Thermal Processing Recipes: Difference between revisions
(→Thermal Oxidation of Silicon: added simulation/data for Wet1050 and Dry1050) |
(moved calculation times to "thermal ox" recipes, renamed "thermal ox recipes" to just "Ox recipes (tystar 8300)") |
||
(13 intermediate revisions by the same user not shown) | |||
Line 1: | Line 1: | ||
==Tystar 8300== |
==[[Tube Furnace (Tystar 8300)|Tystar 8300]]== |
||
=== |
=== Available Recipes (Tystar 8300) === |
||
The following are the available recipes on each furnace tube: |
|||
'''Tube 1: Various applications''' |
|||
*SOG425.001 - ''Spin-On Glass Cure'' |
|||
*ALGAAS.001 - ''Oxidation of AlGaAs'' |
|||
*ANNEAL.001 - ''Anneal with variable time and temp.'' |
|||
'''Tube 2: Cleaned Silicon Only''' |
|||
*WET1050.002 - ''WetOx at 1050°C'' |
|||
* DRY1050.002 - ''DryOx at 1050°C'' |
|||
*WETVAR.002 - ''WetOx, variable temp.'' |
|||
*DRYVAR.002 - ''DryOx, variable temp.'' |
|||
'''Tube 3: Processed silicon or other anneals.''' |
|||
*WET1050.003 - ''WetOx at 1050°C'' |
|||
*DRY1050.003 - ''DryOx at 1050°C'' |
|||
*WETVAR.003 - ''WetOx, variable temp.'' |
|||
*DRYVAR.003 - ''DryOx, variable temp.'' |
|||
*ANNEAL.003 - ''Anneal with variable time and temperature'' |
|||
===Process Limits (Tystar 8300)=== |
|||
*'''Max temperatures (Tystar 8300)''' |
|||
**Tube 1: 800°C max. |
|||
**Tube 2: 1100°C, for ≤24hr |
|||
**Tube 3: 1100°C, for ≤24hr |
|||
*'''DRY1050''' may not be run for more than 3hrs. O2 flow is 3SLPM, which is too high to run for more than 3hr without depleting the bottle. |
|||
**Contact supervisor for other options, such as '''''DRYVAR''''' @ 1100°C, or with lower O2 flow. |
|||
*'''WET1050''' may not be run for more than 24hrs without authorization, due to O2 bottle capacity. Contact supervisor if need to run longer. |
|||
*No recipe should be run with >1slpm gas flow without discussing with supervisor first, or gas bottles will be depleted very fast and likely run out during your process. |
|||
=== Wafer Cleaning === |
|||
For Tube #2, Silicon wafer cleaning, the following process is recommended: |
|||
# If brand new wafers, they should be already relatively clean. Otherwise Acetone/ISO clean might be needed to remove particles - optional |
|||
# Use [[Wet Benches#Wafer Toxic Corrosive Benches|Bay 4 toxic corrosive bench]] to submerge wafers for 20min in PureStrip @ 60°C. Replenish if needed, since PureStrip degrades after a few days at 60°C. |
|||
# QDR - rinse. |
|||
# Transport to Bay 5 HF bench (keep in water - optional) - use Chemical Transport Container. |
|||
# Submerge in HF for 10min. |
|||
# Rinse in DI 3x at HF bench. Pure HF goes down special drain, while rinse water can go down normal drain. |
|||
# Dry with Nitrogen gun OR SRD "Spin Rinse Dryer" at Bay 5. |
|||
# Ready to load into Tystar quartz boats, run recipe on Tystar. |
|||
===Oxidation Recipes (Tystar 8300)=== |
|||
==== Calculating Oxidation Times ==== |
|||
Online calculators for thermal oxidation can be used to estimate the oxidation time for a desired oxidation thickness. |
Online calculators for thermal oxidation can be used to estimate the oxidation time for a desired oxidation thickness. |
||
Please see the [[Calculators + Utilities]] page for links to these oxidation calculators. |
Please see the [[Calculators + Utilities]] page for links to these oxidation calculators. |
