1. Lithography-Part 1� �Dr. Marc Madou, �Winter 2011 UCI �Class 2�
2. Lithography definitions
Resist tone
Introduction to the lithography process
Surface Preparation
Photoresist Application
Soft Bake
Align & Expose
Develop
Hard Bake
Inspection
Etch Layer or Add Layer
Resist Strip
Final Inspection
Clean- Room, Wafer Cleaning
Content
3. Photolithography -- Definitions Photolithography is used to produce 2 1/2-D images using light sensitive photoresist and controlled exposure to light.
Microlithography is the technique used to print ultra-miniature patterns -- used primarily in the semiconductor industry.
4. Photolithography is at the Center of the Wafer Fabrication Process
5. Resist Tone Negative: Prints a pattern that is opposite of the pattern that is on the mask.
Positive: Prints a pattern that is the same as the pattern on the mask.
6. Negative Lithography
7. Positive Lithography
8. Resist Tone
9. Photoresist profiles
Overcut (LIFT-OFF)
Vertical
Undercut Resist Tone
10. Photoresist profiles
Overcut (LIFT-OFF)
Vertical
Undercut Resist Tone
11. This following slides addresses Engineering Technology Content Standard 3 and 4 on Manufacturing and Materials.This following slides addresses Engineering Technology Content Standard 3 and 4 on Manufacturing and Materials.
12. 1. Surface Preparation �(HMDS vapor prime) Dehydration bake in enclosed chamber with exhaust
Clean and dry wafer surface (hydrophobic)
Hexamethyldisilazane (HMDS)
Temp ~ 200 - 250°C
Time ~ 60 sec.
13. 1. Surface Preparation �(HMDS vapor prime)
14. 1. Surface Preparation �(HMDS vapor prime)
15. 2. Photoresist Application Wafer held onto vacuum chuck
Dispense ~5ml of photoresist
Slow spin ~ 500 rpm
Ramp up to ~ 3000 - 5000 rpm
Quality measures:
time
speed
thickness
uniformity
particles & defects
16. Resist spinning thickness T depends on:
Spin speed
Solution concentration
Molecular weight (measured by intrinsic viscosity)
In the equation for T, K is a calibration constant, C the polymer concentration in grams per 100 ml solution, h the intrinsic viscosity, and w the number of rotations per minute (rpm)
Once the various exponential factors (a,b and g) have been determined the equation can be used to predict the thickness of the film that can be spun for various molecular weights and solution concentrations of a given polymer and solvent system
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17. 2. Photoresist Application
18. 2. Photoresist Application
19. 3. Soft Bake Partial evaporation of photo-resist solvents
Improves adhesion
Improves uniformity
Improves etch resistance
Improves linewidth control
Optimizes light absorbance characteristics of photoresist
20. 4. Alignment and Exposure Transfers the mask image to the resist-coated wafer
Activates photo-sensitive components of photoresist
Quality measures:
linewidth resolution
overlay accuracy
particles & defects
21. Alignment errors (many different types)
Mask aligner equipment
Double sided alignment especially important in micromachines 4. Alignment and Exposure
22. 4. Alignment and Exposure
23. 4. Alignment and Exposure
24. Contact printing
Proximity printing
Self-aligned (see next)
Projection printing : R = 2bmin = 0.6??/NA 4. Alignment and Exposure
25. 4. Alignment and Exposure
26. � The defocus tolerance (DOF)
Much bigger issue in miniaturization science than in ICs
27. 4. Alignment and Exposure
28. 5. Develop Soluble areas of photoresist are dissolved by developer chemical
Visible patterns appear on wafer
windows
islands
Quality measures:
line resolution
uniformity
particles & defects
30. 7. Development Inspection Optical or SEM metrology
Quality issues:
particles
defects
critical dimensions
linewidth resolution
overlay accuracy
31. 8. Plasma Etch-Or Add Layer Selective removal of upper layer of wafer through windows in photoresist: subtractive
Two basic methods:
wet acid etch
dry plasma etch
Quality measures:
defects and particles
step height
selectivity
critical dimensions
Adding materials (additive)
Two main techniques:
Sputtering
evaporation
32. 8. Plasma Etch-Or Add Layer
33. 9. Photoresist Removal (strip) No need for photoresist following etch process
Two common methods:
wet acid strip
dry plasma strip
Followed by wet clean to remove remaining resist and strip byproducts
34. 10. Final Inspection Photoresist has been completely removed
Pattern on wafer matches mask pattern (positive resist)
Quality issues:
defects
particles
step height
critical dimensions
35. Clean-rooms, Wafer Cleaning� Yellow light and low particle size/density curves
Cleaning steps
RCA1-peroxides and NH3-removes organics
RCA2-peroxide and HCl-removes metals
Dry vs. wet cleaning
Supercritical cleaning-no liquid phase
36. Clean-rooms, Wafer Cleaning�
37. Clean-rooms, Wafer Cleaning�
38. Clean-rooms, Wafer Cleaning�
39. Clean-rooms, Wafer cleaning Yield is the reason for the clean-rooms-the smaller the features the more important the cleanroom
In the future people will work outside the cleanroom and only wafers will be inside the clean environment
At universities, modularity (many different materials and processes) is more important than yield
40. CD and Tg CD (e.g. 90 nm) i.e. critical dimension (the smallest feature made in a certain process)
Glass transition temperature, above Tg the resist picks up dirt quite readily and the profile might get degraded
41. Making a Mask Software Mask
42. Moore’s ‘Law’ Observation and self fulfilling prophecy --not a physical law
Is it running out of steam?
