1. Nanolithography – strategies for a small world
Applications, Raith GmbH

2. Outline Nanolithography … at the moment situation EBL sytems
History – Capabilities – Components
EBL writing strategies
Process technology
Electron–resist–interactions
Process simulation
Proximity effect and Charging
Lift off / etching
EBL application examples

3. Nanolithography … at the moment situation
32nm
103
102
EUV
DUV 10
Minimum Requirement
For Production 1
X- RAYS ?
Electrons by Projection?
10-1
Writing speed cm2/s
10-2
Electrons: Focused Beam (& Shaped beam)
10-3
Mass Production
 Need Mask
10-4
STM - AFM
10-5
Direct
Writing
 Maskless
10-6
0,001
0,01
0,1 1 10
Resolution / m

4. Optical Lithography Resist Substrate Resist Substrate Substrate
Mask to select the
exposed area:
Contact/ Proximity lithography
Projection/ Reduction lithography
UV – λ : nm
Substrate
Resist
positive resist
negative resist
Substrate
Resist
Substrate

5. Why Electrons? Pros Minimum feature size ~ 5nm
Simple to produce / simple to shape
Maskless
Cons
Vacuum required
Serial exposure strategy (so far)

6. Which tasks for EBL? Fabrication of photo masks and imprint templates
Direct write applications
rapid prototyping
low volume production (confined to ultrahigh resolution layer)
Nanodevices in R&D

7. Outline Nanolithography … at the moment situation EBL sytems
History – Capabilities – Components
EBL writing strategies
Process technology
Electron–resist–interactions
Process simulation
Proximity effect and Charging
Lift off / etching
EBL application examples

8. History of EBL systems and electron optics
Some Milestones in the History of Electron Optics
1897 Discovery of the electron by J.J. Thompson
1924 P. De Broglie: particle/wave dualism
1927 Hans Busch: Electron beams can be focused in an inhomogeneous magnetic field.
1931 Max Knoll and Ernst Ruska built the first TEM
1938 Scanning transmission electron microscope (M. von Ardenne)
1939 First commercial TEM by Siemens (Ruska, von Borries) …
1964 First commercial SEM by Cambridge Instruments
1960s First EBL Systems and EBL Resists

9. Serial Exposure: EBL Systems
R&D
R&D systems
attachments
mask writer
throughput,
complexity,
costs
flexibility, versatility

10. Capabilities of EBL Systems
Pattern size?
Sample size?
Lithography resolution?
New technologies?
University environment?
Process control?
Automation?
Wafer exposure?
R&D
mask writer
R&D systems
attachments
fuzzy classification -
“systems in between”
stitching
stitching
single field
mask making
chip exposure
small layouts
wafers & masks
wafers & masks
direct write
(mix & match)
small samples
small samples
mix & match
mix & match
full automation
automatable jobs
high resolution
high resolution
high resolution
imaging
imaging
metrology
multi user
multi user
nano engineering
nano engineering

11. Most simple EBL system: Upgraded SEM
EBL related components
Courtesy:SPIE Handbook of Microlithography

12. EBL systems
Courtesy:SPIE Handbook of Microlithography

13. Electron guns thermal emission, tungsten or LaB6 b) field emission,
Source: (Gersley,
J. Appl. Phys. 65 (3),
914 (1989))
thermal emission,
tungsten or LaB6
b) field emission,
cold or thermal
advantages: resolution, beam current
stability, filament lifetime

14. Electron beam resolution
 DeBroglie wavelength at 1 kV: nm
current resolution limit of electron optics is in the
range 1 – 2 nm
Courtesy: SPIE Handbook of Microlithography

15. Resolution limit in EBL
4.69 nm
Hier an der Flipchart einen prinzipiellen Aufbau STEM und SEM/EBL zeichnen (Pole Piece)
~ 5nm lines exposed in HSQ resist, J. Yang, MIT, and J. Klingfus, Raith, unpublished

16. EBL systems
Courtesy:SPIE Handbook of Microlithography

17. Beam deflection electro-static electro-magnetic F = q · (E + v × B)
fast deflection
large deflection

18. EBL systems beam blanker deflection
Courtesy:SPIE Handbook of Microlithography

19. How is the exposure executed?
Serial exposure strategy
Need for accurate
stage movement:
Stitching

20. How is the exposure executed?
Serial exposure strategy
Need for accurate
stage movement:
Stitching

21. Laserinterferometer controlled stage
Compact design
No chamber
modification required
Variable working
distance
Integral closed loop position control
Position control
independant of
all SEM settings
Excellent stability
stitching capability

