Atomic Layer Deposition Recipes: Difference between revisions
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**300°C Dep., Thermal Water reaction |
**300°C Dep., Thermal Water reaction |
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**This is considered the standard recipe for ALD |
**This is considered the standard recipe for ALD |
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**Al<sub>2</sub>O<sub>3</sub> deposition rate ~ |
**Al<sub>2</sub>O<sub>3</sub> deposition rate ~ 1.265 A/cyc |
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**Recipe variations: ''TBD'' |
**Recipe variations: ''TBD'' |
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| Line 92: | Line 92: | ||
**300°C Dep., Thermal Water reaction |
**300°C Dep., Thermal Water reaction |
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**This is considered the standard recipe for ALD |
**This is considered the standard recipe for ALD |
||
**Al<sub>2</sub>O<sub>3</sub> deposition rate ~ 1. |
**Al<sub>2</sub>O<sub>3</sub> deposition rate ~ 1.192 A/cyc |
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*Recipe name: '''''CH3-TMA+H2O-25<u>0C</u>''''' ("Thermal") |
*Recipe name: '''''CH3-TMA+H2O-25<u>0C</u>''''' ("Thermal") |
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**Al<sub>2</sub>O<sub>3</sub> deposition rate ~ 1.214 A/cyc |
**Al<sub>2</sub>O<sub>3</sub> deposition rate ~ 1.214 A/cyc |
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Latest revision as of 00:42, 15 November 2024
Back to Vacuum Deposition Recipes.
Atomic Layer Deposition (Oxford FlexAL)
Oxford FlexAL Process Notes
Temperature
"Thermal" ALD, considered the most standard process. Can be slower due to time for reaction to proceed.
To Be Added: effect of varying temeprature
Plasma
O* or N* mean Oxygen/Nitrogen plasma, respectively.
The plasma processes on this tool will run considerably faster than purely thermal proceses, because the reaction time is faster. Also, the O* plasma may reduce carbon contaminants from the organic precursors.
The drawback is that the plasma shutter, which opens/closes between plasma steps, gets coated in materials and can cause higher particle counts. We have attempted to remedy this by keeping the plasma shutter open during all recipes.
Ozone
O3 indicates a recipe using the Ozone generator for reaction. This Ozone-generator must be manually turned on before running the recipe - check with supervisor for details.
More info to be added
Varying Atomic Ratios
For some recipes such as TiN, there are two loops in the recipe. The outermost loop controls the total thickness of the film, the inner loop controls the ratio between the two elements. Contact the superviosr for more detailed info.
Oxford FlexAL Chamber #1: Metals
Maximum 30nm deposition thickness! (ask Tool Supervisor if needed.)
Al2O3 deposition (ALD CHAMBER 1)
- Recipe name: CH3-TMA+H2O-300C ("Thermal")
- 300°C Dep., Thermal Water reaction
- This is considered the standard recipe for ALD
- Al2O3 deposition rate ~ 1.265 A/cyc
- Recipe variations: TBD
Pt deposition (ALD CHAMBER 1)
- Recipe name: Ch1_TMCpPt+O3-300C
- Pt deposition rate ~ 0.5-0.6 A/cyc
- Conductivity data: (to be added)
- recipe utilizes the ozone generator which must be first set to the following conditions:
- O2 flow = 250sccm
- O3 concentration = 15 wt%
- 300°C deposition
- Recipe name: CH1-TMCpPt+250W/O*-300C
- Uses Oxygen plasma
- 300°C deposition
Ru deposition (ALD CHAMBER 1)
- Recipe name: Ch1_Ex03Ru[HPbub]+O2-300C
- Ru deposition rate ~ 0.6-0.7A/cyc.
- Conductivity data: (to be added)
- 300°C, O2 gas reaction
SiO2 deposition (ALD CHAMBER 1)
- Recipe name: CH3-TDMAS+250W/O*-300C ("Plasma")
- SiO2 deposition rate ~ 0.7-0.8A/cyc
- Recipe utilizes an O* plasma @ 250W, 5mTorr pressure, 300°C Temp.
- Temperature variations: 300*C (std.), 250°C, 200°C, 120°C
- Recipe name: CH1-BDEAS-O*/300W-300C
- SiO2 deposition rate ~ 1.008 A/cyc
- Similar to above TDMAS recipes, with different precursor gas.
- Temperature variations: To Be Added
- Etch rate (BHF:DI=1:100)~7.46nm/min
ZnO Deposition (ALD Chamber 1)
Conductive film.
- Recipe name: Ch1_DEZ+H2O-200C
- ZnO deposition rate ≈ 1.6 A/cycle
- resistivity ≈ TBA
- 200°C Deposition, Water reaction
ZnO:Al deposition (ALD CHAMBER 1)
Al-Doped ZnO for variable resisitivity.
- Recipe name: Ch1_DEZ/TMA+H2O-200C
- The recipe has TWO loops. The Outer loop determines final thickness. The Inner loop determines how much AlOx is doped into the film. Note that each full (outer-loop) cycle takes a long time due to this double-loop structure.
