Specific Process Knowledge/Etch/AOE (Advanced Oxide Etch): Difference between revisions

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[[Category: Equipment|Etch AOE]]
[[Category: Etch (Dry) Equipment|AOE]]
{{CC1}}
== Etching using the dry etch technique AOE (Advanced oxide etch) ==
== Etching using the dry etch technique AOE (Advanced oxide etch) ==
[[Image:AOE.jpg|300x300px|thumb|AOE: positioned in cleanroom 2]]
[[Image:AOE.jpg|300x300px|thumb|AOE: positioned in cleanroom B-1, {{photo1}}]]
 
Name: M/PLEX ICP - AOE (Advanced Oxide Etcher) <br>
Vendor: STS (now SPTS) <br>
The AOE can be used for dry etching silicon oxide, silicon (oxy) nitride and quartz. Look in the manuals for the AOE to see how to operate the machine (you can find the manuals in LabManager on the AOE page).
 


The AOE can be used for etching silicon oxide, silicon (oxy)nitride and quartz. Look in the manuals for the AOE to see how to operate the machine (you can find the manuals in LabManager on the [http://labmanager.danchip.dtu.dk/machine/machine_item.php?refpage=machlist&id=115 AOE page]).
'''The user manual, quality control procedure and results, user APV, technical information and contact information can be found in LabManager:'''
<!-- remember to remove the type of documents that are not present -->


Currently all training on the AOE should be agreed with Berit Geilman Herstrøm. For training requests e-mail to [mailto:training@danchip.dtu.dk?Subject=AOE%20training training@danchip.dtu.dk]
<!-- give the link to the equipment info page in LabManager: -->
[http://labmanager.danchip.dtu.dk/function.php?module=Machine&view=view&mach=115  AOE in LabManager - requires login]


== Process information ==
== Process information ==


*[[Specific Process Knowledge/Etch/Etching of Silicon Oxide/SiO2 etch using AOE|Etch of Silicon Oxide using AOE]]
*[[Specific Process Knowledge/Etch/Etching of Silicon Oxide/SiO2 etch using AOE|Etch of Silicon Oxide]]
*[[/Si etch using AOE|Si mask etch using AOE]]
*[[/Si etch using AOE|Etch of Si]]
*[[/Remove resist in the AOE|Remove resist in the AOE]]
*[[/Remove resist in the AOE|Remove/etch resist/barc]]
*[[/Quartz etch using AOE|Quartz etch using AOE]]
*[[Specific Process Knowledge/Etch/Etching of Bulk Glass/AOE etching of fused silica|Etch of Fused Silica]]
<br clear="all" />
*[[/Quartz etch using AOE|Etch of Quartz - special very thick samples]]
*[[/Silicon Nitride Etch using AOE|Etch of Silicon Nitride]]


==A rough overview of the performance of AOE and some process related parameters==
===Limitations using the AOE===
====Wafer bow====
There is a limit to how much the wafer can bow and still be clamped on the chuck. The limit can maybe vary a little over time and may also depend on the material on the backside of the substrate. On a 100mm Si wafer with SiO2 on the backside (<10µm) we expect the limit to be around 50µm bow (when the back side surface is convex).
 
A bow will be created when etching the top oxide layer on a wafer with oxide on both sides. For a larger etch load the bow will be more severe for a specific etch depth when for a smaller etch load. I have been able to etch much deeper in SiO2 with a P-Si mask than with a photo resist mask on a wafer with 50% load. When using photoresist the wafer stopped clamping during the etch after just a few µm. With P-Si I could etch 15µm without problems. I expect this to be due to a combination of P-Si on the back side clamping much better and P-Si on the back side helping to reduce the bow.
 
====Transparent wafers====
Transparent wafers are a challenge for two reasons. 1. In the load lock the LASER detection system that is used to detect the wafer during mapping cannot detect a completely transparent wafer. 2. A transparent wafer is either quartz or fused silicon. These materials are very difficult to clamp electrostatically and will therefore not be able to pass the He leak up test successfully.
# The first issue may be overcome by using a non-transparent masking material or adding a non-transparent material on the back side of the wafer
#The second issue may be overcome by reducing the He back side pressure or reducing the He back side cooling completely. Another way to solve it is to either bond the transparent wafer to a silicon wafer before transferring it into chamber or deposit a more conducting/semiconducting layer on the backside of the wafer (could be silicon, maybe Chromium, please ask). 1-2µm P-Si may be enough, maybe even less.
 
