Stepper 3 (ASML DUV): Difference between revisions

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|super= Demis D. John
|super= Demis D. John
|location=Bay 7
|location=Bay 7
|description = ASML PAS 5500/300 DUV Stepper
|description = Deep-UV Stepper Photolithography
|model = PAS 5500/300
|manufacturer = [http://www.asml.com ASML]
|manufacturer = [http://www.asml.com ASML]
|ToolType = Lithography
|ToolType = Lithography
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==About==
==About==


===General Capabilities/Overview===
The ASML 5500 stepper is a 248nm DUV stepper for imaging dense features down to below 200nm and isolated line structures down to below 150nm. Overlay accuracy is better than 30nm.
The ASML 5500 stepper is a 248nm (KrF) DUV stepper for imaging dense features down to below 200nm and isolated line structures down to below 150nm (with effort). 300nm+ features are relatively "easy" to resolve. Layer-to-layer overlay accuracy is better than 30nm.


The system is configured for 4” wafers and, with staff support, mounted pieces down to 14mm in size can be exposed using a 4” wafer as a carrier. The system is designed for high throughput, so shooting multiple 4" wafers is extremely fast. Additionally, exposure jobs are highly programmable, allowing for very flexible exposures of multiple aligned patterns from multiple masks in a single session, allowing for process optimization of large vs. small features in a single lithography.
The system is configured for 4” wafers. The system is designed for high throughput, so shooting multiple 4" wafers is extremely fast, typically minutes per wafer, but any size other than 4-inch is difficult to work with (see below for more info). Additionally, exposure jobs are highly programmable, allowing for very flexible exposures of multiple aligned patterns from multiple masks/reticles in a single session, allowing for process optimization of large vs. small features in a single lithography.


The full field useable exposure area is limited to the intersection of a 31mm diameter circle and a rectangle of dimensions 22mm x 27mm. See the [[ASML 5500 Mask Making Guidelines|Mask Making Guidelines page]] for more info on exposure field sizes and how to order your mask plates.
The full field useable exposure area is limited to the intersection of a 31mm diameter circle and a rectangle of dimensions 22mm x 27mm. Users have stitched multiple photomasks together with success. See the [[ASML 5500 Mask Making Guidelines|Mask Making Guidelines page]] for more info on exposure field sizes and how to order your mask plates.


'''Tutorial:''' If you are not familiar with the differences between Contact Litho and Stepper Litho, please review this short tutorial: [https://wiki.nanofab.ucsb.edu/w/images/c/cb/Demis_D_John_-_Stepper_Reticle_Layout_vs_Wafer_Layout.pdf Demis D. John - Stepper_Reticle_Layout_vs_Wafer_Layout.pdf]
Resists Used (see [https://wiki.nanotech.ucsb.edu/wiki/index.php/Lithography_Recipes#Photolithography_Recipes PhotoLith. Recipes] for full process info):

===Photoresists Available===
''See [https://wiki.nanotech.ucsb.edu/w/index.php?title=Lithography_Recipes#Photolithography_Recipes PhotoLith. Recipes] for full process info & links to PR datasheets.''


*UV210-0.3 - Positive: 300nm nominal thickness
*UV210-0.3 - Positive: 300nm nominal thickness
Line 31: Line 36:


AZ300MIF Developer for all processes
AZ300MIF Developer for all processes

Many of these DUV PR's are also able to be exposed with [[E-Beam Lithography System (JEOL JBX-6300FS)|EBL]].

===Part Size Limits===
With staff support, mounted pieces down to 14mm in size can be exposed using a 4” wafer as a carrier. Flatness will typically be worse in this situation, so small <<500nm features will usually have bad uniformity across the mounted part due to focus variations. Edge bead on irregular pieces (eg. quarter-wafers/squares) will significantly reduce yield/uniformity.

Multi-layer Alignment on mounted parts is particularly difficult, requiring either semi-permanent mounting to the carrier (eg. BCB, SU8 etc.) or significant difficulty/effort to re-align the part to the carrier wafer on each lithography (≤100µm re-mounting accuracy needed).

At this time the maximum wafer size is 4” (100mm) wafers with SEMI standard wafer flat (not Notch).

===Service Provider===

*[http://www.asml.com ASML] - ASML performs quarterly periodic maintenance and provides on-demand support.


