- 作者:Yannick Loqueta ; yannick.loquet@st.com ; yloqu@us.ibm.com ; Yann Mignota ; Christopher Waskiewiczb ; James Hsueh-Chung Chenb ; Muthumanickam Sankarapandianb ; Shyng-Tsong Chenb ; Philip Flaitzb ; Hideyuki Tomizawac ; Chia-Hsun Tsengb ; Marcy Beardb ; Bryan Morrisb ; Walter Kleemeiera ; E. Linigerb ; Terry Spoonerb
- 关键词:Lithography-Etch-Lithography-Etch ; Hard-mask removal ; BEOL ; Profile optimization ; 56 ; nm
- 刊名:Microelectronic Engineering
- 出版年:2013
- 出版时间:July, 2013
- 年:2013
- 卷:107
- 期:Complete
- 页码:138-144
- 全文大小:3346 K
Line Resistance and intra-level capacitance can be affected by the double patterning integration, but a good process window has been demonstrated, showing no impact on RC performance.
The introduction of a self-aligned via (SAV) process with a TiN hard-mask is able to provide a robust process window in terms of via-metal short yield at line and via level. SAV implementation at these dimensions also affects the aspect-ratio of the structures and leads to new challenges in metallization: optimized profile, without bowing or undercut, is mandatory to enable the filling of 28 nm lines.
The metal hard-mask has to be removed or at least faceted by erosion. This can be achieved by conventional RIE process optimization, but pushes the RIE selectivity to challenging limits. Physical dimensions on target and via chain yield have been demonstrated by fine tuning RIE process.
Profile improvement can also be achieved by the introduction of new WET process, helping the removal of the metal hard-mask while being neutral to the ULK. We have demonstrated good yield and reliability with an integration using hard-mask wet removal.