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   Email: chandanr@usc.edu
   Email: chandanr@usc.edu
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== About ==
== About ==
[[File:RIE.jpg|thumb|300px|Oxford PlasmaPro 80 RIE tool in Etch Bay]]
[[File:RIE.jpg|thumb|300px|Oxford PlasmaPro 80 RIE tool in Etch Bay]]
'''Films / Materials:''' This is an Oxford Instruments PlasmaPro 80 reactive ion etcher (RIE) optimized for etching dielectric materials such as SiO₂, Si₃N₄, and Si, with good anisotropy and control. It is primarily used for etching dielectrics in micro- and nanofabrication processes.
'''Films / Materials:''' This is an Oxford Instruments PlasmaPro 80 reactive ion etcher (RIE) optimized for etching dielectric materials such as SiO₂, Si₃N₄, and Si, with good anisotropy and control. It is primarily used for etching dielectrics in micro- and nanofabrication processes.
'''Hardware:''' Parallel-plate capacitively-coupled RF plasma system (13.56 MHz). Open-load design for fast loading/unloading of samples. No load lock; direct chamber access. Electrode/table temperature controlled at 20°C (ambient/chilled). Includes optical endpoint detection (Horiba Jobin Yvon LEM G50) for precise process stop.
'''Hardware:''' Parallel-plate capacitively-coupled RF plasma system (13.56 MHz). Open-load design for fast loading/unloading of samples. No load lock; direct chamber access. Electrode/table temperature controlled at 20°C (ambient/chilled). Includes optical endpoint detection (Horiba Jobin Yvon LEM G50) for precise process stop.
'''Gases:'''
'''Gases:'''
* Ar (argon – physical sputtering/milling component)
* Ar (argon – physical sputtering/milling component)
Line 20: Line 16:
* CHF₃ (trifluoromethane – for selective SiO₂ etching, polymer sidewall passivation)
* CHF₃ (trifluoromethane – for selective SiO₂ etching, polymer sidewall passivation)
* SF₆ (sulfur hexafluoride – high-rate isotropic/fluorine etching of Si/SiO₂)
* SF₆ (sulfur hexafluoride – high-rate isotropic/fluorine etching of Si/SiO₂)
'''Etch Properties:'''
'''Etch Properties:'''
* Primarily anisotropic etching of dielectrics via ion bombardment and chemical reactions.
* Primarily anisotropic etching of dielectrics via ion bombardment and chemical reactions.
Line 26: Line 21:
* High selectivity possible depending on gas mix and power (e.g., SiO₂ over Si with CHF₃/O₂).
* High selectivity possible depending on gas mix and power (e.g., SiO₂ over Si with CHF₃/O₂).
* Excellent process control for uniformity across up to 200 mm substrates.
* Excellent process control for uniformity across up to 200 mm substrates.
'''Applications:''' Etching of dielectric layers (e.g., oxide/nitride masks, passivation removal, via openings), resist descum, surface cleaning/activation. Not for exposed metals (except Cr) or deep polymer etches; polymer may be used as a mask only.
'''Applications:''' Etching of dielectric layers (e.g., oxide/nitride masks, passivation removal, via openings), resist descum, surface cleaning/activation. Not for exposed metals (except Cr) or deep polymer etches; polymer may be used as a mask only.


