Kapton etch process development

Kapton Etch Process Kapton Etch Process DevelopmentDevelopment1986 to 19881986 to 1988

John GlenningJohn Glenning

7/20/20137/20/2013

© 2011 John Glenning© 2011 John Glenning

Kapton Etch Process DevelopmentKapton Etch Process Development

IBM decided to enter the flexible circuit market

Flip-Chip Technology using thermal compression bonding to replace the C4 Chip Attach Technology



IBM decided to enter the flexible circuit market

Flip-Chip Technology using thermal compression bonding to replace the C4 Chip Attach Technology

PRODUCTS FAMILIES:

Micro-electronic circuitry

Computer hard drives

High performance electric harnesses for the Department of Defense

Automotive harnesses

Aerospace

Industrial applications (flexible heaters, printer heads,…)© 2011 John Glenning© 2011 John Glenning


Kapton

Kapton is a polyimide film developed by DuPont



Kapton

Kapton is a polyimide film developed by DuPont

BENEFITS & STRENTHS:

Very durable

Flexible

Robust to vibration

Excellent electrical, thermal, chemical and mechanical properties

Can withstand extreme temperature



Manufacturing Process

1. Metalize the Kapton surface using sputtering





2. Pattern the electrical circuitry using photolithography, wet processing & plating on both the top and bottom surfaces of the Kapton






3. Pattern the Kapton using photolithography and wet processing







4. Attach the semiconductor chip using thermal compression bonding







4. Attach the semiconductor chip using thermal compression bonding

5. Encapsulate the system, if required



Manufacturing Process Development

All manufacturing technologies existed in IBM except for Kapton etch and thermal compression bonding





Myself and another engineer were asked to join the development team a year before the rest of the team was formed.





Myself and another engineer were asked to join the development team a year before the rest of the team was formed.

I was responsible for developing the entire process for etching Kapton:

1.Develop a chemistry than can etch Kapton

2.Identify a photoresist system that can withstand the Kapton etch process

3.Develop post processing rinsing, cleaning and drying operations



Chemistry

A literature searched identified two existing chemistries

1. Ethylenediamine: Highly carcinogenic

2. Hydrazine Hydrate: Rocket Fuel (very explosive)



Chemistry




Safety would not approve either chemistry unless it was demonstrated that no alternative chemistries existed



Chemistry




Safety would not approve either chemistry unless it was demonstrated that no alternative chemistries existed

Worked with Corporate R & D and identified highly concentrated potassium or sodium hydroxide at elevated temperatures as potential chemistries.



Process Refinement

Built a prototype line in a lab to build product at sizes larger then beakers

Immersion processes with heaters and spargers



Process Refinement



Tested the process chemistries and temperature windows for etch rates based on projected volumes and equipment size

Settled on 7M KOH at 95ºC



Process Refinement





Tested about 30 photoresist systems until we found one that completely withstood the etching chemistry.



Process Refinement





Tested about 30 photoresist systems until we found one that completely withstood the etching chemistry.

Developed a surface neutralization operation (HCl) and rinsing processes



Building the Pilot Line

The rest of the team was formed

The final process would not be immersion. It would be spray. Spray processes give much better mass transfer than immersion.






Hydrochloric Acid neutralization step







Three counter-current cascading water rinses








Hot air dry








Hot air dry

Write the equipment specifications, visit and identify vendors.

Awarded build and installation contracts.

Installed and debugged the process and the equipment .© 2011 John Glenning© 2011 John Glenning


Initial Product Builds

Initial development run:

At 100x magnification, an unknown material was bridging circuits, which was unacceptable.

Lab analysis determined the material to be partially etch Kapton which was redeposited during the etching process




Initial development run:

At 100x magnification, an unknown material was bridging circuits, which was unacceptable.

Lab analysis determined the material to be partially etch Kapton which was redeposited during the etching process

Developed a rinsing chemistry that completely removed this material (0.5 M potassium hydroxide at room temperature).