==An overview of the performance of AOE and some process related parameters==


{| border="2" cellspacing="0" cellpadding="10"  
{| border="2" cellspacing="0" cellpadding="10"  
Line 29: Line 54:
|style="background:LightGrey; color:black"|Etch rates
|style="background:LightGrey; color:black"|Etch rates
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
~0.2-0.6 µm/min
~0.05-0.6 µm/min
|-
|-
|style="background:LightGrey; color:black"|Anisotropy
|style="background:LightGrey; color:black"|Anisotropy
Line 35: Line 60:
*Typical profiles: 86-90 degrees  
*Typical profiles: 86-90 degrees  
|-
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="2"|Process parameter range
!style="background:silver; color:black" align="left" valign="top" rowspan="4"|Process parameter range
|style="background:LightGrey; color:black"|Process pressure
|style="background:LightGrey; color:black"|Process pressure
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
*~2-20 mTorr
*~0.2-95 mTorr
|-
|style="background:LightGrey; color:black"|Process power
|style="background:WhiteSmoke; color:black"|
*Coil power: up to 3000W
*Platen power: up to 600W
|-
|style="background:LightGrey; color:black"|Platen temperature
|style="background:WhiteSmoke; color:black"|
*-10 to 60 degrees Celcius
|-
|-
|style="background:LightGrey; color:black"|Gas flows
|style="background:LightGrey; color:black"|Gas flows
|style="background:WhiteSmoke; color:black"|
|style="background:WhiteSmoke; color:black"|
*C<math>_4</math>F<math>_8</math>: 0-40 sccm
*C<sub>4</sub>F<sub>8</sub>: 0-40 sccm
*O<math>_2</math>: 0-100 sccm
*O<sub>2</sub>: 0-100 sccm
*CF<math>_4</math>: 0-100 sccm
*CF<sub>4</sub>: 0-100 sccm
*H<math>_2</math>: 0-30 sccm
*H<sub>2</sub>: 0-30 sccm
*He: 0-500 sccm
*He: 0-500 sccm
*N<math>_2</math>: 0-1000 sccm
*N<sub>2</sub>: 0-1000 sccm
*SF<math>_6</math>: 0-300 sccm
*SF<sub>6</sub>: 0-300 sccm
|-
|-
!style="background:silver; color:black" align="left" valign="top" rowspan="3"|Substrates
!style="background:silver; color:black" align="left" valign="top" rowspan="3"|Substrates

Latest revision as of 10:38, 3 February 2023

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Unless otherwise stated, this page is written by DTU Nanolab internal

Etching using the dry etch technique AOE (Advanced oxide etch)

AOE: positioned in cleanroom B-1, Photo: DTU Nanolab internal

Name: M/PLEX ICP - AOE (Advanced Oxide Etcher)
Vendor: STS (now SPTS)
The AOE can be used for dry etching silicon oxide, silicon (oxy) nitride and quartz. Look in the manuals for the AOE to see how to operate the machine (you can find the manuals in LabManager on the AOE page).


The user manual, quality control procedure and results, user APV, technical information and contact information can be found in LabManager:

AOE in LabManager - requires login

Process information

Limitations using the AOE

Wafer bow

There is a limit to how much the wafer can bow and still be clamped on the chuck. The limit can maybe vary a little over time and may also depend on the material on the backside of the substrate. On a 100mm Si wafer with SiO2 on the backside (<10µm) we expect the limit to be around 50µm bow (when the back side surface is convex).

A bow will be created when etching the top oxide layer on a wafer with oxide on both sides. For a larger etch load the bow will be more severe for a specific etch depth when for a smaller etch load. I have been able to etch much deeper in SiO2 with a P-Si mask than with a photo resist mask on a wafer with 50% load. When using photoresist the wafer stopped clamping during the etch after just a few µm. With P-Si I could etch 15µm without problems. I expect this to be due to a combination of P-Si on the back side clamping much better and P-Si on the back side helping to reduce the bow.

Transparent wafers

Transparent wafers are a challenge for two reasons. 1. In the load lock the LASER detection system that is used to detect the wafer during mapping cannot detect a completely transparent wafer. 2. A transparent wafer is either quartz or fused silicon. These materials are very difficult to clamp electrostatically and will therefore not be able to pass the He leak up test successfully.

  1. The first issue may be overcome by using a non-transparent masking material or adding a non-transparent material on the back side of the wafer
  2. The second issue may be overcome by reducing the He back side pressure or reducing the He back side cooling completely. Another way to solve it is to either bond the transparent wafer to a silicon wafer before transferring it into chamber or deposit a more conducting/semiconducting layer on the backside of the wafer (could be silicon, maybe Chromium, please ask). 1-2µm P-Si may be enough, maybe even less.

An overview of the performance of AOE and some process related parameters

Purpose Dry etch of
  • Silicon oxide
  • Silicon (oxy)nitride
  • Quartz
  • Silicon mask etching
Performance Etch rates

~0.05-0.6 µm/min

Anisotropy
  • Typical profiles: 86-90 degrees
Process parameter range Process pressure
  • ~0.2-95 mTorr
Process power
  • Coil power: up to 3000W
  • Platen power: up to 600W
Platen temperature
  • -10 to 60 degrees Celcius
Gas flows
  • C4F8: 0-40 sccm
  • O2: 0-100 sccm
  • CF4: 0-100 sccm
  • H2: 0-30 sccm
  • He: 0-500 sccm
  • N2: 0-1000 sccm
  • SF6: 0-300 sccm
Substrates Batch size
  • 1 6" wafer per run (only when the system is setup to 6")
  • 1 4" wafer per run
  • 1 2" wafer per run (needs carrier)
  • Or several smaller pieces (needs carrier)
Substrate material allowed
  • Silicon with layers of silicon oxide or silicon (oxy)nitride
  • Quartz wafers
Possible masking material
  • Photoresist/e-beam resist
  • Silicon/PolySi
  • Aluminium
  • Chromium