Specific Process Knowledge/Thermal Process/Annealing: Difference between revisions

Latest revision as of 16:38, 18 January 2024

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Annealing

At DTU Nanolab we have five furnaces and two RTP (rapid thermal processor) that can be used for annealing: Anneal-Oxide furnace (C1), Anneal-bond furnace (C3), Al_anneal furnace (C4), Multipurpose Anneal furnace, RTP2 Jipelec and RTP Annealsys (last one, reserved to research). Annealing normally takes place in an N₂ atmosphere, or it can be done in H₂ or a H₂-N₂ gas mixture in the Multipurpose Anneal furnace. PECVD PBSG glass is annealed in a wet atmosphere which will also oxidize the silicon substrate.

A 20-minute N₂ annealing step is also included in all recipes on the oxidation furnace, this annealing is done after the oxidation.

Comparison of the annealing furnaces

	Anneal Oxide furnace (C1)	Anneal-Bond furnace (C3)	Aluminium Anneal furnace (C4)	Multipurpose Anneal Furnace	RTP2 Jipelec	RTP Annealsys (research tool)
General description	Annealing of 4" and 6" wafers. Annealing of wafers from the LPCVD furnaces and from PECVD4.	Annealing of wafers from Wafer Bonder 02 and from and PECVD4 and PECVD3.	Annealing of wafers with Al and ALD deposited AL2O3 and TiO2.	Annealing, oxidation and resist pyrolysis of different samples.	Rapid thermal processing, usually, annealing (RTA).	Rapid thermal processing: RTA (annealing), RTO (oxidation), RTN (nitridation) and RTH (hydrogenation).
Annealing gas	N₂	N₂	N₂	N₂ H₂ H₂-N₂ gas mixture Vacuum is possible	Ar N₂ Low vacuum is possible (min. 2/3 mbar)	Ar NH₃ O₂ 5% H₂/Ar High vacuum is possible (10^-6 mbar)
Process temperature	700 ^oC - 1100 ^oC	700 ^oC - 1150 ^oC	Up to 500 ^oC	Vacuum: 20 ^oC - 1050 ^oC¨ No vacuum: 20 ^oC - 1100 ^oC	20 ^oC - 1200 ^oC Max. 100 ^oC/s with carrier wafer or sample wafer Max. 50 ^oC/s with SiC-coated graphite susceptor	700 ^oC - 1200 ^oC Max. 150 ^oC/s
Substrate and Batch size	Small samples on a carrier wafer, horizontal 1-30 50 mm wafers 1-30 100 mm wafers 1-30 150 mm wafers	Small samples on a carrier wafer, horizontal 1-30 50 mm wafers 1-30 100 mm wafers	1-30 50 mm wafers 1-30 100 mm wafers	1-30 50 mm, 100 mm or 150 mm wafers 1-50 200 mm wafers Small samples on a carrier wafer, horizontal	Single-wafer process Chips on carrier 50 mm, 100 mm or 150 mm wafers	Single-wafer process Chips on carrier 100 mm or 150 mm wafers
Allowed materials	All processed wafers have to be RCA cleaned, except wafers from LPCVD furnaces and PECVD4.	All processed wafers have to be RCA cleaned, except wafers from the Wafer Bonder 02 and from PECVD4 and PECVD3.	Wafers with Al	Depends on the furnace quartz ware: Clean: Samples that have been RCA cleaned Metal: Almost all materials, permission is needed Resist (for pyrolysis)	Silicon Silicon oxides and nitrides Quartz Metals - ask for permission III-V materials - below 440 °C, otherwise it can lead to outgassing of toxic gases.	Silicon Silicon Nitride Aluminum Oxide