Excessive “scalloping” of the Kapton was observed near the circuit lines. Product Manager determined this to be a defect and it need to be resolved.





Root cause was determined to be a “tenting” of the laminated photoresist over the circuit lines. This created a channel near the circuit lines and acted as a capillary. The capillary effect drew etchant deep under the photoresist causing this over etch.






It was decided that we would presoak the Photoresist-Kapton System with water to fill the capillary. This solved the scalloping problem, but now we were over etching the material.







It was determined this was caused by the water swelling the Kapton allowing for more repaid penetration of the etchant. Kapton is very hydrophilic.







It was determined this was caused by the water swelling the Kapton allowing for more repaid penetration of the etchant. Kapton is very hydrophilic.

Presoaking the Kapton with water tripled the etch rate.



Understanding the Polyamic Acid Etching Process

In a previous project, I was developing the etching for polyamic acid, which is the precursor of polymide. Polyamic acid is etched using 1 M KOH and 40ºC.





Polymaic acid becomes polyimide by applying heat and the process is know as imidization.






Spraying potassium hydroxide created potassium carbonate. Carbon dioxide is absorbed during the spraying process and reacts with the potassium hydroxide to create potassium carbonate.

2 KOH + CO2 → K2CO3 + H20






Spraying potassium hydroxide created potassium carbonate. Carbon dioxide is absorbed during the spraying process and reacts with the potassium hydroxide to create potassium carbonate.

2 KOH + CO2 → K2CO3 + H20

If the potassium carbonate concentration gets too high, the etching reaction will shut down.




In the pilot line, I tested the entire range of potassium hydroxide, potassium carbonate concentrations and etchant temperature to determine the effect on the etching of Kapton




In the pilot line, I tested the entire range of potassium hydroxide, potassium carbonate concentrations and etchant temperature to determine the effect on the etching of Kapton:

1. The potassium hydroxide concentration determine the etch rate through the Kapton Film






2. The potassium carbonate concentration determine the etch undercut of the Kapton Film






2. The potassium carbonate concentration determine the etch undercut of the Kapton Film

This was documented by a series of cross-section and this effect was reproducible.



Permanent Etch Mask Product Qualification

When planning for this product qualification, I expressed a concern to management that we would fail Reliability Testing because of ionic entrapment in the area between the permanent etch mask and the edge of the Kapton.





It was determined that they would go ahead with the Qualification because of the schedule.






Product failed qualification due to Corrosion-Migration.







I presented my findings to Senior Management. It was agreed to rerun Product Qualification with my alternative chemistry (7M KOH, 3M K2CO3 at 95ºC).








This time, they passed qualification.








This time, they passed qualification.

This became the Plan-of Record Process for Permanent Etch Masks© 2011 John Glenning© 2011 John Glenning


Technology Transfer

I was a member of the Development-Manufacturing Team that transferred the process to manufacturing



Technology Transfer


I was jointly responsible for the equipment design, build, installation and debug with the Manufacturing Engineer for the Kapton Etch sector



Technology Transfer



I was jointly responsible for the process scale-up



Technology Transfer




IBM Qualifies Manufacturing processes using a 4 Level Stage Gate Process



Technology Transfer





Development leads the first two Gates with Manufacturing in support



Technology Transfer






Manufacturing leads the second two Gates with Development in support



Technology Transfer






Manufacturing leads the second two Gates with Development in support

The process was successfully qualified© 2011 John Glenning© 2011 John Glenning


Results

4 US Patents were issued for this Project

US Patent 4,846,929: Wet etching of thermally or chemically cured polyimide

US Patent 4,857,143: Wet etching of cured polyimide

US Patent 4,883,744: Forming a polymide pattern on a substrate

US Patent 5,203,955: Method for etching an organic polymeric material

In 1988, I was given an IBM Division Award for my work.


New Product CommercializationNew Product Commercialization

End of Presentation
