Specific Process Knowledge/Thin film deposition/Deposition of Titanium Oxide: Difference between revisions

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''All contents by '''Nanolab staff.'''''


==Deposition of Titanium Oxide==
==Deposition of Titanium Oxide==
Titanium oxide can be deposited either by a sputter technique or by use of ALD (atomic layer deposition). At the moment the only system where we have a target for Titanium oxide is [[Specific Process Knowledge/Etch/IBE⁄IBSD Ionfab 300|IBE/IBSD Ionfab300]]. The target is Ti. During the sputter deposition oxygen is added to the chamber resulting in Titanium oxide on the sample.
Titanium oxide can be deposited at Nanolab by sputtering, e-beam deposition, or ALD (atomic layer deposition). In sputtering and e-beam deposition of titanium oxide, the target is Ti and oxygen is added to the chamber during the process resulting in Titanium oxide on the sample. Therefore some process development may be necessary to achieve the correct stoichiometry. The oxygen flow in e-beam evaporation is lower than in sputtering, so it may not be possible to obtain fully oxidized TiO<sub>2</sub>, though we have not yet verified this.
 
*[[Specific Process Knowledge/Thin film deposition/ALD Picosun R200/TiO2 deposition using ALD|TiO2 deposition using ALD]]
*[[Specific Process Knowledge/Thin film deposition/TiO2 deposition using Sputter-System Metal-Oxide(PC1)|TiO2 deposition using Sputter-System Metal-Oxide(PC1)]]
*[[Specific Process Knowledge/Thin film deposition/TiO2 deposition in Sputter System (Lesker)|TiO2 deposition in Sputter System (Lesker)]]


*[[/IBSD of TiO2|TiO2 made on IBE/IBSD Ionfab300]]
We also used to have the option to sputter-deposit [[/IBSD of TiO2|TiO2 with the IBE/IBSD Ionfab300]].


==Comparison of the methods for deposition of Titanium Oxide==
==Comparison of the methods for deposition of Titanium Oxide==
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|-style="background:silver; color:black"
|-style="background:silver; color:black"
!
!
!Sputter technique using [[Specific Process Knowledge/Etch/IBE⁄IBSD Ionfab 300|IBE/IBSD Ionfab300]]
![[Specific Process Knowledge/Thin film deposition/10-pocket e-beam evaporator|E-beam evaporator (10-pockets)]]
![[Specific Process Knowledge/Thin film deposition/Lesker|Sputter System Lesker]]
![[Specific Process Knowledge/Thin film deposition/Cluster-based_multi-chamber_high_vacuum_sputtering_deposition_system|Sputter-system Metal-Oxide(PC1)]]
![[Specific Process Knowledge/Thin film deposition/III-V Dielectric evaporator|III-V Dielectric evaporator]]
![[Specific Process Knowledge/Thin film deposition/Lesker|Sputter-System(Lesker)]]
![[Specific Process Knowledge/Thin film deposition/ALD Picosun R200|ALD Picosun 200]]
![[Specific Process Knowledge/Thin film deposition/ALD Picosun R200|ALD Picosun 200]]
|-
|-
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!Generel description
!Generel description
|
|
*TiO2 created from a Ti sputter target. By adding oxygen during the deposition TiO2 is created.
*Evaporation of Ti or TiO<sub>2</sub> pellets in the presence of a O<sub>2</sub> flow.
|
|
*Reactive DC sputtering of Ti target in Ar/O2 (10% O2) plasma.
*Reactive DC sputtering of Ti target  
*RF sputtering of TiO2 target
*Reactive or non-reactive RF sputtering of TiO<sub>2</sub> target
*Reactive pulsed DC sputtering
*Reactive HIPIMS (high-power impulse magnetron sputtering)
|
|
* E-beam evaporation of TiO2
*Reactive DC sputtering of Ti target in Ar/O<sub>2</sub> (10 % O<sub>2</sub>) plasma
*RF sputtering of TiO<sub>2</sub> target
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|
*ALD (atomic layer deposition of TiO<sub>2</sub>
*ALD (atomic layer deposition) of TiO<sub>2</sub>
|-
|-


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!Stoichiometry
!Stoichiometry
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*Can probably be varied (sputter target: Ti, O2 added during deposition)
*Can probably be varied, expect somewhat O-poor composition
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*unknown
*Can probably be varied
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|
*unknown
*Can probably be varied
|
|
*Temperature dependent - Anatase or amorphous TiO<sub>2</sub>
*Temperature dependent - Anatase or amorphous TiO<sub>2</sub>
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!Film Thickness
!Film Thickness
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|
*~10nm - ~0.5µm(>2h)
*few nm - 100 nm
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|
*~10nm - ~0.5µm(>2h)
*~10 nm - ~0.5 µm
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*~10nm - ~200 nm
*~10 nm - ~0.5 µm (>2h)
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* 0nm - 100nm
* few nm - 100 nm
|-
|-


