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

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Deposition of Silicon Oxide can be done with either LPCVD, PECVD or by sputter technique. You can also make a silicon oxide layer by growing a [[Specific Process Knowledge/Thermal Process/Oxidation|thermal oxide]] in a hot furnace but that requires a silicon surface as a starting point.
''All contents by DTU Nanolab staff.''
 
Silicon Oxide can be '''deposited'''  here at DTU Nanolab by LPCVD, PECVD, sputtering, or e-beam evaporation. In our cleanroom it is also possible to '''grow''' silicon oxide using a silicon surface as a starting point. This can be done with wet chemistry in a beaker (see below), or as a [[Specific Process Knowledge/Thermal Process/Oxidation|thermal oxide]] in a hot furnace.


==Deposition of Silicon Oxide using LPCVD==
==Deposition of Silicon Oxide using LPCVD==
The LPCVD oxide you can deposit at DANCHIP is called TEOS oxide. It can be made in the [[Specific Process Knowledge/Thin film deposition/B3 Furnace LPCVD TEOS|LPCVD TEOS furnace]]. It is a batch process meaning you can run a batch of 13 wafers at a time. The deposition takes place at temperatures of 725 degrees Celsius. The TEOS oxide has good step coverage and hole filing/covering properties and the film thickness is very uniform over the wafer. We have two standard TEOS processes: One for depositing standard layers ~(0-1.5 µm) and one for deposition thick layers ~(1.5µm-4µm). The TEOS oxide has a dielectric constant very close to the one for thermal oxide (3.65 for TEOS).
The LPCVD oxide you can deposit at DTU Nanolab is called TEOS oxide. It can be made in the [[Specific Process Knowledge/Thin film deposition/B3 Furnace LPCVD TEOS|LPCVD TEOS furnace]]. It is a batch process meaning you can run a batch of 13 wafers at a time. The deposition takes place at temperatures of 725 degrees Celsius. The TEOS oxide has good step coverage and hole filing/covering properties and the film thickness is very uniform over the wafer. We have two standard TEOS processes: One for depositing standard layers ~(0-1.5 µm) and one for deposition thick layers ~(1.5µm-4µm). The TEOS oxide has a dielectric constant very close to the one for thermal oxide (3.65 for TEOS).
*[[/Deposition of Silicon Oxide using LPCVD TEOS|Deposition of Silicon Oxide using LPCVD TEOS]]
*[[/Deposition of Silicon Oxide using LPCVD TEOS|Deposition of Silicon Oxide using LPCVD TEOS]]


==Deposition of Silicon Oxide using PECVD==
==Deposition of Silicon Oxide using PECVD==
PECVD oxide can be deposited in one of the [[Specific Process Knowledge/Thin film deposition/PECVD|PECVD]] systems. You can run 1-3 wafers at a time depending on which one of the PECVD's you use. The deposition takes place at 300 degrees Celcius. This can be of importance for some applications but it gives a less dense film and the oxide is expected to have some hydrogen incorporated. The step coverage and thickness uniformity of the film is not as good as for the LPCVD TEOS oxide. PECVD oxide has excellent floating properties when doped with boron and/or phosphorus. Then it can be used ex. as top cladding for waveguides or encapsulation of various structures/components. In one of our PECVD systems (PECVD3) we allow small amounts of metal on the wafers entering the system, this is not allowed in the LPCVD and in the other PECVD (PECVD1). It is also a possibility to dope the silicon oxide with Germanium for altering the refractive index of the oxide.
PECVD oxide can be deposited in one of the [[Specific Process Knowledge/Thin film deposition/PECVD|PECVD]] systems. You can run 1-3 wafers at a time depending on which one of the PECVD's you use. The deposition takes place at 300 °C. This can be of importance for some applications but it gives a less dense film and the oxide is expected to have some hydrogen incorporated. The step coverage and thickness uniformity of the film is not as good as for the LPCVD TEOS oxide. PECVD oxide has excellent floating properties when doped with boron and/or phosphorus. Then it can be used, e.g., as top cladding for waveguides or encapsulation of various structures/components. In one of our PECVD systems (PECVD3) we allow small amounts of metal on the wafers entering the system, which is not allowed in the LPCVD and in PECVD4.  
*[[/Deposition of Silicon Oxide using PECVD|Deposition of Silicon Oxide using PECVD]]
*[[/Deposition of Silicon Oxide using PECVD|Deposition of Silicon Oxide using PECVD]]


