Location
Rochester Institute of Technology
Start Date
5-2015 12:00 AM
End Date
5-2015 12:00 AM
Description
Ferroelectric memory shows great promise as a high speed alternative to conventional memory architectures. Traditionally this memory has been constrained to niche applications due to the large size of ceramic-based ferroelectric devices. Doped hafnium dioxide measured on a newly-acquired aixACCT TF Analyzer 1000 is shown to have ferroelectricity an order of magnitude stronger than discrete PZT films that were measured, enabling further scaling while also simplifying fabrication via the elimination of ceramics from the process flow. Additionally, the presence of a TiN capping layer as well as a lower temperature, long duration anneal are shown to be key in obtaining a potential ferroelectric phase in hafnium dioxide.
Index Terms —Ferroelectricity, Hafnium Dioxide, FeFET.
Ferroelectric Hafnium Dioxide Thin Films
Rochester Institute of Technology
Ferroelectric memory shows great promise as a high speed alternative to conventional memory architectures. Traditionally this memory has been constrained to niche applications due to the large size of ceramic-based ferroelectric devices. Doped hafnium dioxide measured on a newly-acquired aixACCT TF Analyzer 1000 is shown to have ferroelectricity an order of magnitude stronger than discrete PZT films that were measured, enabling further scaling while also simplifying fabrication via the elimination of ceramics from the process flow. Additionally, the presence of a TiN capping layer as well as a lower temperature, long duration anneal are shown to be key in obtaining a potential ferroelectric phase in hafnium dioxide.
Index Terms —Ferroelectricity, Hafnium Dioxide, FeFET.