'''Usage:''' Load sample directly (pieces to 200 mm wafers), select/load recipe, set time/power based on calibrated etch rates. Use endpoint detection for timed or auto-stop processes. Monitor particles and uniformity post-etch.
'''Usage:''' Load sample directly (pieces to 200 mm wafers), select/load recipe, set time/power based on calibrated etch rates. Use endpoint detection for timed or auto-stop processes. Monitor particles and uniformity post-etch.
== Detailed Specifications ==
== Detailed Specifications ==
* Model: PlasmaPro 80 reactive ion etcher
* Model: PlasmaPro 80 reactive ion etcher
Line 44: Line 37:
** SF₆ (max) 100 sccm
** SF₆ (max) 100 sccm
* Features: Optical endpoint detection (Horiba Jobin Yvon LEM G50), open-load design for fast access, excellent etch uniformity and rate control
* Features: Optical endpoint detection (Horiba Jobin Yvon LEM G50), open-load design for fast access, excellent etch uniformity and rate control
=== Restrictions and Materials Allowed ===
=== Restrictions and Materials Allowed ===
{| class="wikitable" style="width:100%; margin-top:12px; border:3px solid #990000; background:#ffffff;"
{| class="wikitable" style="width:100%; margin-top:12px; border:3px solid #990000; background:#ffffff;"
Line 69: Line 61:
* Chromium (Cr) as exposed metal
* Chromium (Cr) as exposed metal
|}
|}
== Safety & Emergency ==
'''Required PPE:''' Safety glasses, cleanroom gloves, bunny suit.
'''Toxic gases used:''' CHF₃, SF₆, CF₄ — fluorine byproducts (HF) possible. Do '''not''' open chamber if gas alarm is active.
'''If the tool alarms or gas cabinet shows red:'''
# Press '''EMO''' (Emergency Machine Off) — red button on the front panel.
# Evacuate Etch Bay 1 and notify staff immediately.
# Call Nanofab staff: Chandan Ramakrishnaiah, +1 (213) 551-6726.
# After hours / life-threatening: USC DPS '''(213) 740-4321''', or 911.
'''Gas leak or chemical exposure:''' Activate bay alarm, exit cleanroom, call DPS.
'''Chamber vent failure:''' Do NOT force open. Leave tool and contact staff.


== Dry Etcher Comparison ==
== Dry Etcher Comparison ==
Use this table to help choose the right etching tool for your process.
Use this table to help choose the right etching tool for your process.
 