==Process Information==
==Process Information==


*[https://wiki.nanotech.ucsb.edu/wiki/index.php/Lithography_Recipes#Photolithography_Recipes '''Process Recipes Page'''] '''> "Stepper 3"''' - ''Established recipes and corresponding linewidths, photoresists etc.''
*[https://wiki.nanotech.ucsb.edu/w/index.php?title=Lithography_Recipes#Photolithography_Recipes '''Process Recipes Page'''] '''> "Stepper 3"''' - ''Established recipes and corresponding linewidths, photoresists etc.''
*Sample size: 100 mm wafers with SEMI std. major flat
*Sample size: 100 mm wafers with SEMI std. major flat
**''Piece-parts process is possible but difficult - contact staff for info''
**''Piece-parts process is possible but difficult - contact supervisor for info''
*Alignment Accuracy: < 50 nm
*Alignment Accuracy: < 50 nm
*Minimum Feature Size: ≤150 nm isolated lines, ≤200 nm dense patterns
*Minimum Feature Size: ≤150 nm isolated lines, ≤200 nm dense patterns
**''To achieve ≤200nm features with high uniformity, we recommend wafers with total thickness variation (TTV) ≤5µm, and designing your CAD with a smaller Image Size for the high-res. feature''.
*Maximum Wafer Bow: approx. 100 µm. (4-inch diam.)
*Wafer Thickness: Minimum ≈ 200µm, Maximum ≈ 1.1 mm
**''Near this value, and the job may fail or lose the wafer inside the machine due to wafer vacuum error.''
*Maximum Dose: ~100mJ
**''Non-chemically amplified EBL resists are not permissible due to this limit.''

===Maximum Wafer Bow===
Measured over 90mm on the [[Film Stress (Tencor Flexus)|Tencor Flexus]]

*'''Do not run wafers with bow values higher than the following values''', contact supervisor for advice if needed.
*Silicon wafers (~550µm thick): 100 µm will likely fail.
*Sapphire (less pliable), ≥60µm bow will intermittently fail - DO NOT RUN
**This applies especially for GaN-on-Sapphire, which often have high wafer bow.
*''Near these values, and you may lose the wafer inside the machine due to wafer vacuum error - DO NOT RUN if unsure.''
*''Substrate material and substrate thickness affect this limit - please contact [[Demis D. John|supervisor]] for advice.''
*You can stress-compensate wafers to reduce the wafer bow, eg. via underside dep. of [[Sputtering Recipes#Si3N4 deposition .28IBD.29|IBD SiN]], or other compressive/tensile films for concave-down/up bow, respectively.


==Operating Procedures==
==Operating Procedures==
<code>'''All operating procedures and reticle-making guides have been access-restricted only to'''</code>


<code>'''<u>authorized users with a UCSB NetID</u>, by vendor request. Please contact [[Demis D. John|supervisor]] for access/training.'''</code>
*[[ASML Stepper 3 Standard Operating Procedure|Standard Operating Procedures]]
**''Exposing wafers, loading reticles, focus/exposure matrix''
*[//wiki.nanotech.ucsb.edu/wiki/images/f/f7/ASML_Job_Set-Up_Guide_v2.pdf Job Programming - Full]
*[//wiki.nanotech.ucsb.edu/wiki/images/c/cd/ASML_Job_Set-Up_Guide_simple_v1.pdf Job Programming- Simplified -Full Wafers]


===Troubleshooting and Recovery===


[https://drive.google.com/drive/folders/1U9-03qU2htQp_5x39LNq-mn5Q3vXXLDf?usp=drive_link '''<u>ASML Operating Procedures</u>'''] - shared google drive folder of PAS 5500/300 operating procedures.
*[[ASML Stepper 3 Error Recovery, Troubleshooting and Calibration|Error Recovery, Troubleshooting and Calibration]]
**''Common errors/System Warnings, Wafer Handler Reset, System Calibration Verification''


[https://docs.google.com/document/d/17jPek8P_SF1qRADS09ApoDgUiB_v0NFJsIVpkL-Kdag/edit#heading=h.fmorc9eu8hfz '''<u>Stepper #3 Training Videos</u>'''] - these provide bookmarked quick-reference to various tool procedures & programming.
*[[ASML 5500: Recovering from an Error|ASML 5500: Recovering from an Error/Wafer Retrieval]]
**''How to abort the job and recover your wafer.''


