|
|
Line 387: |
Line 387: |
| |- | | |- |
| |style="background:LightGrey; color:black" align="center" |Electron source | | |style="background:LightGrey; color:black" align="center" |Electron source |
| |style="background:Whitesmoke; color:black" colspan="4" align="center"| FEG (Field Emission Gun) source | | |style="background:Whitesmoke; color:black" colspan="3" align="center"| FEG (Field Emission Gun) source |
| |style="background:WhiteSmoke; color:black"| | | |style="background:WhiteSmoke; color:black"| |
| * Thermionic tungsten filament | | * Thermionic tungsten filament |
Line 430: |
Line 430: |
| |style="background:WhiteSmoke; color:black"| | | |style="background:WhiteSmoke; color:black"| |
| * Up to 8" wafer with 6" view | | * Up to 8" wafer with 6" view |
| |style="background:WhiteSmoke; color:black"|
| |
| * Up to 6" wafer with full view
| |
| |style="background:WhiteSmoke; color:black"| | | |style="background:WhiteSmoke; color:black"| |
| * Up to 6" wafer with full view | | * Up to 6" wafer with full view |
Feedback to this page:
click here
The DRIE Pegasus tools at DTU Nanolab
Unless otherwise stated, all content on this page was created by Jonas Michael-Lindhard, DTU Nanolab
In 2010 DTU Nanolab acquired DRIE-Pegasus 1 (at the time called Danchip and DRIE-Pegasus, respectively). As a state-of-the-art etch tool with excellent performance and great flexibility, it grew immensely popular and by 2015 it was apparent that we needed yet another tool to cope with the demand. Therefore, in 2016 Pegasus 2 was acquired from a closed-down lab in Morocco and installed next to Pegasus 1.
Looking to expand our dry etching capabilities in 2017 we got an irresistible offer on a twin Pegasus system with cassette to cassette vacuum robot from a commerciel fab. The twin Pegasus system (called Pegasus 3 and 4) is installed at the old cluster 2 location in cleanroom C1 and will run only 6" wafers. Pegasus 3 is the 6" silicon etch work horse and Pegasus 4 is converted (adding extra process gases) into a 6" dielectric etch tool that will supplement/replace the AOE.
This page was originally intended as a regular one-machine page (the Pegasus 1 page). However, as of 2018 with several tools, the page will serve as common page for all of our Pegasi with subpages for each tool.
|
|
|
The DRIE-Pegasus 1 load lock and cassette loader in the DTU Nanolab cleanroom A-1. Photo: DTU Nanolab internal
|
The DRIE-Pegasus 2 operator station and load lock in the DTU Nanolab cleanroom A-1. Photo: DTU Nanolab internal
|
The DRIE-Pegasus3 and DRIE-Pegasus4 operator station and cassette loading stations. Photo: DTU Nanolab internal
|
The Bosch process
The DRIE Pegasus tools are state-of-art silicon dry etchers that offer outstanding performance in terms of etch rate, uniformity etc. They use the so-called Bosch process to achieve excellent control of the etched features. Click HERE to access the top of the page. The contents are:
- Description of the Bosch process
- Processing options on the Pegasus
- Modification of the showerhead
- RF matching
- RF matching in general
- Why RF matching is extremely important in the Bosch process
- Picoscope process monitoring
As of 2017, completing the Dry Etch TPT course is mandatory for all new users. On the TPT web page you will find a version of the latest lecture slides - here you will find information as well.
Links to the individual pages for the Pegasi
Equipment performance and process related parameters
Equipment
|
DRIE-Pegasus 1
|
DRIE-Pegasus 2
|
DRIE-Pegasus 3
|
DRIE-Pegasus 4
|
Purpose
|
Primary
|
- Dry etching of 4" silicon
- Dry etching of barc
|
|
- Dry etching of 6" silicon
|
- Dry etching of 6" dielectrics
|
Alternative
|
|
- Backup dry etching of 6" silicon
|
|
|
Performance
|
Etch rates
|
- Standard processes A and B up to 15 µm/min depending on etch load and feature size
- Other processes: Any number from 200 nm/min to 10 µm/min
|
|
|
|
Uniformity
|
- For standard processes better than 3 % across a 150 mm wafer.