{{:Etcher_Comparison}}
{| class="wikitable" style="width:100%; border:3px solid #990000; background:#ffffff; text-align:left;"
|-
! style="background:#990000; color:#FFCC00; padding:10px; border:2px solid #990000; min-width:120px;" | Feature
! style="background:#FFCC00; color:#990000; padding:10px; border:2px solid #990000; font-weight:bold;" | ★ [[Oxford_RIE|Oxford RIE]] (this tool)
! style="background:#990000; color:#FFCC00; padding:10px; border:2px solid #990000;" | [[Tool_list#Oxford_DRIE|Oxford DRIE]]
! style="background:#990000; color:#FFCC00; padding:10px; border:2px solid #990000;" | [[Tool_list#Oxford_DRIE-ALE|Oxford DRIE-ALE]]
! style="background:#990000; color:#FFCC00; padding:10px; border:2px solid #990000;" | [[Tool_list#Oxford_III-V|Oxford III-V]]
! style="background:#990000; color:#FFCC00; padding:10px; border:2px solid #990000;" | [[Tool_list#XeF2_etcher|XeF2 Etcher]]
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Model
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | PlasmaPro 80 RIE
| style="padding:8px; border:1px solid #990000;" | Oxford System 100 DRIE
| style="padding:8px; border:1px solid #990000;" | Oxford DRIE + ALE
| style="padding:8px; border:1px solid #990000;" | PlasmaPro 100 Cobra
| style="padding:8px; border:1px solid #990000;" | Custom built (Armani group)
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Location
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | Etch Bay 1
| style="padding:8px; border:1px solid #990000;" | Etch Bay 1
| style="padding:8px; border:1px solid #990000;" | Etch Bay 1
| style="padding:8px; border:1px solid #990000;" | Etch Bay 1
| style="padding:8px; border:1px solid #990000;" | Deposition Bay 1
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Substrate Size
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | Up to 200 mm (8")
| style="padding:8px; border:1px solid #990000;" | Up to 4" clamp; 2", 3", 4", 6", 8" possible
| style="padding:8px; border:1px solid #990000;" | TBD (commissioning)
| style="padding:8px; border:1px solid #990000;" | Up to 4" clamp; 2", 3", 4", 6", 8" possible
| style="padding:8px; border:1px solid #990000;" | Up to 6"
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Etch Type
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | RIE (capacitively coupled)
| style="padding:8px; border:1px solid #990000;" | DRIE / Bosch (ICP)
| style="padding:8px; border:1px solid #990000;" | DRIE + Atomic Layer Etch
| style="padding:8px; border:1px solid #990000;" | ICP-RIE (cryo capable)
| style="padding:8px; border:1px solid #990000;" | Isotropic chemical etch
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Table RF Power
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | 300 W max
| style="padding:8px; border:1px solid #990000;" | 300 W max
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | 1500 W max
| style="padding:8px; border:1px solid #990000;" | N/A
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | ICP Power
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | None (RIE only)
| style="padding:8px; border:1px solid #990000;" | 3000 W max
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | 1500 W max
| style="padding:8px; border:1px solid #990000;" | N/A
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Table Temperature
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | 20°C
| style="padding:8px; border:1px solid #990000;" | 20°C
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | -120°C to 200°C
| style="padding:8px; border:1px solid #990000;" | 20°C
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Gases
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | Ar, O₂, CF₄, CHF₃, SF₆
| style="padding:8px; border:1px solid #990000;" | Ar, O₂, CF₄, CHF₃, SF₆, C₄F₈
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | Ar, O₂, SF₆, CH₄, H₂, Cl₂, BCl₃, SiCl₄
| style="padding:8px; border:1px solid #990000;" | XeF₂ (crystal source)
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Allowed Materials
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | Si, SiO₂, Si₃N₄, oxide/nitride masks, Cr
| style="padding:8px; border:1px solid #990000;" | Si, SiO₂, SiN, Parylene, Polyimide, LiNbO₃, BCB
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | InP, InAs, GaN, AlGaAs, GaAs, InGaAsP, ITO, Si, SiC, MoS₂, WSe, Graphene
| style="padding:8px; border:1px solid #990000;" | Si only
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Disallowed
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | No metals except Cr; no deep polymer >1 µm
| style="padding:8px; border:1px solid #990000;" | No exposed metals except Cr
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | No metals except Cr; no deep polymer >1 µm
| style="padding:8px; border:1px solid #990000;" | None listed
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Endpoint Detection
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | ✓ Optical (LEM G50)
| style="padding:8px; border:1px solid #990000;" | ✓ Optical
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | ✓ Optical (LEM G50)
| style="padding:8px; border:1px solid #990000;" | ✗
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Best For
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | Dielectric etching, passivation removal, via openings, resist descum
| style="padding:8px; border:1px solid #990000;" | Deep Si etching, high-aspect-ratio structures, Bosch process
| style="padding:8px; border:1px solid #990000;" | Precise atomic-layer-level etch control
| style="padding:8px; border:1px solid #990000;" | III-V semiconductors, exotic/compound materials, cryo etching
| style="padding:8px; border:1px solid #990000;" | Fast isotropic Si etching, high selectivity
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | Status
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | ✓ Operational
| style="padding:8px; border:1px solid #990000;" | ✓ Operational
| style="padding:8px; border:1px solid #990000;" | ⚠ Being commissioned
| style="padding:8px; border:1px solid #990000;" | ✓ Operational
| style="padding:8px; border:1px solid #990000;" | ✓ Operational
|-
| style="background:#fff5f5; font-weight:bold; padding:8px; border:1px solid #990000;" | SOP
| style="padding:8px; border:1px solid #990000; background:#fffdf0;" | [[:File:OXFDRIE80 SOP Updated 2026.pdf|SOP]]
| style="padding:8px; border:1px solid #990000;" | [[:File:DRIE_SOP_-_August_2023.pdf|SOP]]
| style="padding:8px; border:1px solid #990000;" | TBD
| style="padding:8px; border:1px solid #990000;" | [[:File:III_V_Etcher_SOP_-_August_2023.pdf|SOP]]
| style="padding:8px; border:1px solid #990000;" | [[:File:XeF2_SOP_-_June_2023.pdf|SOP]]
|}