*''You must log into google-drive with your UCSB NetID to access these materials.''
===Software Options===
*''Please contact the [[Demis D. John|tool supervisor]] if you need access.''


===Training Procedure===
*[[ASML Stepper 3 - Shifted Measurement Scans (SMS)|Shifted Measurement Scans]] - better tilt/level measurement locations for edge-die. Simply enable the Checkbox in your job file.
To get access to this tool, please do the following:
*[[ASML Stepper 3 - Compound Image Design (CIDS)|Compound Image Design]] - flexible Image Distribution: grouping of Images with shifts, duplicate instances of Images in each Cell.
*[[ASML Stepper 3 - Job Creator|Job Creator]] - create binary ASML job files from ASCII text files. Python scripting capabilities using this option are currently implemented, see below.


#Email the [[Demis D. John|supervisor]] for access to the training materials. Please provide your <u>UCSB NetID</u>.
==Design & Fabrication Tools==
#Study the [https://docs.google.com/document/d/17jPek8P_SF1qRADS09ApoDgUiB_v0NFJsIVpkL-Kdag/edit#heading=h.fmorc9eu8hfz training videos].
##If you are a technician and will never program jobs, only Part 1 is necessary.
#"Shadow" someone in your group who uses the machine, <u>until you are completely comfortable</u> with wafer cleaning (critical), reticle load/unload and running a pre-made job. When you are ready, do step 4:
#Contact [[Demis D. John|the supervisor]] for an short hands-on check-off, after which you'll get signupmonkey access.


==Design Tools==
*[[ASML 5500 Mask Making Guidelines|ASML 5500 Mask Making Guidelines]] - All the info you need to design and order a reticle for this system.
**[[ASML 5500 Mask Making Guidelines#Templates|Templates and CAD help]] - on the above page, CAD files and spreadsheets to help you design/program.
*[https://github.com/demisjohn/ASML_JobCreator ASML Job Creator] - Python scripts for generating ASML Job Files.
**''This new scriptable job programming is in the user-testing phase - contact [[Demis D. John|the supervisor]] if interested.''
*[[ASML Stepper 3 - UCSB Test Reticles|UCSB Test Reticles]] - Alignment Markers, Resolution Testing etc.


===Mask Design and CAD files===
== Recipes ==

See the '''[[Stepper Recipes#Stepper 3 .28ASML DUV.29|Recipes > Stepper Recipes > Stepper #3]]''' page for starting processes for various photoresists, including Dose/Focus values.
*[https://wiki.nanofab.ucsb.edu/wiki/Stepper_Mask-Making_Guidelines_(Generic) '''Stepper Mask-Making Guidelines'''] - Generic info needed to design and order a reticle for any Stepper system. This is minimal unrestricted info that is viewable without additional paperwork.

*'''[https://docs.google.com/document/d/1b9YT11RPsl-UlLvN74hrQvG01OcYDL16r6I5lPOlBEo/edit?usp=sharing ASML-specific Mask Making Guidelines]''' - All the detailed info you need to design and order a reticle for this specific ASML system.
**''Access is restricted to trained users only - please contact [[Demis D. John|tool supervisor]] for access.''

*See the [[Calculators + Utilities#CAD%20Files%20.26%20Templates|Calculators + Utilities > '''CAD Files & Templates''']] page for other useful CAD files, such as overlay verniers, vented fonts etc.

===UCSB Photomasks Available===

*[[ASML Stepper 3 - UCSB Test Reticles|UCSB DUV Reticles]] - Photomasks available with various Alignment Markers (contact, EBL), Resolution Testing etc.

==Recipes==
See the '''[[Stepper Recipes#Stepper 3 .28ASML DUV.29|Recipes > Lithography > Stepper Recipes > Stepper #3]]''' page for starting processes for various photoresists, including Dose/Focus values.


Litho. recipes for all our photolith. tools can be found on the [[Lithography Recipes#Photolithography Recipes|Photolithography Recipes]] page.
Litho. recipes for all our photolith. tools can be found on the [[Lithography Recipes#Photolithography Recipes|Photolithography Recipes]] page.