||
Using the [http://www.lelandstanfordjunior.com/thermaloxide.html Stanford Leland Jr. "Advanced Silicon Thermal Oxide Thickness Calculator"], we have determined the following simulation parameters to predict oxidation times. |
Using the [http://www.lelandstanfordjunior.com/thermaloxide.html Stanford Leland Jr. "Advanced Silicon Thermal Oxide Thickness Calculator"], we have determined the following simulation parameters (“partial pressure” in particular) to predict oxidation times. Please note, however, that doping level, impurity concentration and other factors can alter these calibrations, so you may need to calibrate the ''Partial Pressure'' yourself if you need higher accuracy. |
||
A simpler but less accurate oxidation calculator can be found at the [https://cleanroom.byu.edu/oxidetimecalc/ BYU Thermal Oxidation Calculator]. |
|||
==== 1050°C Dry Oxidation ==== |
|||
* Partial Pressure = 1.09 |
|||
====1050°C Dry Oxidation==== |
|||
* <100>, 1050°C, 10Å Native Oxide, no dopants |
|||
[[File:TyStar Thermal Oxidations - DryOx 1050°C 2018-04-09.png|frameless|300x300px]] |
|||
*Recipe Name: '''''DRY1050''''' |
|||
*Tube #2 for Cleaned Silicon Only |
|||
*Tube #3 for processed silicon or other anneals. |
|||
=====Simulation Parameters===== |
|||
*Partial Pressure = 1.12 (best fit to measured data below) |
|||
*<100>, 1050°C, 10Å Native Oxide, no dopants |
|||
[[File:TyStar_Thermal_Oxidations_-_DryOx_1050°C_2018-04-09.png|alt=plot of Measurements and Curve-Fitting for 1050°C Dry oxidations.|none|thumb|300x300px|'''Measurements and Curve-Fitting for 1050°C Dry oxidations. Note: three data points only. ''(Demis D. John, 2017-12)''''']] |
|||
====1050°C Wet Oxidation==== |
|||
*Recipe Name: '''''WET1050''''' |
|||
*Tube #2 for Cleaned Silicon Only |
|||
*Tube #3 for processed silicon or other anneals. |
|||
=====Simulation Parameters===== |
|||
*Partial Pressure = 1.09 (best fit to measured data below) |
|||
*<100>, 1050°C, 10Å Native Oxide, no dopants |
|||
==== 1050°C Wet Oxidation ==== |
|||
* Partial Pressure = 1.12 |
|||
* <100>, 1050°C, 10Å Native Oxide, no dopants |
|||
{| |
{| |
||
![[File:TyStar_Thermal_Oxidations_-_WetOx_1050°C_2018-04-09.png|alt=plot of Measurements and Curve-Fitting for 1050°C Wet oxidations.|none|thumb|300x300px|Measurements and Curve-Fitting for 1050°C Wet oxidations. '''''(Demis D. John, 2017-12)''''']] |
|||
![[File:TyStar Thermal Oxidations - WetOx 1050°C 2018-04-09.png|border|frameless|304x304px]] |
|||
![[File:TyStar_Thermal_Oxidations_-_WetOx_1050°C_2018-04-09_zoom.png|alt=plot of Zoom-in on Measurements and Curve-Fitting for 1050°C Wet oxidations.|none|thumb|300x300px|Zoom-in on Measurements and Curve-Fitting for 1050°C Wet oxidations.]] |
|||
![[File:TyStar Thermal Oxidations - WetOx 1050°C 2018-04-09 zoom.png|frameless|300x300px]] |
|||
|} |
|} |
||
====AlGaAs Oxidation==== |
|||
A recipe is available on Tube #1 for thermal oxidation of AlGaAs layers, at much lower temperatures than Tubes #2 & #3. There are special procedures for running this lower-temp. oxidation at shorter times, please contact [[Tony Bosch]] or the NanoFab process Group for more information. |
|||
==Wafer Substrate Bonding== |
==Wafer Substrate Bonding== |
||
