Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology
The continual advancement of integrated circuits has seen the relentless scaling of minimum dimensions for semiconductor devices. Consequently, the burgeoning complexity of process technology and devices fabricated has necessitated advancements in device characterisation all through the failure anal...
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2020
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sg-ntu-dr.10356-1441322023-03-04T16:42:53Z Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology Teo, Wee Siang Gan Chee Lip School of Materials Science and Engineering Advanced Micro Devices (Singapore) Pte Ltd CLGan@ntu.edu.sg Engineering::Materials::Microelectronics and semiconductor materials The continual advancement of integrated circuits has seen the relentless scaling of minimum dimensions for semiconductor devices. Consequently, the burgeoning complexity of process technology and devices fabricated has necessitated advancements in device characterisation all through the failure analysis workflow. In particular, initial fault isolation techniques exploit infrared laser beams to probe the circuitry through silicon thinned mechanically to 50 um. Moving down to sub-20 nm process nodes, the infrared based lasers are challenged to resolve minute features as it hits its resolution limits. There is thus a need to use shorter wavelengths beam probes in the visible spectrum and beyond. However, visible light’s higher absorption coefficient in silicon necessitates silicon to be ultra-thinned to under 10 um to reduce signal attenuation. With existing contour milling techniques limited by its precision when ultra-thinning silicon, experiments were then conducted to understand key challenges in terms of the sample behaviour during thinning. Thereafter, a modified workflow was proposed to account for sample relaxation during ultra-thinning and tested on actual devices. With ultra-thinned samples prepared, challenges relating to the device’s thermal stability were then subsequently encountered. In overcoming these difficulties, targeted 2D and 3D thinning techniques were then explored and validated on actual devices prepared. In anticipation of further advanced probing techniques necessitating sub-micron remaining silicon thicknesses, focused ion beam milling techniques were then explored as a means to further localise ultrathin silicon to the area of interest. As a means for precise material removal, the milling rate was first characterised on different systems before the resulting milling finish was studied as a function of the beam parameters. The proposed workflow was then examined with its application on actual thinned devices. Process challenges and limitations were then discussed in relation to its application. Master of Engineering 2020-10-15T02:01:05Z 2020-10-15T02:01:05Z 2020 Thesis-Master by Research Teo, W. S. (2020). Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology. Master's thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/144132 10.32657/10356/144132 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University |
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Engineering::Materials::Microelectronics and semiconductor materials Teo, Wee Siang Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology |
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The continual advancement of integrated circuits has seen the relentless scaling of minimum dimensions for semiconductor devices. Consequently, the burgeoning complexity of process technology and devices fabricated has necessitated advancements in device characterisation all through the failure analysis workflow. In particular, initial fault isolation techniques exploit infrared laser beams to probe the circuitry through silicon thinned mechanically to 50 um. Moving down to sub-20 nm process nodes, the infrared based lasers are challenged to resolve minute features as it hits its resolution limits. There is thus a need to use shorter wavelengths beam probes in the visible spectrum and beyond. However, visible light’s higher absorption coefficient in silicon necessitates silicon to be ultra-thinned to under 10 um to reduce signal attenuation.
With existing contour milling techniques limited by its precision when ultra-thinning silicon, experiments were then conducted to understand key challenges in terms of the sample behaviour during thinning. Thereafter, a modified workflow was proposed to account for sample relaxation during ultra-thinning and tested on actual devices. With ultra-thinned samples prepared, challenges relating to the device’s thermal stability were then subsequently encountered. In overcoming these difficulties, targeted 2D and 3D thinning techniques were then explored and validated on actual devices prepared.
In anticipation of further advanced probing techniques necessitating sub-micron remaining silicon thicknesses, focused ion beam milling techniques were then explored as a means to further localise ultrathin silicon to the area of interest. As a means for precise material removal, the milling rate was first characterised on different systems before the resulting milling finish was studied as a function of the beam parameters. The proposed workflow was then examined with its application on actual thinned devices. Process challenges and limitations were then discussed in relation to its application. |
| author2 |
Gan Chee Lip |
| author_facet |
Gan Chee Lip Teo, Wee Siang |
| format |
Thesis-Master by Research |
| author |
Teo, Wee Siang |
| author_sort |
Teo, Wee Siang |
| title |
Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology |
| title_short |
Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology |
| title_full |
Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology |
| title_fullStr |
Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology |
| title_full_unstemmed |
Ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in Sub-20 nm technology |
| title_sort |
ultra-thin bulk silicon thinning of advanced microprocessors & graphics processors fabricated in sub-20 nm technology |
| publisher |
Nanyang Technological University |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/144132 |
| _version_ |
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