==Service Provider==
==Process Control Data==


*''The Process Group regularly measures the lithography Critical Dimension ("CD") and Wafer-stage Particulate Contamination for this tool, using a sensitive lithography process that will reveal small changes in Dose repeatability and wafer flatness.''
*[http://www.asml.com ASML] - ASML performs quarterly periodic maintenance and provides on-demand support.
*[https://docs.google.com/spreadsheets/d/1xW1TFH_QjPMWl9T1jiKzwmYe4B2wg7KY-nqOKUoXttI/edit#gid=0 '''Data Table for CD Uniformity and Particulate Contamination''']
*[https://docs.google.com/spreadsheets/d/1xW1TFH_QjPMWl9T1jiKzwmYe4B2wg7KY-nqOKUoXttI/edit#gid=1804752281 '''Plots of CD Repeatability''']

{|
|[[File:ASML CD Cals - Example Table.jpg|alt=ASML CD Calibration data - Screenshot of Table|none|thumb|300x300px|''Example of Data Table with SEM's of 320nm features. [https://docs.google.com/spreadsheets/d/1xW1TFH_QjPMWl9T1jiKzwmYe4B2wg7KY-nqOKUoXttI/edit#gid=0 Click for full data table.]''|link=https://docs.google.com/spreadsheets/d/1xW1TFH_QjPMWl9T1jiKzwmYe4B2wg7KY-nqOKUoXttI/edit#gid=0]]
|[[File:ASML CD Cals - Example Plot.jpg|alt=ASML CD Calibration Data - Screenshot of SPC Plot|none|thumb|''Example SPC Chart - Measured Critical Dimension "CD" versus Date.'' ''[https://docs.google.com/spreadsheets/d/1xW1TFH_QjPMWl9T1jiKzwmYe4B2wg7KY-nqOKUoXttI/edit#gid=1804752281 Click for current charts.]''|link=https://docs.google.com/spreadsheets/d/1xW1TFH_QjPMWl9T1jiKzwmYe4B2wg7KY-nqOKUoXttI/edit#gid=1804752281]]
|}
<br />

Revision as of 19:33, 19 July 2024

Stepper 3 (ASML DUV)
ASML.jpg
Tool Type Lithography
Location Bay 7
Supervisor Demis D. John
Supervisor Phone (805) 893-5934
Supervisor E-Mail demis@ucsb.edu
Description Deep-UV Stepper Photolithography
Manufacturer ASML
Model PAS 5500/300
Lithography Recipes
Sign up for this tool



About

General Capabilities/Overview

The ASML 5500 stepper is a 248nm (KrF) DUV stepper for imaging dense features down to below 200nm and isolated line structures down to below 150nm (with effort). 300nm+ features are relatively "easy" to resolve. Layer-to-layer overlay accuracy is better than 30nm.

The system is configured for 4” wafers. The system is designed for high throughput, so shooting multiple 4" wafers is extremely fast, typically minutes per wafer, but any size other than 4-inch is difficult to work with (see below for more info). Additionally, exposure jobs are highly programmable, allowing for very flexible exposures of multiple aligned patterns from multiple masks/reticles in a single session, allowing for process optimization of large vs. small features in a single lithography.

The full field useable exposure area is limited to the intersection of a 31mm diameter circle and a rectangle of dimensions 22mm x 27mm. Users have stitched multiple photomasks together with success. See the Mask Making Guidelines page for more info on exposure field sizes and how to order your mask plates.

Tutorial: If you are not familiar with the differences between Contact Litho and Stepper Litho, please review this short tutorial: Demis D. John - Stepper_Reticle_Layout_vs_Wafer_Layout.pdf

Photoresists Available

See PhotoLith. Recipes for full process info & links to PR datasheets.

  • UV210-0.3 - Positive: 300nm nominal thickness
  • UV6-0.8 - Positive: 800nm nominal thickness
  • UV26-2.5 - Positive: 2.5um nominal thickness
  • UVN2300-0.5 - Negative: 500nm nominal thickness
  • DUV42P-6/DS-K101 - Bottom Anti-Reflective Coatings “BARC”
  • PMGI/LOL1000/LOL2000 - Underlayers

AZ300MIF Developer for all processes

Many of these DUV PR's are also able to be exposed with EBL.