== Documentation ==
== Documentation ==
Line 187: Line 83:
* [https://drive.google.com/file/d/15cHZNcl4yK-OBauSIQ__ZOWv5xrtNU40/view?usp=sharing Training video]
* [https://drive.google.com/file/d/15cHZNcl4yK-OBauSIQ__ZOWv5xrtNU40/view?usp=sharing Training video]
* Training required – contact lab staff (Chandan Ramakrishnaiah) [https://usc.qualtrics.com/jfe/form/SV_2ccy8prA0oRcZng Request form]
* Training required – contact lab staff (Chandan Ramakrishnaiah) [https://usc.qualtrics.com/jfe/form/SV_2ccy8prA0oRcZng Request form]
== Recipes & Data ==
== Recipes & Data ==
* Standard Recipes: [https://docs.google.com/spreadsheets/d/e/2PACX-1vQq4XcefR151mYBgklqcWF9FOO8aEkGMUIhjG4EBruVm8xm6_LGaJOBhc3icg2DIVvD4bUZ4bUZ4wXFI1G_/pubhtml?gid=873136343&single=true Standard Recipe]
* Standard Recipes: [https://docs.google.com/spreadsheets/d/e/2PACX-1vQq4XcefR151mYBgklqcWF9FOO8aEkGMUIhjG4EBruVm8xm6_LGaJOBhc3icg2DIVvD4bUZ4wXFI1G_/pubhtml Standard Recipe]
* Process Control and Calibration Data: [https://docs.google.com/spreadsheets/d/1cleuEcpL6Nnjj40jUlnfaEt4aXEZ23ReL1UCT6eQsUY/edit?gid=864539770#gid=864539770 Standard Recipe Calibration]
* Process Control and Calibration Data: [https://docs.google.com/spreadsheets/d/1cleuEcpL6Nnjj40jUlnfaEt4aXEZ23ReL1UCT6eQsUY/edit?gid=864539770#gid=864539770 Standard Recipe Calibration]
==== Recipe Control Charts ====
* SiO2 Etch Control Chart
<div style="margin:10px 0 20px 0;">
<html><iframe width="481" height="257" seamless frameborder="0" scrolling="no"
  src="https://docs.google.com/spreadsheets/d/e/2PACX-1vQq4XcefR151mYBgklqcWF9FOO8aEkGMUIhjG4EBruVm8xm6_LGaJOBhc3icg2DIVvD4bUZ4wXFI1G_/pubchart?oid=1003919682&amp;format=interactive">
</iframe></html>
</div>
* SiNx Etch Control Chart
<div style="margin:10px 0 20px 0;">
<html><iframe width="481" height="257" seamless frameborder="0" scrolling="no" src="https://docs.google.com/spreadsheets/d/e/2PACX-1vQq4XcefR151mYBgklqcWF9FOO8aEkGMUIhjG4EBruVm8xm6_LGaJOBhc3icg2DIVvD4bUZ4wXFI1G_/pubchart?oid=612163521&amp;format=interactive"></iframe></html>
</div>


==== Recipe Control Charts ====
== Troubleshooting ==
* [https://docs.google.com/spreadsheets/d/e/2PACX-1vQq4XcefR151mYBgklqcWF9FOO8aEkGMUIhjG4EBruVm8xm6_LGaJOBhc3icg2DIVvD4bUZ4wXFI1G_/pubchart?oid=1003919682&format=interactive SiO2 Etch Control Chart]
; Plasma won't ignite
* [https://docs.google.com/spreadsheets/d/e/2PACX-1vQq4XcefR151mYBgklqcWF9FOO8aEkGMUIhjG4EBruVm8xm6_LGaJOBhc3icg2DIVvD4bUZ4wXFI1G_/pubchart?oid=612163521&format=interactive SiNx Etch Control Chart]
: Check gas flows are stable, pressure is in range (10–200 mTorr), and RF matching network is tuned.
; Etch rate dropped suddenly
: Chamber may need conditioning. Run an O₂ clean recipe for 30 min.
; Endpoint detector not triggering
: Verify Horiba LEM G50 is on, lens is clean, correct wavelength is selected. See [[:File:OES SOP apr 2026.pdf|OES SOP]].
; Chamber pressure won't drop
: Possible vacuum leak or pump issue. Stop process, notify staff.
 