- Al dose fraction = 5% for lowest resistivity
- ZnO deposition rate ~ 1.7A/cyc
- resistivity ~ 4200uOhm.cm (390A film)
Oxford FlexAL Chamber #3: Dielectrics
Maximum 30nm deposition thickness! (ask Tool Supervisor if needed.)
Al2O3 deposition (ALD CHAMBER 3)
- Recipe name: CH3-TMA+H2O-300C ("Thermal")
- 300°C Dep., Thermal Water reaction
- This is considered the standard recipe for ALD
- Al2O3 deposition rate ~ 1.192 A/cyc
- Recipe name: CH3-TMA+H2O-250C ("Thermal")
- Al2O3 deposition rate ~ 1.214 A/cyc
- Temperature variations: 300°C (std.), 250°C, 200°C, 150°C, 120°C
- Recipe Name: CH3-TMA+250W/O*-300C ("Plasma")
- Oxygen Plasma reaction instead of H2O
- Lower carbon content
- Approx. 1.5–2x faster deposition rate than thermal.
- Temperature variations: 300°C (std.), 200°C, 120°C
- Recipe Name: CH3-TMA+O3/200mT-300C ("Ozone")
- Similar dep. rate
- Ozone (O3) reactant, experimental
- Requires Ozone generator to be turned on - ask supervisor
AlN deposition (ALD CHAMBER 3)
- Recipe name: CH3-TMA+100W/N*-300C
- AlN deposition rate ~ t.b.d.
- Recipe utilizes a N* plasma @ 100W, 20mTorr pressure.
- Temperature Variations: 300°C Dep. (std.), 200*C, 120°C
- Power variations: 300W, 400W (at 300°C)
- Nitrogen/Hydrogen variations: "30N*/30H*" at 200*C and 300°C
HfO2 deposition (ALD CHAMBER 3)
- Recipe name: CH3-TEMAH+H2O-300C ("Thermal")
- HfO2 deposition rate ~ 0.9-1.0A/cyc
- Note: deposition shows significant parasitic growth (via CVD channel) if H2O purge/pump times are not sufficient.
- Temperature variations: 300°C (std.), 250°C, 200°C, 150°C, 120°C
- Recipe name: CH3-TEMAH+250W/O*-300C ("Plasma")
- Uses Oxygen plasma reactant instead of H2O
- Recipe name: CH3-TEMAH+O3/100mT-300C ("Ozone")
- Uses Ozone (O3) for reactant instead of H2O
- Requires Ozone generator to be turned on - ask supervisor
SiO2 deposition (ALD CHAMBER 3)
- Recipe name: CH3-TDMAS+250W/O*-300C ("Plasma")
- SiO2 deposition rate ~ 0.7-0.8A/cyc
- Recipe utilizes an O* plasma @ 250W, 5mTorr pressure, 300°C Temp.
- Temperature variations: 300°C (std.), 250°C, 230°C, 220°C, 200°C, 175°C, 150°C, 120°C
- Recipe name: CH3-TDMAS+O3/200mT-300C ("Ozone")
- Uses Ozone (O3) for reactant instead of H2O
- Requires Ozone generator to be turned on - ask supervisor
ZrO2 deposition (ALD CHAMBER 3)
- Recipe name: CH3-TEMAZ+H2O-300C ("Thermal")
- ZrO2 deposition rate ~ 0.9-1.0A/cyc
- Not directly characterized since results are basically the same as the HfO2 process above.
- Temperature variations: 300°C (std.), 200°C
- Recipe name: CH3-TEMAZ+250W/O*-300C ("Plasma")
- Uses Oxygen plasma reactant instead of H2O
- Recipe name: CH3-TEMAZ+O3/100mT-300C ("Ozone")
- Uses Ozone (O3) for reactant instead of H2O
- Requires Ozone generator to be turned on - ask supervisor
TiO2 deposition (ALD CHAMBER 3)
- Recipe name: CH3-TDMAT+H2O-300C ("Thermal")
- TiO2 deposition rate ~ 0.6A/cyc
- Note: deposition shows parasitic growth (via CVD channel) if H2O purge/pump times are not sufficient.
- Temperature variations: 300°C (std.), 200°C, 120*C
- Recipe name: CH3-TDMAT+250W/O*-300C ("Plasma")
- Uses Oxygen plasma reactant instead of H2O
TiN deposition (ALD CHAMBER 3)
- Recipe name: CH3-TDMAT+400W/12N*/4H*-300C
- TiN deposition rate ~ 0.7A/cyc
- Conductivity data: (to be added)
- Uses Plasma of N2 & H2 gases.
- Temperatures: 300°C (std.), 200°C
- Recipe name: CH3-TDMAT+100W/N*-300C
- Uses Plasma of N2 only
- Temperatures: 300°C (std.), 200°C
- Recipe name: CH3-TDMAT+100W/NH3*-300C
- Uses Plasma of NH3 only
- Temperatures: 300°C (std.), 200°C