==Deposition of Silicon Oxide using sputter deposition technique==
==Deposition of Silicon Oxide using sputter deposition==
At DANCHIP you can also deposit silicon oxide using [[Specific Process Knowledge/Thin film deposition/Lesker|Lesker]], [[Specific Process Knowledge/Thin film deposition/Multisource PVD|PVD co-sputter/evaporation]] or [[Specific Process Knowledge/Etch/IBE⁄IBSD Ionfab 300|IBE Ionfab300]]
At DTU Nanolab we sputter silicon oxide in the Sputter-System [[Specific Process Knowledge/Thin film deposition/Lesker|(Lesker)]] or the [[Specific_Process_Knowledge/Thin_film_deposition/Cluster-based_multi-chamber_high_vacuum_sputtering_deposition_system|Sputter-System Metal Oxide(PC1)]]. An advantage of sputtering is that you can deposit on many kinds of material.
sputter systems. One of the advantages here is that you can deposit on any material you like.
*[[Specific Process Knowledge/Thin film deposition/Deposition of Silicon oxide in PVD co-sputter/evaporation|Deposition of Silicon Oxide using PVD co-sputter/evaporation tool]]


*[[Specific Process Knowledge/Thin film deposition/Deposition of Silicon Oxide/Reactively sputtered SiO2 in Sputter-System Metal Oxide (PC1)|Reactively Sputtered Silicon Oxide in Sputter-System Metal Oxide (PC1)]]
*[[/Deposition of Silicon Oxide using Lesker sputter tool|Deposition of Silicon Oxide using Lesker sputter tool]]
*[[/Deposition of Silicon Oxide using Lesker sputter tool|Deposition of Silicon Oxide using Lesker sputter tool]]
*[[Specific Process Knowledge/Thin film deposition/Deposition of Silicon Oxide/IBSD of SiO2|Deposition of Silicon Oxide using IBE/IBSD Ionfab300]]
 
Formerly we also had the option to sputter silicon oxide using the [[Specific Process Knowledge/Etch/IBE⁄IBSD Ionfab 300|IBE Ionfab300]]. You can read more about that [[Specific Process Knowledge/Thin film deposition/Deposition of Silicon Oxide/IBSD of SiO2|here]].
 
==Deposition of Silicon Oxide using e-beam evaporation==
It is possible to e-beam evaporate silicon dioxide at Nanolab using the [[Specific Process Knowledge/Thin film deposition/10-pocket e-beam evaporator|E-beam evaporator (10-pockets)]]. You can use silicon dioxide pellets as a starting point or silicon with an oxygen flow - in the latter case we expect the resultant films to be oxygen poor. As with sputtering you can deposit on almost any material. In e-beam evaporation the deposition is line-of-sight and will be suitable for lift-off. However for 8" wafers the system is not optimized for lift-off on the full diameter of the wafer.
 
*[[/Deposition of SiO2 in E-Beam Evaporator Temescal-2|Deposition of SiO2 using E-Beam Evaporator (10-pockets)]]
 
==Wet SiO2 growth ==
[https://labmanager.dtu.dk/view_binary.php?class=ChemicalProcess&id=118&name=Updated_APV_Wet_SiO2-growth_using_HNO3+%281%29.docx '''Link to risk assessment and procedure in Labmanager (password needed)''']
 
Wet SiO2 growth using hot HNO3.
Done in fume hood 1 or 2 in D-3. Growth rate is 1,5 - 2 nm on 10 min
 
'''Training and risk assessment always needed'''
 
==Deposition of Silicon Oxide using ALD==
Formerly it was possible to deposit thin films of silicon oxide up to 50 nm in the [[Specific Process Knowledge/Thin film deposition/ALD2 (PEALD)|ALD2]]. This is unfortunately no longer possible. You can read about the results of depositions in the past here: [[Specific Process Knowledge/Thin film deposition/ALD2 (PEALD)/SiO2 deposition using ALD2|Deposition of Silicon Oxide using ALD2]].
 


