Title :
A study of barrier engineered Al2O3 and HfO2 high-K charge trapping devices (BE-MAONOS and BE-MHONOS) with optimal high-K thickness
Author :
Lai, Sheng-Chih ; Chen, Chih-Ping ; Du, Pei-Ying ; Lue, Hang-Ting ; Heh, Dawei ; Shen, Chih-Yen ; Hsueh, F.K. ; Wu, H.Y. ; Liao, Jeng-Hwa ; Hsieh, Jung-Yu ; Wu, M.T. ; Hsu, F.H. ; Hong, S.P. ; Yeh, C.T. ; Hung, Yung-Tai ; Hsieh, Kuang-Yeu ; Lu, Chih-Yuan
Author_Institution :
Emerging Central Lab., Macronix Int. Co., Ltd., Hsinchu, Taiwan
Abstract :
The behavior of barrier engineered charge trapping devices incorporating Al2O3 and HfO2 high-K layers has been critically examined. We propose to use a thicker buffer oxide (≫ 6 nm) and thin (≪5nm) high-K top capping layer for BE-MAONOS and BE-MHONOS in order to improve the reliability. Thinner high-K top capping layer reduces the fast initial charge loss under high-temperature baking. Moreover, it also reduces the undesired transient read current relaxation. These effects are due to the bulk trapped charge in high-K material during programming/erasing. By reducing the high-K thickness these reliability issues can be minimized. We also found that HfO2 has a better thickness scaling capability than Al2O3. Finally, a high-performance BE-SHONOS (with n+-poly gate and HfO2 top capping layer) transistor is demonstrated in this work.
Keywords :
aluminium compounds; hafnium compounds; high-k dielectric thin films; Al2O3; BE-MAONOS; BE-MHONOS; HfO2; barrier engineered charge trapping devices; high-K charge trapping devices; high-K material; optimal high-K thickness; reliability issues; transient read current relaxation; Aluminum oxide; Channel bank filters; Dielectric thin films; Electrons; Hafnium oxide; High K dielectric materials; High-K gate dielectrics; Laboratories; Silicon compounds; Tunneling;
Conference_Titel :
Memory Workshop (IMW), 2010 IEEE International
Conference_Location :
Seoul
Print_ISBN :
978-1-4244-6719-8
Electronic_ISBN :
978-1-4244-7668-8
DOI :
10.1109/IMW.2010.5488382
