap-engineered silicon-oxide-nitride-oxide-silicon,barrier-engineered charge-trapping nand flash devices,blocking dielectric,electron tunneling,high-κ tunneling,hole tunneling,incremental-step pulse programming,multilayer barrier,nand flash,barrier-engineered silicon–oxide–nitride–oxide–silicon (be-sonos),barrier engineering (be),charge-trapping device,incremental-step pulse programming (ispp),modeling,tunneling,genetic programming,dielectrics
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