==Comparison of the methods for deposition of Silicon Oxide==
==Comparison of the methods for deposition of Silicon Oxide==
Line 28: Line 48:
![[Specific Process Knowledge/Thin film deposition/Furnace LPCVD TEOS|LPCVD(TEOS)]]
![[Specific Process Knowledge/Thin film deposition/Furnace LPCVD TEOS|LPCVD(TEOS)]]
![[Specific Process Knowledge/Thin film deposition/PECVD|PECVD]]
![[Specific Process Knowledge/Thin film deposition/PECVD|PECVD]]
![[Specific Process Knowledge/Thin film deposition/Deposition of Silicon oxide in PVD co-sputter/evaporation|PVD co-sputter/evaporation tool]]
![[Specific Process Knowledge/Etch/IBE⁄IBSD Ionfab 300|IBE/IBSD Ionfab300]]
![[Specific Process Knowledge/Thin film deposition/Lesker|Sputter System Lesker]]
![[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)]]
! E-beam evaporation ([[Specific Process Knowledge/Thin film deposition/10-pocket e-beam evaporator|E-beam evaporator (10-pockets)]])
!Wet SiO2 growth in hot HNO3
|-
|-


|-
|-
|-style="background:WhiteSmoke; color:black"
|-style="background:WhiteSmoke; color:black"
!Generel description
!General description
|Generel description - method 1
|Low Presure Chemical Vapor Deposition TEOS gives a good quality SiO2 and is a batch process.
|Plasma Enhanced Chemical Vapor Deposition has the advantach that a silicon oxide and be deposited with a quit high deposition rate at a rather low temperature.
|Plasma Enhanced Chemical Vapor Deposition has the advantage that a silicon oxide and be deposited with a quite high deposition rate at a rather low temperature
|.
|Sputter deposition: can be done on top of a large range of materials
|.
|Sputter deposition: can be done on top of a large range of materials.
|.
| E-beam evaporation: line-of-sight deposition on top of a large range of materials.
|Wet SiO2 growth using hot HNO3. Done in fume hood 1 or 2 in D-3. '''Training and risk assessment always needed'''
|-
|-


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|
|
*SiO<sub>2</sub>
*SiO<sub>2</sub>
Can be doped with boron
|
|
*Si<sub>x</sub>O<sub>y</sub>H<sub>z</sub>
*Si<sub>x</sub>O<sub>y</sub>H<sub>z</sub>
Can be doped with boron, phosphorus or germanium
Can be doped with boron, phosphorus or germanium
|
*Not measured (a sputter target with stoichiometry SiO<sub>2</sub> is used)
|
|
*Not measured (a sputter target with stoichiometry SiO<sub>2</sub> is used
*
|
*Slightly O-poor as deposited non-reactively (O:Si=64:36), may be tunable if reactively sputtered with O<sub>2</sub> (see acceptance test results [[Specific_Process_Knowledge/Thin_film_deposition/Cluster-based_multi-chamber_high_vacuum_sputtering_deposition_system#Process_information|here]])
|
|
*
* to be verified; may depend on O<sub>2</sub> flow
|
*SiO2
|-
|-


Line 64: Line 87:
!Film thickness range
!Film thickness range
|
|
*~300nm - 4µm
*~300 nm - 4 µm
|
|
*~40nm - 30µm
*~40 nm - 30 µm
|
|
*Thin layers (up to 300-400 nm)
* Thin layers (up to 200-300 nm)
|
|
*~10nm - ~1µm(>2h)
* Thin layers (up to 200-300 nm)
|
|
*
* Thin layers (up to 100 nm)*
|
*1,5-2 nm after 10 min.
|-
|-


Line 78: Line 103:
!Process Temperature
!Process Temperature
|
|
*725 <sup>o</sup>C
*725 °C
|
*300 °C
|
|
*300 <sup>o</sup>C
*Room temp
|
|
*Can be between room temp. and 400 <sup>o</sup>C
*Room temp to 600 °C
|
|
*Expected to be below 100<sup>o</sup>C
*Room temp to 250 °C
|
|
*
*80°C
|-
|-


Line 93: Line 120:
!Step Coverage
!Step Coverage
|
|
*Excelent. Very high surface mobility.
*Excellent. Very high surface mobility.
*Deposition on both sides of the substrate.
*Deposition on both sides of the substrate.
|
|
*Less good
*Less good
*When doped with phosphorus and/or Boron the oxide can float at about 1000 <sup>o</sup>C in a wet oxidation.
*When doped with phosphorus and/or Boron the oxide can float at about 1000 °C in a wet oxidation.
*Deposition on one side of the substrate
|
*Not Known
*Deposition on one side of the substrate
*Deposition on one side of the substrate
|
|
*Not known
*Medium. Perhaps use of HIPIMS can improve step coverage (requires significant process development)
*Deposition on one side of the substrate
*Deposition on one side of the substrate
|
|
*Not Known
*No step coverage expected unless using tilt holder, in which case step coverage can be very good and can be tuned with the tilt angle.
*Deposition on one side of the substrate
*Deposition on one side of the substrate
|
|
*
*Not known
|-
|-


