Title :
Modeling of tunneling currents through HfO2 and (HfO2)x(Al2O3)/sub 1-x/ gate stacks
Author :
Hou, Y.T. ; Li, M.-F. ; Yu, H.Y. ; Kwong, D.L.
Author_Institution :
Silicon Nano Device Lab., Nat. Univ. of Singapore, Singapore
Abstract :
We present a physical modeling of tunneling currents through ultrathin high-/spl kappa/ gate stacks, which includes an ultrathin interface layer, both electron and hole quantization in the substrate and gate electrode, and energy band offsets between high-/spl kappa/ dielectrics and Si determined from high-resolution XPS. Excellent agreements between simulated and experimentally measured tunneling currents have been obtained for chemical vapor deposited and physical vapor deposited HfO/sub 2/ with and without NH/sub 3/-based interface layers, and ALD Al/sub 2/O/sub 3/ gate stacks with different EOT and bias polarities. This model is applied to more thermally stable (HfO/sub 2/)/sub x/(Al/sub 2/O/sub 3/)/sub 1-x/ gate stacks in order to project their scalability for future CMOS applications.
Keywords :
CMOS integrated circuits; CVD coatings; MOS capacitors; MOSFET; X-ray photoelectron spectra; alumina; dielectric thin films; hafnium compounds; semiconductor device models; sputtered coatings; thermal stability; tunnelling; (HfO/sub 2/)/sub x/(Al/sub 2/O/sub 3/)/sub 1-x/; (HfO/sub 2/)/sub x/(Al/sub 2/O/sub 3/)/sub 1-x/ ultrathin high-/spl kappa/ gate stacks; ALD Al/sub 2/O/sub 3/ gate stacks; CMOS scaling; EOT; HfO/sub 2/; HfO/sub 2/ ultrathin high-/spl kappa/ gate stacks; MOS capacitor structure; bias polarities; chemical vapor deposited films; electron quantization; energy band offsets; high-resolution XPS; hole quantization; n-MOSFETs; physical modeling; physical vapor deposited films; thermally stable gate stacks; tunneling currents; ultrathin interface layer; Charge carrier processes; Chemicals; Current measurement; Dielectric measurements; Dielectric substrates; Electrodes; Hafnium oxide; Quantization; Semiconductor device modeling; Tunneling;
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2002.807708
