Specific Process Knowledge/Etch/Etching of Bulk Glass: Difference between revisions

From LabAdviser
← Older edit
VisualWikitext
Fj (talk | contribs)
Bureaucrats, danchip, Administrators
143 edits
No edit summary
Rkch (talk | contribs)
DCH-Employees-701, NLAB-Employees-701, NLAB-LabmanagerAllUsers
271 edits
No edit summary
 
(79 intermediate revisions by 6 users not shown)
Line 1: Line 1:
At Danchip, we have two types of bulk glass substrates: Borosilicate glass (Borofloat) and fused silicate glass which in cleanliness match quartz.
'''Unless anything else is stated, everything on this page, text and pictures are made by DTU Nanolab.'''


'''All links to Kemibrug (SDS) and Labmanager Including APV and QC requires login.'''


Silicon oxide can be etched using either wet chemistry or dry etch equipment. Wet chemistry is mainly used to remove all the oxide on the surface (backside and front side) of a wafer or for isotrotropic etching. Dry etching etches anisotropic. It etches one side of the wafer at a time and can be used to etch structures with several masking materials.
'''Feedback to this page''': '''[mailto:labadviser@nanolab.dtu.dk?Subject=Feed%20back%20from%20page%20http://labadviser.nanolab.dtu.dk/index.php/Specific_Process_Knowledge/Etch/Etching_of_Bulk_Glass click here]'''
<!-- Replace "http://labadviser.nanolab.dtu.dk/..." with the link to the Labadviser page-->


== Comparing methods for etching bulk glass at DTU Nanolab ==


Etching of glass can be done either wet or dry. Wet etching is done with HF. Dry etching can be done either with [[Specific Process Knowledge/Etch/AOE (Advanced Oxide Etch)|AOE]] using fluorine chemistry (only fused silica) or with [[Specific Process Knowledge/Etch/IBE⁄IBSD Ionfab 300|IBE]] by sputtering with Ar ions and/or using fluorine chemistry.


40% HF 3µm/min
At DTU Nanolab, we have two types of bulk glass substrates: Borosilicate glass (Borofloat 33 (like pyrex)) and fused silica glass which in cleanliness is similar to quartz. Both types are etched wet in a special set-up placed in a fumehood using a concentrated HF-solution (isotropic etch).
Beaker
The set-up consists of a 5L plastic beaker placed on a stirring plate (magnetic stirring) and a special horizontal wafer holder. Normally a 40% pre-mixed HF solution is used.
Maske?


Beskrives en hel process.
Masking materials and pre-treatment of the glass surface prior to the deposition of the masking material is a special concern in particular for deep etching (> 10µm).


==Comparison of wet Silicon Oxide etch and dry etches (RIE and AOE) etch for etching of Silicon Oxide==
Due to the high cleanliness fused silica is allowed access to basically all machines meaning that e.g. LPCVD silicon can be deposited as masking material. This is an excellent mask even for quite deep etches.
{| border="2" cellspacing="0" cellpadding="4" align="center"
 
!  
Regarding borosilicate glass masking is more tricky. Sputtered Si, Cr or Cr/Au can be used. It is a challenge to avoid delamination, pinholes and cracks in the masking material. 
! Wet Silicon Oxide etch (BHF and SIO Etch (wetting agent))
 
! RIE
 
! AOE
*[[/AOE etching of fused silica|AOE etching of fused silica]]
|- valign="top"
*[[/HF Etch of Glass|HF Etch of Glass (fused silica and borofloat)]]
|'''General description'''
 
==Compare the methods for bulk glass etching==
 
{|border="1" cellspacing="1" cellpadding="3" style="text-align:left;"
|-
 
|-
|-style="background:silver; color:black"
!
![[Specific Process Knowledge/Etch/Wet Silicon Oxide Etch (BHF)|Wet Silicon Oxide etch (BHF/HF)]]
![[Specific Process Knowledge/Etch/ASE (Advanced Silicon Etch)|ASE]]
![[Specific Process Knowledge/Etch/AOE (Advanced Oxide Etch)|AOE (Advanced Oxide Etch)]]
![[Specific Process Knowledge/Etch/IBE&frasl;IBSD Ionfab 300|IBE/IBSD Ionfab 300]]
 
|-
 
|-
|-style="background:WhiteSmoke; color:black"
!Generel description
|
|
*Isotropic etch
*Isotropic etch
Line 25: Line 46:
*Anisotropic etch: vertical sidewalls
*Anisotropic etch: vertical sidewalls
|
|
*Anisotropic etch: vertical sidewalls, especially good for deep etch and high aspect ratio etch  
*Anisotropic etch: vertical sidewalls
|-valign="top"
|
|'''Possible masking materials'''
*Primarily for pure physical etch by sputtering with Ar-ions
|-
 