== Acknowledgment ==
If results from this tool appear in a publication, please acknowledge the facility:
<blockquote>
"This work was performed in part at the USC Nanofab at the University of Southern California, Michelson Center for Convergent Bioscience."
</blockquote>
Please also email the citation to [mailto:chandanr@usc.edu chandanr@usc.edu] so we can track facility output.

Latest revision as of 10:44, 23 April 2026

About

Oxford PlasmaPro 80 RIE tool in Etch Bay

Films / Materials: This is an Oxford Instruments PlasmaPro 80 reactive ion etcher (RIE) optimized for etching dielectric materials such as SiO₂, Si₃N₄, and Si, with good anisotropy and control. It is primarily used for etching dielectrics in micro- and nanofabrication processes. Hardware: Parallel-plate capacitively-coupled RF plasma system (13.56 MHz). Open-load design for fast loading/unloading of samples. No load lock; direct chamber access. Electrode/table temperature controlled at 20°C (ambient/chilled). Includes optical endpoint detection (Horiba Jobin Yvon LEM G50) for precise process stop. Gases:

  • Ar (argon – physical sputtering/milling component)
  • O₂ (oxygen – for ashing, oxidation, or enhancing etch rates)
  • CF₄ (tetrafluoromethane – fluorine-based etching of SiO₂/Si₃N₄)
  • CHF₃ (trifluoromethane – for selective SiO₂ etching, polymer sidewall passivation)
  • SF₆ (sulfur hexafluoride – high-rate isotropic/fluorine etching of Si/SiO₂)

Etch Properties:

  • Primarily anisotropic etching of dielectrics via ion bombardment and chemical reactions.
  • Suitable for shallow to moderate depth etches (avoid deep polymer etching >1 µm due to restrictions).
  • High selectivity possible depending on gas mix and power (e.g., SiO₂ over Si with CHF₃/O₂).
  • Excellent process control for uniformity across up to 200 mm substrates.

Applications: Etching of dielectric layers (e.g., oxide/nitride masks, passivation removal, via openings), resist descum, surface cleaning/activation. Not for exposed metals (except Cr) or deep polymer etches; polymer may be used as a mask only.

Usage: Load sample directly (pieces to 200 mm wafers), select/load recipe, set time/power based on calibrated etch rates. Use endpoint detection for timed or auto-stop processes. Monitor particles and uniformity post-etch.

Detailed Specifications

  • Model: PlasmaPro 80 reactive ion etcher
  • Location: Etch Bay 1
  • Substrate size: Up to 8 (200 mm) wafers (pieces/smaller possible; open loading)
  • RF Power: Table RF power (max) 300 W (13.56 MHz)
  • Table temperature: 20°C (chilled/controlled) / (max) 80°C
  • Gases:
    • CHF₃ (max) 100 sccm
    • Ar (max) 100 sccm
    • O₂ (max) 50 sccm
    • CF₄ (max) 50 sccm
    • SF₆ (max) 100 sccm
  • Features: Optical endpoint detection (Horiba Jobin Yvon LEM G50), open-load design for fast access, excellent etch uniformity and rate control

Restrictions and Materials Allowed

Restrictions Materials Allowed
  • No exposed metals except Cr
  • No deep polymer etching (> 1 µm)
  • Polymers allowed only as masks
  • Not intended for metal etching
  • Avoid uncalibrated deep or high-aspect-ratio processes
  • SiO₂
  • Si₃N₄
  • Si
  • Oxide masks
  • Nitride masks
  • Passivation removal
  • Via openings
  • Resist descum
  • Surface cleaning and activation
  • Chromium (Cr) as exposed metal

Safety & Emergency

Required PPE: Safety glasses, cleanroom gloves, bunny suit. Toxic gases used: CHF₃, SF₆, CF₄ — fluorine byproducts (HF) possible. Do not open chamber if gas alarm is active. If the tool alarms or gas cabinet shows red:

  1. Press EMO (Emergency Machine Off) — red button on the front panel.
  2. Evacuate Etch Bay 1 and notify staff immediately.
  3. Call Nanofab staff: Chandan Ramakrishnaiah, +1 (213) 551-6726.
  4. After hours / life-threatening: USC DPS (213) 740-4321, or 911.