Line 122: Line 152:
*
*
|
|
*
*Not yet known, but expect lower density than bulk material.
|
|-
|-


Line 137: Line 168:
*1 150 mm wafer
*1 150 mm wafer
|
|
*Several small samples
*Pieces or
*1-12 100 mm wafers
*1x4" wafer or
*1-4 150 mm wafers
*1x6" wafer
*Process time for 3 wafers is the same as for 1 wafer
|
*Many smaller pieces or
*up to 10x 4" or 6" wafer
|
|
*Several small samples mounted with capton tape
*Up to 4 x 6" wafer or
*1 50 mm wafer
*3x 8" wafers (ask for special holder)
*1 100 mm wafer
*Many smaller pieces
*1 150 mm wafer
*1 200 mm wafer
|
|
*
*Beaker depended
|-
|-


Line 165: Line 196:
*Small amount of metal (in PECVD3)
*Small amount of metal (in PECVD3)
|
|
*Silicon
* Silicon
**with layers of silicon oxide or silicon (oxy)nitride
* Silicon oxide
*Quartz
* Silicon nitride
*Metals  
* Silicon (oxy)nitride  
* Photoresist
* PMMA
* Mylar
* SU-8
* Metals  
* Carbon
|
*Almost any that will not degas and is not very poisonous
*See the [http://labmanager.dtu.dk/function.php?module=XcMachineaction&view=edit&MachID=441 cross-contamination sheet]
|
|
*Almost any material
*Almost any that will not degas and is not very poisonous  
*not Pb and very poisonous materials
*See the [http://labmanager.dtu.dk/function.php?module=XcMachineaction&view=edit&MachID=511 cross-contamination sheet]
|
|
*
*Acids react with a number of metals to produce hydrogen which, in contact with the air, may cause explosions
|-
|-
|}
|}
'''*''' If you wish to deposit more than 100 nm, please talk to responsible staff or write to thinfilm@nanolab.dtu.dk

Latest revision as of 15:45, 7 February 2024

Feedback to this page: click here

All contents by DTU Nanolab staff.

Silicon Oxide can be deposited here at DTU Nanolab by LPCVD, PECVD, sputtering, or e-beam evaporation. In our cleanroom it is also possible to grow silicon oxide using a silicon surface as a starting point. This can be done with wet chemistry in a beaker (see below), or as a thermal oxide in a hot furnace.

Deposition of Silicon Oxide using LPCVD

The LPCVD oxide you can deposit at DTU Nanolab is called TEOS oxide. It can be made in the LPCVD TEOS furnace. It is a batch process meaning you can run a batch of 13 wafers at a time. The deposition takes place at temperatures of 725 degrees Celsius. The TEOS oxide has good step coverage and hole filing/covering properties and the film thickness is very uniform over the wafer. We have two standard TEOS processes: One for depositing standard layers ~(0-1.5 µm) and one for deposition thick layers ~(1.5µm-4µm). The TEOS oxide has a dielectric constant very close to the one for thermal oxide (3.65 for TEOS).

Deposition of Silicon Oxide using PECVD

PECVD oxide can be deposited in one of the PECVD systems. You can run 1-3 wafers at a time depending on which one of the PECVD's you use. The deposition takes place at 300 °C. This can be of importance for some applications but it gives a less dense film and the oxide is expected to have some hydrogen incorporated. The step coverage and thickness uniformity of the film is not as good as for the LPCVD TEOS oxide. PECVD oxide has excellent floating properties when doped with boron and/or phosphorus. Then it can be used, e.g., as top cladding for waveguides or encapsulation of various structures/components. In one of our PECVD systems (PECVD3) we allow small amounts of metal on the wafers entering the system, which is not allowed in the LPCVD and in PECVD4.

Deposition of Silicon Oxide using sputter deposition

At DTU Nanolab we sputter silicon oxide in the Sputter-System (Lesker) or the Sputter-System Metal Oxide(PC1). An advantage of sputtering is that you can deposit on many kinds of material.

Formerly we also had the option to sputter silicon oxide using the IBE Ionfab300. You can read more about that here.

