Specific Process Knowledge/Etch/DRIE-Pegasus/Pegasus-2/Si Nano etching: Difference between revisions

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'''Feedback to this page:  
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[mailto:labadviser@danchip.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.danchip.dtu.dk/index.php/Specific_Process_Knowledge/Etch/DRIE-Pegasus/Pegasus-2/Si_Nano_etching click here]'''
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<!-- Page reviewed 9/8-2022 jmli -->
 


The CORE sequence (meaning Clear, Oxidize, Remove and Etch) is a fluorocarbon-free directional plasma etch procedure that enables a higher selectivity, creates pattern independence of etching profiles and works excellent at room temperature. The CORE process resembles the well-known SF<sub>6</sub>-based Bosch process, but the usual C<sub>4</sub>F<sub>8</sub> inhibitor is replaced by O<sub>2</sub> oxidation with self-limiting characteristics. Therefore the CORE result is similar to Bosch, however has the advantage of preventing the pile-up of fluorocarbon deposits at the topside of deep-etched or nano-sized features. At the same time, process drift is minimized as the reactor wall is staying perfectly clean. The CORE process has shown an excellent performance in high aspect ratio (3D) nanoscale structures with an accurate and controllable etch rate between 1 and 50 nm min<sup>−1</sup> (and SiO<sub>2</sub>-selectivity of ca. 35) using the etch-tool in the RIE-mode. By adding the ICP source (DRIE-mode), a directional etch rate up to 1 μm min<sup>−1</sup> (at 50 sccm SF<sub>6</sub> flow) and selectivity >200 for SiO<sub>2</sub> is possible.
The CORE sequence (meaning Clear, Oxidize, Remove and Etch) is a fluorocarbon-free directional plasma etch procedure that enables a higher selectivity, creates pattern independence of etching profiles and works excellent at room temperature. The CORE process resembles the well-known SF<sub>6</sub>-based Bosch process, but the usual C<sub>4</sub>F<sub>8</sub> inhibitor is replaced by O<sub>2</sub> oxidation with self-limiting characteristics. Therefore the CORE result is similar to Bosch, however has the advantage of preventing the pile-up of fluorocarbon deposits at the topside of deep-etched or nano-sized features. At the same time, process drift is minimized as the reactor wall is staying perfectly clean. The CORE process has shown an excellent performance in high aspect ratio (3D) nanoscale structures with an accurate and controllable etch rate between 1 and 50 nm min<sup>−1</sup> (and SiO<sub>2</sub>-selectivity of ca. 35) using the etch-tool in the RIE-mode. By adding the ICP source (DRIE-mode), a directional etch rate up to 1 μm min<sup>−1</sup> (at 50 sccm SF<sub>6</sub> flow) and selectivity >200 for SiO<sub>2</sub> is possible.


'''The CORE recipe is shown as below'''
'''The CORE recipe is shown as below'''
[[File:CORE.png|800px|thumb|left]]
 
[[File:CORE.png|800px]]
 
The CORE cycle design rules and optimized recipe for the etch rate  fixed at 15 nm\min
 
 
'''Rule 1''': 2 min E-time needs 2 s O-time. Every 2 min extra E-time will need 1 s extra O-time until a maximum of 14 min E-time.
 
'''Rule 2''': Every second of O-time needs at least 3 s R-time (for 8 min E-time).
 
'''Rule 3''': The undercut is roughly half of the gained etch depth per CORE cycle.
 
 
Silicon wafers are prepared with 1.5 μm thick resist patterns (AZ MIR 701 DUV resist from MicroChemicals) and exposed using a maskless aligner (MLA150, Heidelberg) to create patterns above 400 nm.
 
For nanosized patterns between 30 and 100 nm, an electron beam writing system (JEOL JBX-9500FSZ)  is used with positive tone e-beam resist ZEP520A (ZEON).
 
 
Below are some SEM images of the silicon nanostructures achieved by the CORE process:
 
 
[[File:Fig 13a.png|800px|left|thumb|'''''Submicron silicon trenches and lines derived from the fine-tuned CORE sequence.''''']]
 
 
[[File:Fig 13b.png|800px|left|thumb|'''''Submicron silicon holes derived from the fine-tuned CORE sequence. The side wall angle is ca. 2°.''''' ]]
 
 
[[File:Fig 13c.png|800px|left|thumb|'''''Submicron silicon pillars derived from the fine-tuned CORE sequence.''''' ]]
 
 
[[File:Fig 13d - 1.png|800px|left|thumb|'''''Notch-free nanostructures in SOI material derived from the fine-tuned CORE sequence.(Left) Grating with 80 nm periodicity. (Right) RIE lag test structure between 30 and 100 nm.''''']]
<br clear="all" />
For more details, please contact Henri Jansen (henrija@dtu.dk) or Vy Thi Hoang Nguyen (vthongu@dtu.dk).

Latest revision as of 10:37, 9 August 2022

Feedback to this page: silicon etching with SF6 and O2 click here


The CORE sequence (meaning Clear, Oxidize, Remove and Etch) is a fluorocarbon-free directional plasma etch procedure that enables a higher selectivity, creates pattern independence of etching profiles and works excellent at room temperature. The CORE process resembles the well-known SF6-based Bosch process, but the usual C4F8 inhibitor is replaced by O2 oxidation with self-limiting characteristics. Therefore the CORE result is similar to Bosch, however has the advantage of preventing the pile-up of fluorocarbon deposits at the topside of deep-etched or nano-sized features. At the same time, process drift is minimized as the reactor wall is staying perfectly clean. The CORE process has shown an excellent performance in high aspect ratio (3D) nanoscale structures with an accurate and controllable etch rate between 1 and 50 nm min−1 (and SiO2-selectivity of ca. 35) using the etch-tool in the RIE-mode. By adding the ICP source (DRIE-mode), a directional etch rate up to 1 μm min−1 (at 50 sccm SF6 flow) and selectivity >200 for SiO2 is possible.

The CORE recipe is shown as below

The CORE cycle design rules and optimized recipe for the etch rate fixed at 15 nm\min


Rule 1: 2 min E-time needs 2 s O-time. Every 2 min extra E-time will need 1 s extra O-time until a maximum of 14 min E-time.

Rule 2: Every second of O-time needs at least 3 s R-time (for 8 min E-time).

Rule 3: The undercut is roughly half of the gained etch depth per CORE cycle.


Silicon wafers are prepared with 1.5 μm thick resist patterns (AZ MIR 701 DUV resist from MicroChemicals) and exposed using a maskless aligner (MLA150, Heidelberg) to create patterns above 400 nm.

For nanosized patterns between 30 and 100 nm, an electron beam writing system (JEOL JBX-9500FSZ) is used with positive tone e-beam resist ZEP520A (ZEON).


Below are some SEM images of the silicon nanostructures achieved by the CORE process:


Submicron silicon trenches and lines derived from the fine-tuned CORE sequence.


Submicron silicon holes derived from the fine-tuned CORE sequence. The side wall angle is ca. 2°.


Submicron silicon pillars derived from the fine-tuned CORE sequence.


Notch-free nanostructures in SOI material derived from the fine-tuned CORE sequence.(Left) Grating with 80 nm periodicity. (Right) RIE lag test structure between 30 and 100 nm.


For more details, please contact Henri Jansen (henrija@dtu.dk) or Vy Thi Hoang Nguyen (vthongu@dtu.dk).

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