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!Deposition rate
!Deposition rate
|
|
*3.0-3.5nm/min (reactive DC sputtering)
*1-10 Å/s Ti deposition rate (oxidized layer growth should be faster; actual growth rate will need testing)
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|
*3 - 5 nm/min (RF sputtering)
*not yet known, probably faster than Sputter-System(Lesker)
*0.3 - 0.5nm/min
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* 1 - 2 Å/s
*3-5 nm/min (RF sputtering)
*0.3 - 0.5 nm/min
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* Not measured
* 0.06 nm/min - 0.40 nm/min (very recipe and temperature dependent)
|-
|-


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!Step coverage
!Step coverage
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*Not Known
*expect no step coverage unless the tilted sample holder is used, in which case step coverage should be very good and may be tuned with the tilt angle.
|
|
*Not Known
*Not Known
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*Not Known
*Not Known
|
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*Very good. Covers sample everywhere (but long purge time needed very very high aspect ratio structures)  
*Very good. Covers sample everywhere (but long purge time needed for very high aspect ratio structures)  
|-
|-


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!Process Temperature
!Process Temperature
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|
*Expected to be below 100<sup>o</sup>C
*RT to 250 °C
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*Done at RT. There is a possibility to run at higher temperatures
*RT to 600 °C
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*Sample temperature can be set to 20-250 <sup>o</sup>C
*RT
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*120<sup>o</sup>C - 150<sup>o</sup>C: Amorphous TiO<sub>2</sub>
*120 °C - 150 °C: Amorphous TiO<sub>2</sub>
*300<sup>o</sup>C - 350<sup>o</sup>C: Anatase TiO<sub>2</sub>   
*300 °C - 350 °C: Anatase TiO<sub>2</sub>   
|-
|-


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!More info on TiO2
!More info on TiO2
|
|
*[[/IBSD of TiO2|TiO2 made on IBE/IBSD Ionfab300]]
*Expect lower density than bulk material of same stoichiometry.
|
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*
*[[Specific Process Knowledge/Thin film deposition/TiO2 deposition using Sputter-System Metal-Oxide(PC1)|TiO2 deposition using Sputter-System Metal-Oxide(PC1)]]
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*
*
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*[[Specific Process Knowledge/Thin film deposition/ALD Picosun R200/TiO2 deposition using ALD|TiO2 deposition using ALD]]
ALD1:
*[[Specific Process Knowledge/Thin film deposition/ALD Picosun R200/TiO2 deposition using ALD|TiO2 deposition using ALD1]]
ALD2:
*[[Specific Process Knowledge/Thin film deposition/ALD2 (PEALD)/TiO2 deposition using ALD2|TiO2 deposition using ALD2]]  
|-
|-


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!Substrate size
!Substrate size
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*1 50mm wafer
*Up to 4x6" wafers
*1 100mm wafer
*Up to 3x8" wafers (ask for holder)
*1 150mm wafer
*smaller pieces
*1 200mm wafer
|
*Smaller pieces can be mounted with capton tape
*many small samples
*Up to 10x 100 mm or 150 mm wafers
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*several small samples
*several small samples
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*1x 150 mm wafers  
*1x 150 mm wafers  
|
|
*1x 2" wafer or
ALD1:
*several smaller samples
|
*1-5 100 mm wafers
*1-5 100 mm wafers
*1-5 150 mm wafers
*1-5 150 mm wafers
*1 200 mm wafer
*Several smaller samples
ALD2:
*1 100 mm wafer
*1 150 mm wafer
*1 200 mm wafer
*Several smaller samples  
*Several smaller samples  
|-
|-


|-
|-
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
!'''Allowed materials'''
!Allowed materials
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|
*Almost any materials
*Almost any material that does not outgas at your intended substrate temperature and is not toxic
*not Pb and very poisonous materials
*See the [http://labmanager.dtu.dk/function.php?module=XcMachineaction&view=edit&MachID=511 cross-contamination sheet]
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*Almost any materials
*Almost any material that does not outgas at your intended substrate temperature
*Pb and poisonous materials only after special agreement
*Pb and other toxic materials only after special agreement
|
*Almost any that do not outgas and are not very toxic
*Dedicated carrier for III-V materials
*See [http://labmanager.dtu.dk/function.php?module=XcMachineaction&view=edit&MachID=441 cross-contamination sheet]
|  
|  
|
*Silicon
*Silicon  
*Silicon oxide, silicon nitride
*Silicon oxide, silicon nitride
*Quartz/fused silica  
*Quartz/fused silica
*Al, Al<sub>2</sub>O<sub>3</sub>
*Metals - Use a dedicated carrier wafer
*Ti, TiO<sub>2</sub>
*III-V materials - Use dedicated carrier wafer
*Other metals (use dedicated carrier wafer)
*Polymers - Depending on the melting point/deposition temperature, use dedicated carrier wafer. Ask for permission
*III-V materials (use dedicated carrier wafer)
*Polymers (depending on the melting point/deposition temperature, use carrier wafer)
|-
|-
|}
|}