Deposition of Silicon Oxide using e-beam evaporation

It is possible to e-beam evaporate silicon dioxide at Nanolab using the E-beam evaporator (10-pockets). You can use silicon dioxide pellets as a starting point or silicon with an oxygen flow - in the latter case we expect the resultant films to be oxygen poor. As with sputtering you can deposit on almost any material. In e-beam evaporation the deposition is line-of-sight and will be suitable for lift-off. However for 8" wafers the system is not optimized for lift-off on the full diameter of the wafer.

Wet SiO2 growth

Link to risk assessment and procedure in Labmanager (password needed)

Wet SiO2 growth using hot HNO3.

Done in fume hood 1 or 2 in D-3. Growth rate is 1,5 - 2 nm on 10 min

Training and risk assessment always needed

Deposition of Silicon Oxide using ALD

Formerly it was possible to deposit thin films of silicon oxide up to 50 nm in the ALD2. This is unfortunately no longer possible. You can read about the results of depositions in the past here: Deposition of Silicon Oxide using ALD2.


Comparison of the methods for deposition of Silicon Oxide

LPCVD(TEOS) PECVD Sputter System Lesker Sputter-system Metal-Oxide(PC1) E-beam evaporation (E-beam evaporator (10-pockets)) Wet SiO2 growth in hot HNO3
General description Low Presure Chemical Vapor Deposition TEOS gives a good quality SiO2 and is a batch process. Plasma Enhanced Chemical Vapor Deposition has the advantage that a silicon oxide and be deposited with a quite high deposition rate at a rather low temperature Sputter deposition: can be done on top of a large range of materials Sputter deposition: can be done on top of a large range of materials. E-beam evaporation: line-of-sight deposition on top of a large range of materials. Wet SiO2 growth using hot HNO3. Done in fume hood 1 or 2 in D-3. Training and risk assessment always needed
Stochiometry
  • SiO2
  • SixOyHz

Can be doped with boron, phosphorus or germanium

  • Slightly O-poor as deposited non-reactively (O:Si=64:36), may be tunable if reactively sputtered with O2 (see acceptance test results here)
  • to be verified; may depend on O2 flow
  • SiO2
Film thickness range
  • ~300 nm - 4 µm
  • ~40 nm - 30 µm
  • Thin layers (up to 200-300 nm)
  • Thin layers (up to 200-300 nm)
  • Thin layers (up to 100 nm)*
  • 1,5-2 nm after 10 min.
Process Temperature
  • 725 °C
  • 300 °C
  • Room temp
  • Room temp to 600 °C
  • Room temp to 250 °C
  • 80°C
Step Coverage
  • Excellent. Very high surface mobility.
  • Deposition on both sides of the substrate.
  • Less good
  • When doped with phosphorus and/or Boron the oxide can float at about 1000 °C in a wet oxidation.
  • Deposition on one side of the substrate
  • Not Known
  • Deposition on one side of the substrate
  • Medium. Perhaps use of HIPIMS can improve step coverage (requires significant process development)
  • Deposition on one side of the substrate
  • No step coverage expected unless using tilt holder, in which case step coverage can be very good and can be tuned with the tilt angle.
  • Deposition on one side of the substrate
  • Not known
Film Quality
  • Less than thermal oxide. Annealing makes it more dense.
  • Few defects
  • Less dense film
  • Incorporation of hydrogen in the film
  • Not yet known, but expect lower density than bulk material.
Substrate size / Batch size
  • 1-13 100 mm wafers
  • Several small samples
  • 1-7 50 mm wafers
  • 1-3 100 mm wafers
  • 1 150 mm wafer
  • Pieces or
  • 1x4" wafer or
  • 1x6" wafer
  • Many smaller pieces or
  • up to 10x 4" or 6" wafer
  • Up to 4 x 6" wafer or
  • 3x 8" wafers (ask for special holder)
  • Many smaller pieces
  • Beaker depended
Allowed materials
  • Silicon wafers
    • with layers of silicon oxide or silicon (oxy)nitride
  • Quartz wafers
  • Silicon
    • with layers of silicon oxide or silicon (oxy)nitride
  • Quartz
  • IIIV materials (in PECVD2)
  • Small amount of metal (in PECVD3)
  • Silicon
  • Silicon oxide
  • Silicon nitride
  • Silicon (oxy)nitride
  • Photoresist
  • PMMA
  • Mylar
  • SU-8
  • Metals
  • Carbon
  • Acids react with a number of metals to produce hydrogen which, in contact with the air, may cause explosions

* If you wish to deposit more than 100 nm, please talk to responsible staff or write to thinfilm@nanolab.dtu.dk