Numerous research groups perform wafer bonding using either the [[Wafer Bonder (SUSS SB6-8E)|Suss Wafer Bonder]] or a custom graphite fixture and any one of [[Thermal Processing|numerous ovens]], such as the N2-purged [[Tube Furnace Wafer Bonding (Thermco)|Wafer Bonding Furnace]] (with glove box) or N2-purged [[High Temp Oven (Blue M)|Blue M oven]]. |
|||
===Direct Bonding=== |
|||
The [[Plasma Activation (EVG 810)|EVG Plasma Activation]] system and [[Goniometer]] allow for surface prep/inspection prior to bonding. |
|||
Numerous research groups perform direct wafer bonding (of various materials) using either the [[Wafer Bonder (SUSS SB6-8E)|Suss Wafer Bonder]], or a custom graphite fixture in conjunction with any one of [[Thermal Processing|numerous ovens]], such as the N2-purged [[Tube Furnace Wafer Bonding (Thermco)|Wafer Bonding Furnace]] (with glove box) or N2-purged [[High Temp Oven (Blue M)|Blue M oven]] or HeraTherm oven. |
|||
Il addition, the [[Flip-Chip Bonder (Finetech)|Fine-Tech Flip-Chip Bonder]] can perform aligned bonding of various-sized pieces. The Fine-Tech can do metal-to-metal thermo-compression bonding with ultrasonic assist. |
|||
The [[Plasma Activation (EVG 810)|EVG Plasma Activation]] system and [[Goniometer (Rame-Hart A-100)|Goniometer]] allow for surface prep/inspection prior to bonding. |
|||
===Bonding with Intermediate/adhesive layer=== |
|||
The [[Wafer Bonder (Logitech WBS7)|Logitech Bonder]] allows wafer-bonding with a CrystalBond wax or other intermediate layer, while applying pressure to the top surface to improve uniform wax distribution. Please see the '''''Recipes > Packaging > [[Packaging Recipes#Wafer Bonder .28Logitech WBS7.29|<u>Logitech Bonder</u>]]''''' page for recipes. |
|||
==[[Tube Furnace AlGaAs Oxidation (Lindberg)]]== |
|||
Oxidation of AlGaAs (high-Aluminum content >90%) is performed in this furnace, at temperatures between 200°C → 500°C. |
|||
Maximum time is about 3 hours before the bubbler water temperature becomes uncontrolled. |
|||
Recipes are available, please ask the NanoFab Process group staff. |
|||
==[[Rapid Thermal Processor (SSI Solaris 150)]]== |
|||
[[Category:Processing]] |
[[Category:Processing]] |
||
{{todo|Add starting recipes for RTP}} |
|||
== Rapid Thermal Annealer (AET RTA) == |
|||
{{todo|Add starting recipes for RTA}} |
Latest revision as of 22:01, 24 October 2024
Tystar 8300
Available Recipes (Tystar 8300)
The following are the available recipes on each furnace tube:
Tube 1: Various applications
- SOG425.001 - Spin-On Glass Cure
- ALGAAS.001 - Oxidation of AlGaAs
- ANNEAL.001 - Anneal with variable time and temp.
Tube 2: Cleaned Silicon Only
- WET1050.002 - WetOx at 1050°C
- DRY1050.002 - DryOx at 1050°C
- WETVAR.002 - WetOx, variable temp.
- DRYVAR.002 - DryOx, variable temp.
Tube 3: Processed silicon or other anneals.
- WET1050.003 - WetOx at 1050°C
- DRY1050.003 - DryOx at 1050°C
- WETVAR.003 - WetOx, variable temp.
- DRYVAR.003 - DryOx, variable temp.
- ANNEAL.003 - Anneal with variable time and temperature
Process Limits (Tystar 8300)
- Max temperatures (Tystar 8300)
- Tube 1: 800°C max.
- Tube 2: 1100°C, for ≤24hr
- Tube 3: 1100°C, for ≤24hr
- DRY1050 may not be run for more than 3hrs. O2 flow is 3SLPM, which is too high to run for more than 3hr without depleting the bottle.
- Contact supervisor for other options, such as DRYVAR @ 1100°C, or with lower O2 flow.