|-
|-style="background:LightGrey; color:black"
!Possible masking materials
|
|
*Photoresist
*Photoresist
*Silicon nitride
*PolySilicon
*Silicon nitride (LPCVD)
*Blue film
*Cr/Au for deeper etches (plastic beaker)
|
|
*Photoresist
*Photoresist
*DUV resist
*E-beam resist
*(Poly)Silicon
*(Poly)Silicon
*Aluminium
*Silicon Nitride
*Chromium (ONLY RIE2!)
*Metals if they cover less than 5% of the wafer area
*Other metals that covers less the 5% of the wafer area (ONLY RIE2!)
|
|
*Photoresist
*Photoresist
*DUV resist
*E-beam resist
*(Poly)Silicon
*(Poly)Silicon
*Silicon Nitride
*Aluminium
*Aluminium
|- valign="top"
*Chromium (Please try to avoid this)
|'''Etch rate'''
|
*Any material that is accepted in the machine
|-
 
|-
|-style="background:WhiteSmoke; color:black"
!Etch rate range
|
|
*~75 nm/min (Thermal oxide) in BHF
*~75 nm/min (Thermal oxide) in BHF
*~90 nm/min (Thermal oxide) in SIO Etch
*~80 nm/min (Thermal oxide) in BOE 7:1 Etchant VLSI with Surfactant
*~25 nm/min (Thermal oxide) in 5%HF
*~3-4µm/min in 40%HF
|
|
*Typically 40-120 nm/min can be increased or decreased by using other recipe parameters. 
*Process dependent
*Expected range: ~ less than 20 nm/min - ~200 nm/min  
|
|
*Typically 200-600 nm/min can be increased or decreased by using other recipe parameters.
*Process dependent
|-valign="top"
*Expected range: ~ less than 230 nm/min - ~550 nm/min
|'''Batch size'''
|
|
*1-25 wafers at a time
*Process dependent
*Expected ~10-30 nm/min
|-
 
|-
|-style="background:LightGrey; color:black"
!Substrate size
|
|
*1 wafer at a time
*<nowiki>#</nowiki>1-25 100 mm wafers in our 100mm bath
*What can be fitted in a plastic beaker
|
|
*1 wafer at a time
*As many small samples as can be fitted on the 100mm carrier (bad/no cooling!)
|-valign="top"
*<nowiki>#</nowiki>1 100mm wafer (or smaller with carrier)
|'''Size of substrate'''
*<nowiki>#</nowiki>1 150mm wafer (only when set up for 150mm)
|
|
*4" wafers
*As many small samples as can be fitted on a 100mm wafer
*<nowiki>#</nowiki>1 50 mm wafer fitted on a 100mm wafer
*<nowiki>#</nowiki>1 100 mm wafer
*<nowiki>#</nowiki>1 150 mm wafers (only when the system is set up to 150mm)
|
|
*4" wafers or smaller pieces
*As many samples as can be securely fitted on a up to 200mm wafer
|
*<nowiki>#</nowiki>1 50 mm wafer with special carrier
*6" or 4" depending on the setup (smaller pieces if you have a carrier wafer)
*<nowiki>#</nowiki>1 100 mm wafer with special carrier
|-valign="top"
*<nowiki>#</nowiki>1 150 mm wafers with special carrier
|'''Allowed materials'''
*<nowiki>#</nowiki>1 200 mm wafer
|-
|-style="background:WhiteSmoke; color:black"
!Allowed materials
|
|
In the dedicated bath:
*Silicon
*Silicon
*Silicon Oxide
*Silicon Oxide
Line 75: Line 130:
*Photoresist
*Photoresist
*Blue film
*Blue film
*Gold (Au) and Nickel (Ni) (but only in BHF2 (KOH)!)
In a plastic beaker:
*No limits cross contamination wise
|
|
*Silicon
*Silicon
Line 82: Line 138:
*Silicon Oxynitride
*Silicon Oxynitride
*Photoresist
*Photoresist
*DUV resist
*E-beam resist
*E-beam resist
*Aluminium
*Other metals if they cover less than 5% of the wafer area
*Chromium (ONLY RIE2!)
*Quartz/fused silica
*Other metals that covers less the 5% of the wafer area (ONLY RIE2!)
|
|
*Silicon
*Silicon
Line 92: Line 148:
*Silicon Oxynitride
*Silicon Oxynitride
*Photoresist
*Photoresist
*DUV resist
*E-beam resist
*E-beam resist
*Aluminium
*Aluminium
*Chromium (try to avoid it)
*Quartz/fused silica
|
*Silicon
*Silicon oxides
*Silicon (oxy)nitrides
*Metals from the +list
*Metals from the -list
*Alloys from the above list
*Stainless steel
*Glass
*III-V materials
*Resists
*Polymers
*Capton tape
|-
|-
|}
|}
<br clear="all" />

Latest revision as of 15:39, 6 February 2023

Unless anything else is stated, everything on this page, text and pictures are made by DTU Nanolab.