Latest revision as of 13:11, 4 July 2024

Feedback to this page: click here

All contents by Nanolab staff.

Deposition of Titanium Oxide

Titanium oxide can be deposited at Nanolab by sputtering, e-beam deposition, or ALD (atomic layer deposition). In sputtering and e-beam deposition of titanium oxide, the target is Ti and oxygen is added to the chamber during the process resulting in Titanium oxide on the sample. Therefore some process development may be necessary to achieve the correct stoichiometry. The oxygen flow in e-beam evaporation is lower than in sputtering, so it may not be possible to obtain fully oxidized TiO2, though we have not yet verified this.

We also used to have the option to sputter-deposit TiO2 with the IBE/IBSD Ionfab300.

Comparison of the methods for deposition of Titanium Oxide

E-beam evaporator (10-pockets) Sputter-system Metal-Oxide(PC1) Sputter-System(Lesker) ALD Picosun 200
Generel description
  • Evaporation of Ti or TiO2 pellets in the presence of a O2 flow.
  • Reactive DC sputtering of Ti target
  • Reactive or non-reactive RF sputtering of TiO2 target
  • Reactive pulsed DC sputtering
  • Reactive HIPIMS (high-power impulse magnetron sputtering)
  • Reactive DC sputtering of Ti target in Ar/O2 (10 % O2) plasma
  • RF sputtering of TiO2 target
  • ALD (atomic layer deposition) of TiO2
Stoichiometry
  • Can probably be varied, expect somewhat O-poor composition
  • Can probably be varied
  • Can probably be varied
  • Temperature dependent - Anatase or amorphous TiO2
Film Thickness
  • few nm - 100 nm
  • ~10 nm - ~0.5 µm
  • ~10 nm - ~0.5 µm (>2h)
  • few nm - 100 nm
Deposition rate
  • 1-10 Å/s Ti deposition rate (oxidized layer growth should be faster; actual growth rate will need testing)
  • not yet known, probably faster than Sputter-System(Lesker)
  • 3-5 nm/min (RF sputtering)
  • 0.3 - 0.5 nm/min
  • 0.06 nm/min - 0.40 nm/min (very recipe and temperature dependent)
Step coverage
  • expect no step coverage unless the tilted sample holder is used, in which case step coverage should be very good and may be tuned with the tilt angle.
  • Not Known
  • Not Known
  • Very good. Covers sample everywhere (but long purge time needed for very high aspect ratio structures)
Process Temperature
  • RT to 250 °C
  • RT to 600 °C
  • RT
  • 120 °C - 150 °C: Amorphous TiO2
  • 300 °C - 350 °C: Anatase TiO2
More info on TiO2
  • Expect lower density than bulk material of same stoichiometry.

ALD1:

ALD2:

Substrate size
  • Up to 4x6" wafers
  • Up to 3x8" wafers (ask for holder)
  • smaller pieces
  • many small samples
  • Up to 10x 100 mm or 150 mm wafers
  • several small samples
  • several 50 mm wafers (Ø150mm carrier)
  • 1x 100 mm wafers
  • 1x 150 mm wafers

ALD1:

  • 1-5 100 mm wafers
  • 1-5 150 mm wafers
  • 1 200 mm wafer
  • Several smaller samples

ALD2:

  • 1 100 mm wafer
  • 1 150 mm wafer
  • 1 200 mm wafer
  • Several smaller samples
Allowed materials
  • Almost any material that does not outgas at your intended substrate temperature and is not toxic
  • See the cross-contamination sheet
  • Almost any material that does not outgas at your intended substrate temperature
  • Pb and other toxic materials only after special agreement
  • Silicon
  • Silicon oxide, silicon nitride
  • Quartz/fused silica
  • Metals - Use a dedicated carrier wafer
  • III-V materials - Use dedicated carrier wafer
  • Polymers - Depending on the melting point/deposition temperature, use dedicated carrier wafer. Ask for permission
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