Title :
Gate Leakage for 28 nm Stacked HfZrOx Dielectric of p-Channel MOSFETs After Decoupled Plasma Nitridation Treatment With Annealing Temperatures
Author :
Shea-Jue Wang ; Mu-Chun Wang ; Win-Der Lee ; Jie-Min Yang ; Huang, L.S. ; Heng-Sheng Huang
Author_Institution :
Dept. of Mater. & Resources Eng., Nat. Taipei Univ. of Technol., Taipei, Taiwan
Abstract :
Choosing a plasma nitridation treatment with some annealing technique incorporated into the gate engineering is helpful to fix the existence of oxygen vacancy and promote the crystallization temperature in high-k dielectric. Here is the higher annealing atmosphere as a whole providing the better drive current in p-channel metal-oxide-semiconductor field-effect transistors, compared with the lower one. The interface traps for the former, however, is slightly greater than the latter, causing a higher gate leakage in the middle electrical field operated at inversion mode. This phenomenon is more obvious in the tested short-channel device. A sandwich type of HfOx/ZrOy/HfOx as gate dielectric at 28 nm node process is a fine selection to withstand or decrease the possibility of the formation of micro- or nanocrystallization increasing the gate leakage.
Keywords :
MOSFET; annealing; crystallisation; hafnium compounds; high-k dielectric thin films; nitridation; plasma deposition; semiconductor device breakdown; zirconium compounds; HfOx-ZrOy-HfOx; annealing temperatures; crystallization temperature; decoupled plasma nitridation treatment; gate engineering; gate leakage; high-k dielectric; middle electrical field; oxygen vacancy; p-channel MOSFET; size 28 nm; stacked dielectric; Annealing; Dielectrics; Gate leakage; Logic gates; MOSFET; MOSFET circuits; Annealing; MOSFET; decoupled plasma nitridation (DPN); gate leakage; high- $k$ dielectric; high-k dielectric;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2014.2349005
