Fluorine ICP Etcher (PlasmaTherm/SLR Fluorine ICP): Difference between revisions
(→Recipes: mention historical data) |
(Text replacement - "/wiki/index.php/" to "/wiki/index.php?title=") |
||
Line 39: | Line 39: | ||
= Recipes = |
= Recipes = |
||
* Recipes > [[Dry Etching Recipes|Dry Etching]] > [https://wiki.nanotech.ucsb.edu/wiki/index.php |
* Recipes > [[Dry Etching Recipes|Dry Etching]] > [https://wiki.nanotech.ucsb.edu/wiki/index.php?title=ICP_Etching_Recipes#PlasmaTherm.2FSLR_Fluorine_Etcher '''PlasmaTherm/SLR Fluorine Etcher'''] |
||
** Starting point recipes for the FL-ICP |
** Starting point recipes for the FL-ICP |
||
** ''Historical Data'' records "calibration" etches to test tool performance. |
** ''Historical Data'' records "calibration" etches to test tool performance. |
Revision as of 19:47, 4 September 2021
|
About
The system is a Plasma-Therm 770 SLR series system with a loadlock. The system has an Inductively Coupled Plasma (ICP) coil and a capactively coupled substrate RF supply to independently control plasma density and ion energy in the system. The system is fully computer controlled in all aspects of the pumping cycles and process control, and can be programmed by the user. The fixturing is configured for 4" diameter Si wafers and uses a clamp to hold the sample on the RF chuck.
The materials allowed in the system are limited to Silicon, SiO2, Si3N4, SiOXNY, and polymer films such as photoresist, PMMA, and polyimide. Other materials can be placed in the chamber, such as metal layers on the surface, only if they will remain completely protected from the plasma by an allowed material during the entire etch. Some alternate stop-etch materials may be allowed upon discussion with facility staff.
Helium back-side cooling is used to keep the sample cool during the etch. Temperature control is very important as the polymer passivation layer is chemically etched away by the fluorine gas at elevated temperatures, resulting in loss of profile control. Pieces of wafers can be mounted onto 4" silicon wafers using thin, uniform, bubble-free hard baked photoresist. The etch rate is dependent on the open area of silicon (macro-loading effect) with large open area samples etching slower than small open area samples. Features with a high aspect ratio will also etch slower than more open areas. This is known as RIE lag or the micro-loading effect.
The in-situ laser monitor installed on the chamber allows for repeatable etches and endpoint detection via continuous optical monitoring of the wafer reflectivity in a user-determined location, through a porthole on the chamber.
Detailed Specifications
- 1000 W ICP coil power at 2 MHz and 500 W substrate bias at 13.56 MHz plasma generators
- C4F8, SF6, O2, Ar, N2, CHF3, CF4 gases available
- He-back-side cooling
- Windows-based computer control of process and wafer handling
- Allowed materials: Silicon, SiO2, Si3N4, SiOXNY, and polymer films such as photoresist, PMMA, and polyimide; other stop-etch materials on request
- Realized etch rates (including passivation steps) of > 3 µm / min. Using the standard Plasma Therm recipe, a nominal etch rate of 2 um / min. is achieved; etch rate dependent on conditions and open area
- Laser endpoint monitoring with camera and simulation software, for repeatable etching - see: Intellemetrics LEP 500
Documentation
Recipes
- Recipes > Dry Etching > PlasmaTherm/SLR Fluorine Etcher
- Starting point recipes for the FL-ICP
- Historical Data records "calibration" etches to test tool performance.
- You can see a full list of all tools and all materials able to be etched by each on our Dry Etching Recipes Table.