Title :
Combined effect of X-irradiation and forming gas anneal on the hot-carrier response of MOS oxides
Author :
Milanowski, R.J. ; Pagey, M.P. ; Matta, A.I. ; Bhuva, B.L. ; Massengill, L.W. ; Kerns, S.E.
Author_Institution :
Dept. of Electr. Eng., Vanderbilt Univ., Nashville, TN, USA
fDate :
12/1/1993 12:00:00 AM
Abstract :
Process-radiation-induced defects and hot-carrier instability in n-channel transistors subjected to simulated X-ray lithography have been studied. Using optically assisted electron injection (photoinjection), two specific instability mechanisms were investigated. These mechanisms are trapping of electrons at Coulombic centers in the bulk oxide and depassivation/passivation of interface traps by hydrogen originating in the bulk oxide. Devices treated with a standard forming gas anneal after X-irradiation show residual, but minor, susceptibility to hot-carrier-induced instability via both these mechanisms. These results can be explained by the presence of postanneal neutral electron traps and the failure of the forming gas anneal to fully restore the preirradiation hydrogen-transport properties of the oxide
Keywords :
X-ray effects; X-ray lithography; annealing; electron traps; hot carriers; insulated gate field effect transistors; interface electron states; semiconductor device testing; Coulombic centers; MOS oxides; MOSFET; Si-SiO2; SiO2; SiO2:H2; X-ray irradiation; depassivation/passivation; forming gas anneal; hot-carrier instability; hot-carrier response; interface traps; n-channel transistors; optically assisted electron injection; postanneal neutral electron traps; process-radiation-induced defects; simulated X-ray lithography; Annealing; Bonding; Electron optics; Electron traps; Flexible printed circuits; Hot carrier effects; Hot carriers; Ionizing radiation; Lithography; Optical devices;
Journal_Title :
Nuclear Science, IEEE Transactions on