All links to Kemibrug (SDS) and Labmanager Including APV and QC requires login.

Feedback to this page: click here

Comparing methods for etching bulk glass at DTU Nanolab

Etching of glass can be done either wet or dry. Wet etching is done with HF. Dry etching can be done either with AOE using fluorine chemistry (only fused silica) or with IBE by sputtering with Ar ions and/or using fluorine chemistry.

At DTU Nanolab, we have two types of bulk glass substrates: Borosilicate glass (Borofloat 33 (like pyrex)) and fused silica glass which in cleanliness is similar to quartz. Both types are etched wet in a special set-up placed in a fumehood using a concentrated HF-solution (isotropic etch). The set-up consists of a 5L plastic beaker placed on a stirring plate (magnetic stirring) and a special horizontal wafer holder. Normally a 40% pre-mixed HF solution is used.

Masking materials and pre-treatment of the glass surface prior to the deposition of the masking material is a special concern in particular for deep etching (> 10µm).

Due to the high cleanliness fused silica is allowed access to basically all machines meaning that e.g. LPCVD silicon can be deposited as masking material. This is an excellent mask even for quite deep etches.

Regarding borosilicate glass masking is more tricky. Sputtered Si, Cr or Cr/Au can be used. It is a challenge to avoid delamination, pinholes and cracks in the masking material.


Compare the methods for bulk glass etching

Wet Silicon Oxide etch (BHF/HF) ASE AOE (Advanced Oxide Etch) IBE/IBSD Ionfab 300
Generel description
  • Isotropic etch
  • Anisotropic etch: vertical sidewalls
  • Anisotropic etch: vertical sidewalls
  • Primarily for pure physical etch by sputtering with Ar-ions
Possible masking materials
  • Photoresist
  • PolySilicon
  • Silicon nitride (LPCVD)
  • Blue film
  • Cr/Au for deeper etches (plastic beaker)
  • Photoresist
  • DUV resist
  • E-beam resist
  • (Poly)Silicon
  • Silicon Nitride
  • Metals if they cover less than 5% of the wafer area
  • Photoresist
  • DUV resist
  • E-beam resist
  • (Poly)Silicon
  • Silicon Nitride
  • Aluminium
  • Chromium (Please try to avoid this)
  • Any material that is accepted in the machine
Etch rate range
  • ~75 nm/min (Thermal oxide) in BHF
  • ~80 nm/min (Thermal oxide) in BOE 7:1 Etchant VLSI with Surfactant
  • ~25 nm/min (Thermal oxide) in 5%HF
  • ~3-4µm/min in 40%HF
  • Process dependent
  • Expected range: ~ less than 20 nm/min - ~200 nm/min
  • Process dependent
  • Expected range: ~ less than 230 nm/min - ~550 nm/min
  • Process dependent
  • Expected ~10-30 nm/min
Substrate size
  • #1-25 100 mm wafers in our 100mm bath
  • What can be fitted in a plastic beaker
  • As many small samples as can be fitted on the 100mm carrier (bad/no cooling!)
  • #1 100mm wafer (or smaller with carrier)
  • #1 150mm wafer (only when set up for 150mm)
  • As many small samples as can be fitted on a 100mm wafer
  • #1 50 mm wafer fitted on a 100mm wafer
  • #1 100 mm wafer
  • #1 150 mm wafers (only when the system is set up to 150mm)
  • As many samples as can be securely fitted on a up to 200mm wafer
  • #1 50 mm wafer with special carrier
  • #1 100 mm wafer with special carrier
  • #1 150 mm wafers with special carrier
  • #1 200 mm wafer
Allowed materials

In the dedicated bath:

  • Silicon
  • Silicon Oxide
  • Silicon Nitride
  • Silicon Oxynitride
  • Photoresist
  • Blue film

In a plastic beaker:

  • No limits cross contamination wise
  • Silicon
  • Silicon Oxide
  • Silicon Nitride
  • Silicon Oxynitride
  • Photoresist
  • DUV resist
  • E-beam resist
  • Other metals if they cover less than 5% of the wafer area
  • Quartz/fused silica
  • Silicon
  • Silicon Oxide
  • Silicon Nitride
  • Silicon Oxynitride
  • Photoresist
  • DUV resist
  • E-beam resist
  • Aluminium
  • Chromium (try to avoid it)
  • Quartz/fused silica
  • Silicon
  • Silicon oxides
  • Silicon (oxy)nitrides
  • Metals from the +list
  • Metals from the -list
  • Alloys from the above list
  • Stainless steel
  • Glass
  • III-V materials
  • Resists
  • Polymers
  • Capton tape


Retrieved from "https://labadviser.nanolab.dtu.dk//index.php?title=Specific_Process_Knowledge/Etch/Etching_of_Bulk_Glass&oldid=44487"