- WET1050 may not be run for more than 24hrs without authorization, due to O2 bottle capacity. Contact supervisor if need to run longer.
- No recipe should be run with >1slpm gas flow without discussing with supervisor first, or gas bottles will be depleted very fast and likely run out during your process.
Wafer Cleaning
For Tube #2, Silicon wafer cleaning, the following process is recommended:
- If brand new wafers, they should be already relatively clean. Otherwise Acetone/ISO clean might be needed to remove particles - optional
- Use Bay 4 toxic corrosive bench to submerge wafers for 20min in PureStrip @ 60°C. Replenish if needed, since PureStrip degrades after a few days at 60°C.
- QDR - rinse.
- Transport to Bay 5 HF bench (keep in water - optional) - use Chemical Transport Container.
- Submerge in HF for 10min.
- Rinse in DI 3x at HF bench. Pure HF goes down special drain, while rinse water can go down normal drain.
- Dry with Nitrogen gun OR SRD "Spin Rinse Dryer" at Bay 5.
- Ready to load into Tystar quartz boats, run recipe on Tystar.
Oxidation Recipes (Tystar 8300)
Calculating Oxidation Times
Online calculators for thermal oxidation can be used to estimate the oxidation time for a desired oxidation thickness. Please see the Calculators + Utilities page for links to these oxidation calculators.
Using the Stanford Leland Jr. "Advanced Silicon Thermal Oxide Thickness Calculator", we have determined the following simulation parameters (“partial pressure” in particular) to predict oxidation times. Please note, however, that doping level, impurity concentration and other factors can alter these calibrations, so you may need to calibrate the Partial Pressure yourself if you need higher accuracy.
A simpler but less accurate oxidation calculator can be found at the BYU Thermal Oxidation Calculator.
1050°C Dry Oxidation
- Recipe Name: DRY1050
- Tube #2 for Cleaned Silicon Only
- Tube #3 for processed silicon or other anneals.
Simulation Parameters
- Partial Pressure = 1.12 (best fit to measured data below)
- <100>, 1050°C, 10Å Native Oxide, no dopants
1050°C Wet Oxidation
- Recipe Name: WET1050
- Tube #2 for Cleaned Silicon Only
- Tube #3 for processed silicon or other anneals.
Simulation Parameters
- Partial Pressure = 1.09 (best fit to measured data below)
- <100>, 1050°C, 10Å Native Oxide, no dopants
AlGaAs Oxidation
A recipe is available on Tube #1 for thermal oxidation of AlGaAs layers, at much lower temperatures than Tubes #2 & #3. There are special procedures for running this lower-temp. oxidation at shorter times, please contact Tony Bosch or the NanoFab process Group for more information.
Wafer Substrate Bonding
Direct Bonding
Numerous research groups perform direct wafer bonding (of various materials) using either the Suss Wafer Bonder, or a custom graphite fixture in conjunction with any one of numerous ovens, such as the N2-purged Wafer Bonding Furnace (with glove box) or N2-purged Blue M oven or HeraTherm oven.
Il addition, the Fine-Tech Flip-Chip Bonder can perform aligned bonding of various-sized pieces. The Fine-Tech can do metal-to-metal thermo-compression bonding with ultrasonic assist.
The EVG Plasma Activation system and Goniometer allow for surface prep/inspection prior to bonding.
Bonding with Intermediate/adhesive layer
The Logitech Bonder allows wafer-bonding with a CrystalBond wax or other intermediate layer, while applying pressure to the top surface to improve uniform wax distribution. Please see the Recipes > Packaging > Logitech Bonder page for recipes.
Tube Furnace AlGaAs Oxidation (Lindberg)
Oxidation of AlGaAs (high-Aluminum content >90%) is performed in this furnace, at temperatures between 200°C → 500°C.
Maximum time is about 3 hours before the bubbler water temperature becomes uncontrolled.
Recipes are available, please ask the NanoFab Process group staff.
Rapid Thermal Processor (SSI Solaris 150)
To Do: Add starting recipes for RTP |
Rapid Thermal Annealer (AET RTA)
To Do: Add starting recipes for RTA |