1. Organic Materials Development for Advanced Lithographic Applications
Jacob R. Adams
Willson Research Group
University of Texas at Austin

2. Rising Cost of Wafer Fabs Vs. GNPs
100 nm
technology
node, 2004
70 nm
50 nm
35 nm
technology
technology
technology
GNP of:
node, 2007
node, 2010
node, 2013
1000
Denmark
Singapore
100
Hungary
Czech Rep.
Luxemburg
Guatemala
billion $ 10
Panama
Kenya
Macedonia 1
Monaco
0.1
0.01 10 1
0.1
0.01
feature size [µm] 
Ralph Dammel

3. Moore’s Law
# Transistors

4. Minimum Feature Size Reduction in Semiconductor Devices: Moore’s Law
10,000
436 nm Contact Exposure
4 K / 7000
5,000
16 K / 5000
436 nm 1:1 Projection
64 K / 3000
2,000
256 K / 1500
436 nm
5:1 Projection
1,000
1 M / 1000
4 M / 750
Minimum Dimension (nm)
500
365 nm
16 M / 500
64 M / 350
R= k l NA
200
248 nm
256 M / 250
1 G / 180
193 nm
100
4 G / 120
157 nm ?
16 G / ? 50
1976
1980
1984
1988
1992
1996
2000
2004
Year

5. Photolithographic Process
Photoresist
Substrate
Silicon Wafer

6. Well, How do These Things Really Work??
resist image

7. Some Scale Perspective
1990
1980
800 Å
These 80nm features are less than 600 carbon atoms wide [based on the average length of a carbon-carbon bond]
193nm resist images
2001
2002
40nm images

8. Modular Resist Design Backbone Etch Barrier Latent Acidic Group
Protecting
Patterson, K. et. al. Proc. SPIE-Int. Soc. Opt. Eng. 2000, 3999,

9. Resist Progression
365 nm
436 nm
193 nm
248 nm

10. Modular Resist Design for 193 nm
Aromatics become too absorbing at 193 nm
Etch rate α N/(Nc-No)
Replace with bridged cyclic aliphatics
Ohnishi, Y. et al. J. Electrochem. Soc. 1983, 130(1),

11. Examples of 193 nm resists Acrylate with Pendant
Cage Structure
COMA (Cyclic Olefin Maleic Anhydride)

12. Early Imprint Lithography
Tang Dynasty Templates
600 AD
Mesopotamian Templates 12

13. The Step and Flash Imprint Lithography (SFIL) Process
1. Monomer Dispense
2. Spread and Fill
3. UV Cure
4. Separate
Release treatment
Template
Monomer droplet
Substrate film stack
Spreading Monomer
UV radiation
Crosslinked film
Components
Steps

14. Unparalleled Resolution
20 nm Replication with no LER
Rogers, J. A. et al. Nano Letters (12), 2467–71.

15. SFIL Formulations Bulky Monomer Low Viscosity Monomer
Increase Tg
Low Viscosity Monomer
Improve Template Filling
Silicon Containing Monomer
- Etch Resistance
Cross-linkable Monomer
Strengthen Mechanical Properties
Photoinitiator

16. Motivation for Strippable Materials
Issues:
Highly cross-linked polymers are insoluble
Silicon containing polymers resist oxidative cleaning
Cross-linked Imprint Resist
Solution:
Strippable polymers
Improve template lifetime
These templates are EXPENSIVE!!!
Aid wafer reworking

17. Strippable Materials De-cross-linking
Insoluble Cross-linked Network
Soluble Polymers
Heat, Acid, light, etc.
Cross-linker
Polymer
Polymer

18. Acid Degradable Cross-linkers
Tertiary Ester Diacrylate (TEDA)
Viscosity: cP
Dose to cure: 13.5 mJ/cm2
Acetal Diacrylate (ADA)
Viscosity: cP
Dose to cure: 58.3 mJ/cm2
Targeted values: Viscosity < 20 cP, Dose to cure < 90 mJ/cm2
Palmieri, F. L. Ph.D. Thesis, Univ. of Texas at Austin, Austin, TX USA 2008.

19. Mechanism for acid-catalyzed cleavage of tert-Butyl esters

20. Mechanism of Acetal Formation
-Driving the Process

21. Retrosynthetic Analysis

22. How to Avoid This Problem
An azeotrope is a mixture of two or more liquids whose proportions cannot be altered by simple distillation. This happens because, when an azeotrope is boiled, the vapor has the same proportions of constituents as the unboiled mixture.

23. A Few Boiling Points Water 100.0 Methanol 64.7 Benzene 80.2
Component
Boiling Point (oC)
Water
100.0
Methanol
64.7
Benzene
80.2
Benzene:Water
69.3
Benzene:Methanol
58.3

24. Transketalization Mechanism

25. Trans-acet(ket)alization

26. Stripping Demonstration
Polymer Filled Vias
Imprinted
Stripping Demo
Control
ADA
Acid
Treated
Cleaned Vias
Control
Control
Acid
Treated
7:1 Aspect ratio

27. Resolution and Mechanical Integrity
15% TEDA
10% ADA
Palmieri, F. et al. ACS Nano 2007, 1(4),

28. Conclusions Acetal Cross-Linked Acrylate
Compatible with SFIL Formulation
Decross-links
Strips from Wafer
Cleans from Template
Sufficient Mechanical Strength
Imprintable

29. Acknowledgements Prof. C. Grant Willson Dr. Frank Palmieri
Dr. Bill Heath