Gas leak or chemical exposure: Activate bay alarm, exit cleanroom, call DPS. Chamber vent failure: Do NOT force open. Leave tool and contact staff.

Dry Etcher Comparison

Use this table to help choose the right etching tool for your process.

Feature Oxford RIE Oxford DRIE Oxford DRIE-ALE Oxford III-V XeF2 Etcher
Model PlasmaPro 80 RIE Oxford System 100 DRIE Oxford DRIE + ALE PlasmaPro 100 Cobra Custom built (Armani group)
Location Etch Bay 1 Etch Bay 1 Etch Bay 1 Etch Bay 1 Deposition Bay 1
Substrate Size Up to 200 mm (8") Up to 4" clamp; 2", 3", 4", 6", 8" possible Up to 4" clamp; 2", 3", 4", 6", 8" possible Up to 4" clamp; 2", 3", 4", 6", 8" possible Up to 6"
Etch Type RIE (capacitively coupled) DRIE / Bosch (ICP) DRIE + Atomic Layer Etch ICP-RIE (cryo capable) Isotropic chemical etch
Table RF Power 300 W max 300 W max 300 W max 1500 W max N/A
ICP Power None (RIE only) 3000 W max 3000 W max 1500 W max N/A
Table Temperature 20°C 20°C -120°C to 200°C allowed

(-150°C to 400°C max)

-120°C to 200°C allowed

(-150°C to 400°C max)

20°C
Gases Ar, O₂, CF₄, CHF₃, SF₆ Ar, O₂, CF₄, CHF₃, SF₆, C₄F₈ Ar, O₂, C₄F₈, SF₆, BCl₃, Cl₂, H₂, N₂O, CH₄, CF₄, CHF₃ Ar, O₂, SF₆, CH₄, H₂, Cl₂, BCl₃, SiCl₄ XeF₂ (crystal source)
Allowed Materials Si, SiO₂, Si₃N₄, oxide/nitride masks, Cr Si, SiO₂, SiN, Parylene, Polyimide, LiNbO₃, BCB InP, InAs, GaN, AlGaAs, GaAs, InGaAsP, ITO, Si, SiC, MoS₂, WSe, Graphene InP, InAs, GaN, AlGaAs, GaAs, InGaAsP, ITO, Si, SiC, MoS₂, WSe, Graphene Si only
Disallowed No metals except Cr; no deep polymer >1 µm No exposed metals except Cr No metals except Cr; no deep polymer >1 µm No metals except Cr; no deep polymer >1 µm None listed
Endpoint Detection Optical (LEM G50) Not Available TBD Optical (LEM G50) Not Available
Best For Dielectric etching, passivation removal, via openings, resist descum Deep Si etching, high-aspect-ratio structures, Bosch process Precise atomic-layer-level etch control III-V semiconductors, exotic/compound materials, cryo etching Fast isotropic Si etching, high selectivity
Status Operational Operational Operational Operational Operational
SOP SOP SOP TBD SOP SOP

Documentation

Recipes & Data

Recipe Control Charts

  • SiO2 Etch Control Chart

  • SiNx Etch Control Chart

Troubleshooting

Plasma won't ignite
Check gas flows are stable, pressure is in range (10–200 mTorr), and RF matching network is tuned.
Etch rate dropped suddenly
Chamber may need conditioning. Run an O₂ clean recipe for 30 min.
Endpoint detector not triggering
Verify Horiba LEM G50 is on, lens is clean, correct wavelength is selected. See OES SOP.
Chamber pressure won't drop
Possible vacuum leak or pump issue. Stop process, notify staff.

Acknowledgment

If results from this tool appear in a publication, please acknowledge the facility:

"This work was performed in part at the USC Nanofab at the University of Southern California, Michelson Center for Convergent Bioscience."

Please also email the citation to chandanr@usc.edu so we can track facility output.

Retrieved from "https://wiki.nanofab.usc.edu/index.php?title=Oxford_RIE&oldid=896"