|
|
|
|
Process parameter range
|
RF powers
|
- Coil Power 5 kW
- Platen power 300/500 W (HF/LF)
|
- Coil Power 5 kW
- Platen power 300/500 W (HF/LF)
|
- Coil Power 5 kW
- Platen power 300/500 W (HF/LF)
|
- Coil Power 5 kW
- Platen power 300/500 W (HF/LF)
|
Gas flows
|
- SF6: 0 to 1200 sccm
- O2: 0 to 200 sccm
- C4F8: 0 to 400 sccm
- Ar: 0 to 283 sccm
|
- SF6: 0 to 1200 sccm
- O2: 0 to 200 sccm
- C4F8: 0 to 400 sccm
- Ar: 0 to 283 sccm
|
|
- SF6: ?(<20) sccm
- O2: 200 sccm
- C4F8: 400 sccm
- Ar: 283 sccm
- He: 500 sccm
- CF4: 100 sccm
- H2: 100 sccm
|
Pressure and temperature
|
- Pressure range 4 to 250 mTorr
- Temperature range -20 to 30 degrees C
|
- Pressure range 4 to 250 mTorr
- Temperature range -20 to 30 degrees C
|
- Pressure range 4 to 250 mTorr
- Temperature range -20 to 30 degrees C
|
- Pressure range 4 to 250 mTorr
- Temperature range -20 to 30 degrees C
|
Process options
|
- Bosch processes with etch and dep cycles each split into three
- Parameter ramping during process steps
- SOI option to reduce notching at buried oxide layers
- Picoscope monitoring
- Claritas endpoint detection system
|
- Bosch processes with etch and dep cycles each split into three
- Parameter ramping during process steps
- SOI option to reduce notching at buried oxide layers
- Picoscope monitoring
- Verity OES
|
- Bosch processes with etch and dep cycles each split into three
- Parameter ramping during process steps
- Picoscope monitoring
- SOI option to reduce notching at buried oxide layers
|
- Bosch processes with etch and dep cycles each split into three
- Parameter ramping during process steps
- Verity OES
|
Substrates
|
Sizes
|
- Smaller than 100mm: Bonded to carriers
- 100 mm wafers: Up to 25 wafers in a batch process
|
- Smaller than 150mm: Bonded to carriers
- 150 mm wafers
|
- Smaller than 150mm: Bonded to carriers
- 150 mm wafers
|
- Smaller than 150mm: Bonded to carriers
- 150 mm wafers
|
Loading
|
- Load lock
- MACS (Multiplex Atmospheric Cassette System)
|
|
- Vacuum cassette loader with two cassette stations and shared dealer chamber with Brooks robot
|
Allowed materials
|
- Silicon wafers
- Quartz wafers need a (semi)conducting layer for clamping
|
- Silicon wafers
- Quartz wafers need a (semi)conducting layer for clamping
|
- Silicon wafers
- Quartz wafers need a (semi)conducting layer for clamping
|
- Silicon wafers
- Quartz wafers need a (semi)conducting layer for clamping
|
Possible masking materials
|
- AZ photoresist
- zep resist
- DUV stepper resist (barc + krf)
- Oxides and nitrides
- Aluminium (only very gentle processes such as process C and nanoetches)
|
- AZ photoresist
- zep resist
- DUV stepper resist (barc + krf)
- Oxides and nitrides
- Aluminium (only very gentle processes)
|
- AZ and MiR photoresist
- zep resist
- DUV stepper resist (barc + krf)
- Oxides and nitrides
|
- AZ photoresist
- zep resist
- DUV stepper resist (barc + krf)
- Silicon,Oxides and nitrides
- Al, Cr masks
|
Process information
Process notation
Describing a process recipe on the Pegasus may sometimes be difficult because of the great flexibility of the instrument. A compact and precise notation is therefore required for the recipes. Click HERE to find a short description.