Part Size Limits

With staff support, mounted pieces down to 14mm in size can be exposed using a 4” wafer as a carrier. Flatness will typically be worse in this situation, so small <<500nm features will usually have bad uniformity across the mounted part due to focus variations. Edge bead on irregular pieces (eg. quarter-wafers/squares) will significantly reduce yield/uniformity.

Multi-layer Alignment on mounted parts is particularly difficult, requiring either semi-permanent mounting to the carrier (eg. BCB, SU8 etc.) or significant difficulty/effort to re-align the part to the carrier wafer on each lithography (≤100µm re-mounting accuracy needed).

At this time the maximum wafer size is 4” (100mm) wafers with SEMI standard wafer flat (not Notch).

Service Provider

  • ASML - ASML performs quarterly periodic maintenance and provides on-demand support.

Process Information

  • Process Recipes Page > "Stepper 3" - Established recipes and corresponding linewidths, photoresists etc.
  • Sample size: 100 mm wafers with SEMI std. major flat
    • Piece-parts process is possible but difficult - contact supervisor for info
  • Alignment Accuracy: < 50 nm
  • Minimum Feature Size: ≤150 nm isolated lines, ≤200 nm dense patterns
    • To achieve ≤200nm features with high uniformity, we recommend wafers with total thickness variation (TTV) ≤5µm, and designing your CAD with a smaller Image Size for the high-res. feature.
  • Wafer Thickness: Minimum ≈ 200µm, Maximum ≈ 1.1 mm
  • Maximum Dose: ~100mJ
    • Non-chemically amplified EBL resists are not permissible due to this limit.

Maximum Wafer Bow

Measured over 90mm on the Tencor Flexus

  • Do not run wafers with bow values higher than the following values, contact supervisor for advice if needed.
  • Silicon wafers (~550µm thick): 100 µm will likely fail.
  • Sapphire (less pliable), ≥60µm bow will intermittently fail - DO NOT RUN
    • This applies especially for GaN-on-Sapphire, which often have high wafer bow.
  • Near these values, and you may lose the wafer inside the machine due to wafer vacuum error - DO NOT RUN if unsure.
  • Substrate material and substrate thickness affect this limit - please contact supervisor for advice.
  • You can stress-compensate wafers to reduce the wafer bow, eg. via underside dep. of IBD SiN, or other compressive/tensile films for concave-down/up bow, respectively.

Operating Procedures

All operating procedures and reticle-making guides have been access-restricted only to

authorized users with a UCSB NetID, by vendor request. Please contact supervisor for access/training.


ASML Operating Procedures - shared google drive folder of PAS 5500/300 operating procedures.

Stepper #3 Training Videos - these provide bookmarked quick-reference to various tool procedures & programming.

  • You must log into google-drive with your UCSB NetID to access these materials.
  • Please contact the tool supervisor if you need access.

Training Procedure

To get access to this tool, please do the following:

  1. Email the supervisor for access to the training materials. Please provide your UCSB NetID.
  2. Study the training videos.
    1. If you are a technician and will never program jobs, only Part 1 is necessary.
  3. "Shadow" someone in your group who uses the machine, until you are completely comfortable with wafer cleaning (critical), reticle load/unload and running a pre-made job. When you are ready, do step 4:
  4. Contact the supervisor for an short hands-on check-off, after which you'll get signupmonkey access.

Design Tools

Mask Design and CAD files

  • Stepper Mask-Making Guidelines - Generic info needed to design and order a reticle for any Stepper system. This is minimal unrestricted info that is viewable without additional paperwork.

UCSB Photomasks Available

  • UCSB DUV Reticles - Photomasks available with various Alignment Markers (contact, EBL), Resolution Testing etc.

Recipes

See the Recipes > Lithography > Stepper Recipes > Stepper #3 page for starting processes for various photoresists, including Dose/Focus values.

Litho. recipes for all our photolith. tools can be found on the Photolithography Recipes page.

Process Control Data

ASML CD Calibration data - Screenshot of Table
Example of Data Table with SEM's of 320nm features. Click for full data table.
ASML CD Calibration Data - Screenshot of SPC Plot
Example SPC Chart - Measured Critical Dimension "CD" versus Date. Click for current charts.