@@ Line 4: / Line 4: @@
 ==Annealing==
-At DTU Nanolab  we have five furnaces and an RTP (Rapid thermal annealing) that can be used for annealing: Anneal-Oxide furnace (C1), Anneal-bond furnace (C3), Al_anneal furnace (C4), Multipurpose Anneal furnace and Jipelec2 RTP. Annealing normally takes place in an N<sub>2</sub> atmosphere, or it can be done in H<sub>2</sub> or a H<sub>2</sub>-N<sub>2</sub> gas mixture in the Multipurpose Anneal furnace. PECVD PBSG glass is annealed in a wet atmosphere which will also oxidize the silicon substrate.
+At DTU Nanolab  we have five furnaces and two RTP (rapid thermal processor) that can be used for annealing: Anneal-Oxide furnace (C1), Anneal-bond furnace (C3), Al_anneal furnace (C4), Multipurpose Anneal furnace, RTP2 Jipelec and RTP Annealsys (last one, reserved to research). Annealing normally takes place in an N<sub>2</sub> atmosphere, or it can be done in H<sub>2</sub> or a H<sub>2</sub>-N<sub>2</sub> gas mixture in the Multipurpose Anneal furnace. PECVD PBSG glass is annealed in a wet atmosphere which will also oxidize the silicon substrate.
 A 20-minute N<sub>2</sub> annealing step is also included in all recipes on the oxidation furnace, this annealing is done after the oxidation.
 ==Comparison of the annealing furnaces==
 {|border="1" cellspacing="1" cellpadding="3" style="text-align:left;"
 |-
@@ Line 21: / Line 22: @@
 !
 [[Specific Process Knowledge/Thermal Process/C4 Aluminium Anneal furnace|Aluminium Anneal furnace (C4)]]
+!
+[[Specific Process Knowledge/Thermal Process/Furnace: Multipurpose annealing| Multipurpose Anneal Furnace]]
 !
 [[Specific_Process_Knowledge/Thermal_Process/RTP Jipelec 2| RTP2 Jipelec]]
 !
-[[Specific Process Knowledge/Thermal Process/Furnace: Multipurpose annealing| Multipurpose Anneal Furnace]]
+[[Specific_Process_Knowledge/Thermal_Process/RTP Annealsys| RTP Annealsys (research tool)]]
 |-
@@ Line 33: / Line 36: @@
 |Annealing of wafers from Wafer Bonder 02 and from and PECVD4 and PECVD3.
 |Annealing of wafers with Al and ALD deposited AL2O3 and TiO2.
+|Annealing, oxidation and resist pyrolysis of different samples.
 |Rapid thermal processing, usually, annealing (RTA).
-|Annealing, oxidation and resist pyrolysis of different samples
+|Rapid thermal processing: RTA (annealing), RTO (oxidation), RTN (nitridation) and RTH (hydrogenation).
 |-
@@ Line 46: / Line 50: @@
 |
 *N<sub>2</sub>
+|
+*N<sub>2</sub>
+*H<sub>2</sub>
+*H<sub>2</sub>-N<sub>2</sub> gas mixture
+*Vacuum is possible
 |
 *Ar
@@ Line 51: / Line 60: @@
 *Low vacuum is possible (min. 2/3 mbar)
 |
-*N<sub>2</sub>
+*Ar
-*H<sub>2</sub>
+*NH<sub>3</sub>
-*H<sub>2</sub>-N<sub>2</sub> gas mixture
+*O<sub>2</sub>
-*Vacuum is possible
+*5% H<sub>2</sub>/Ar
+*High vacuum is possible (10<sup>-6</sup> mbar)
 |-
@@ Line 66: / Line 76: @@
 |
 *Up to 500 <sup>o</sup>C
+|
+*Vacuum: 20 <sup>o</sup>C - 1050 <sup>o</sup>C¨
+*No vacuum: 20 <sup>o</sup>C - 1100 <sup>o</sup>C
 |
 *20 <sup>o</sup>C - 1200 <sup>o</sup>C
@@ Line 71: / Line 84: @@
 * '''Max. 50 <sup>o</sup>C/s''' with SiC-coated graphite '''susceptor'''
 |
-*Vacuum: 20 <sup>o</sup>C - 1050 <sup>o</sup>C¨
+*700 <sup>o</sup>C - 1200 <sup>o</sup>C
-*No vacuum: 20 <sup>o</sup>C - 1100 <sup>o</sup>C
+*Max. 150 <sup>o</sup>C/s
 |-
@@ Line 90: / Line 103: @@
 *1-30 50 mm wafers
 *1-30 100 mm wafers
+|
+*1-30 50 mm, 100 mm or 150 mm wafers
+*1-50 200 mm wafers
+*Small samples on a carrier wafer, horizontal
 |
 *Single-wafer process
@@ Line 95: / Line 112: @@
 *50 mm, 100 mm or 150 mm wafers
 |
-*1-30 50 mm, 100 mm or 150 mm wafers
+*Single-wafer process
-*1-50 200 mm wafers
+*Chips on carrier
-*Small samples on a carrier wafer, horizontal
+*100 mm or 150 mm wafers
 |-
@@ Line 109: / Line 126: @@
 |
 *Wafers with Al
+|
+*Depends on the furnace quartz ware:
+**Clean: Samples that have been RCA cleaned
+**Metal: Almost all materials, permission is needed
+**Resist (for pyrolysis)
 |
 *Silicon
 *Silicon oxides and nitrides
 *Quartz
-*Metals - ask for permisson
+*Metals - ask for permission
 *III-V materials - '''below 440 °C''', otherwise it can lead to outgassing of toxic gases.
 |
-*Depends on the furnace quartz ware:
+*Silicon
-**Clean: Samples that have been RCA cleaned
+*Silicon Nitride
-**Metal: Almost all materials, permission is needed
+*Aluminum Oxide
-**Resist pyrolysis
 |-
 |}
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Specific Process Knowledge/Thermal Process/Annealing: Difference between revisions

Latest revision as of 16:38, 18 January 2024

Annealing

Comparison of the annealing furnaces

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