Comparison of SEM's in building 346/451
Equipment
|
SEM Supra 1
|
SEM Supra 2
|
SEM Supra 3
Under installation (August 2023)
|
SEM Tabletop 1
|
Model
|
Zeiss Supra 40 VP
|
Zeiss Supra 60 VP
|
Zeiss Supra 40 VP
|
SEM Tabletop 1
|
Purpose
|
Imaging and measurement of
|
- Conducting samples
- Semi-conducting samples
- Thin (~ 5 µm <) layers of non-conducting materials such as polymers
- Thick polymers, glass or quartz samples
|
- Conducting samples
- Semi-conducting samples
- Thin (~ 5 µm <) layers of non-conducting materials such as polymers
- Thick polymers, glass or quartz samples
|
- Conducting samples
- Semi-conducting samples
- Thin (~ 5 µm <) layers of non-conducting materials such as polymers
- Thick polymers, glass or quartz samples
|
- Conducting samples
- Semi-conducting samples
- Thin (~ 5 µm <) layers of non-conducting materials such as polymers
- Thick polymers, glass or quartz samples
|
Other purpose
|
|
- Surface material analysis using EDX
|
|
|
|
Instrument location
|
|
|
- Cleanroom of DTU Nanolab in building 346
|
- Cleanroom of DTU Nanolab in building 346
|
(in the North-East corner of the building's basement)
|
Performance
|
Resolution
|
The resolution of a SEM is strongly dependent on the type of sample and the skills of the operator. The highest resolution is probably only achieved on special samples
|
- 1-2 nm (limited by vibrations)
|
- 1-2 nm (limited by vibrations)
|
- 1-2 nm (limited by vibrations)
|
- ~25 nm (limited by instrument)
|
Instrument specifics
|
Detectors
|
- Secondary electron (Se2)
- Inlens secondary electron (Inlens)
- 4 Quadrant Backscatter electron (QBSD)
- Variable pressure secondary electron (VPSE)
|
- Secondary electron (Se2)
- Inlens secondary electron (Inlens)
- 4 Quadrant Backscatter electron (QBSD)
- Variable pressure secondary electron (VPSE)
|
- Secondary electron (Se2)
- Inlens secondary electron (Inlens)
- High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)
- Variable pressure secondary electron (VPSE)
|
- Secondary electron (SE)
- Backscatter electron (BSE)
|
Stage
|
- X, Y: 130 × 130 mm
- T: -4 to 70o
- R: 360o
- Z: 50 mm
|
- X, Y: 150 × 150 mm
- T: -10 to 70o
- R: 360o
- Z: 50 mm
|
- X, Y: 130 × 130 mm
- T: -4 to 70o
- R: 360o
- Z: 50 mm
|
- X, Y: 35 mm
- T: No tilt
- R: No rotation
- Z: 0 mm
|
Electron source
|
FEG (Field Emission Gun) source
|
- Thermionic tungsten filament
|
Operating pressures
|
- Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
- Variable at Low vacuum (0.1 mbar-2 mbar)
|
- Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
- Variable at Low vacuum (0.1 mbar-2 mbar)
|
- Fixed at High vacuum (2 × 10-4mbar - 10-6mbar)
- Variable at Low vacuum (0.1 mbar-2 mbar)
|
- Conductor vacuum mode: 5 Pa
- Standard vacuum mode: 30 Pa
- Charge-up reduction vacuum mode: 50 Pa
|
Options
|
- All software options available
- Electron magnetic noise cancellations system
|
- Antivibration platform
- Fjeld M-200 airlock taking up to 8" wafers
- Oxford Instruments X-MaxN 50 mm2 SDD EDX detector and AZtec software package
|
- High Definition four quadrant Angular Selective Backscattered electron detector (HDAsB)
|
|
Substrates
|
Sample sizes
|
- Up to 6" wafer with full view
|
- Up to 8" wafer with 6" view
|
- Up to 6" wafer with full view
|
- Up to 70 mm with full wiew
|
Allowed materials
|
- Any standard cleanroom material and samples from the Laser Micromachining tool and the Polymer Injection Molding tool
|
- Any standard cleanroom materials
|
- Any standard cleanroom materials
|
- Any standard cleanroom material and samples from the Laser Micromachining tool and the Polymer Injection Molding tool
- Some biological samples (ask for permission)
|
Hardware changes
A few hardware modifications have been made on the Pegasus 1 since it was installed in 2010. The changes are listed in the table below under hardware options.
General Pegasus information
Wafer bonding
To find information on how to bond wafers or chips to a carrier wafer, click HERE.
Characterisation of etched trenches
The trenches in deep silicon trenches can be characterized in many ways. Being able to compare processes requires that a set of common measurements and calculations must be established. Click HERE to find more information about the parameters used on the DRIE-Pegasus process development.