22. Outline Nanolithography … at the moment situation EBL sytems
History – Capabilities – Components
EBL writing strategies
Process technology
Electron–resist–interactions
Process simulation
Proximity effect and Charging
Lift off / etching
EBL application examples

23. EBL techniques Vector scan / Raster scan
Vector: only necessary parts are scanned
Raster: complete exposure area is scanned
Beam is blanked when necessary
Gaussian beam / shaped beam / cell projection
Gaussian: focused beam (point-by-point)
Shaped: projection of variable shapes (2 apertures combined – area exposure)
Cell: Projection of a dedicated shape (area exposure)
Exposure
Stage stationary during exposure (stitching)
Write-on-the-fly: moving stage during exposure

24. Writing strategies: Gaussian beam
Vector Scan
High resolution electron optics optimised for smallest spot diameters
Gaussian Beam
Raster Scan
Complex electron optics
with high speed deflector
for 200 MHz – exposure while moving the stage

25. Writing strategies: Write-on-Fly
stage motion
beam motion

26. Writing strategies: Shaped beam
Vector Scan
Complex electron optics
with shaping apertures
require high current densities
Different writing strategies
applied for different tasks
„There‘s no good or bad“

27. Outline Nanolithography … at the moment situation EBL sytems
History – Capabilities – Components
EBL writing strategies
Process technology
Electron–resist–interactions
Process simulation
Proximity effect and Charging
Lift off / etching
EBL application examples

28. Process technology pattern transfer spin coating
substrate
resist
spin coating
exposure
developing
wafer
coating or stripping step
after x process steps
remover
lift-off
etching
metal
pattern
transfer

29. Process technology pattern transfer spin coating exposure gas EBID
remover
Lift-Off
etching
metal
pattern
transfer
substrate
resist
spin coating
exposure
developing
substrate
EBID
gas
injection
metal
etching

30. Electron scattering Forward scattering events resist
very often
scattering under small angles
small-angle hence inelastic
generation of Secondary Electrons with a few eV kinetic Energy
incident
beam
BSE
SEII
SEI
resist
Backward scattering events
occasionally
scattering under large angles
large angle hence mainly elastic
high kinetic energy, range of the primary electrons
substrate
Organic resist: exposure by secondary electrons (SEI and SEII)

31. Resist – what happens? Chemical bonds creation or break
Organic resist: 6 – 10eV (secondary electrons)
Inorganic resist: > 50eV
high energy electrons: beam itself  high resolution
Positive resist
Chemical bond break
(e.g.: PMMA, PMMA/CoMAA, PMGI, ZEP520)
Negative resist
Chemical bond creation
(e.g.: ma-N 2400, PMMA, calixarene)

32. Fragmentation of PMMA m o n C O C C C C C C C C O C O O C O C C O H H

33. Resist – what happens? chemically amplified negative resist
chemical bond break due to acid radical creation
thermally activated cross-linking (PEB – Post Exposure Bake) due to molecular weight
(e.g.: SU8, KRS-XE, UVNxx, SAL601, SNR200, AZ-PN114)
inorganic materials
phase or cristallinity change, chemical bond break or auto-developing
e.g.: HSQ, WO3, AlF3, SiO2)

34. Chemically amplified resists
SU8 resist
substrate
spin coating
exposure
developing
prebake
chemically amplified resist:
postexposure bake
chemically amplified resist
most applications:
used with postexposure bake for high contrast
postbake

35. Some resists Positive resists Negative resists PMMA ZEP UV5
AR-N 7520 or ma-N2403
HSQ
SU8
UVN30
more info at:
| |

36. Getting started As an EBL beginner …
avoid chemically amplified resist because they need a carefully controlled post exposure bake
avoid very sensitive resists
make first tests with positive resist, because several tests can be made on one sample
 use for example PMMA 950K from Raith’s EBL starter kit

37. Monte Carlo simulation
1.4 µm PMMA, E = 30 keV, exposed line: 300 nm , Dose 520 µC/cm2

38. Developing 45 s 40 s 55 s 60 s 35 s 50 s 25 s 5 s 10 s 15 s 20 s 30 s
1.4 µm PMMA, E = 30 keV, exposed line: 300 nm , Dose 520 µC/cm2
with MIBK:IPA = 1:3
45 s
40 s
55 s
60 s
35 s
50 s
25 s
5 s
10 s
15 s
20 s
30 s

39. Clearing dose Cross-Section after developing for 30 s 460 µC/cm2

40. Process Window Dose Process window (decreases with resist thickness)
Developing (Time, Temperature)

41. Clearing dose: Rule of thumb
incident
beam
SEII
BSE
SEI
1. Minor influence of resist thickness on dose
2. Dose depends on beam energy

42. Proximity effect incident beam BSE SEII SEI Proximity effect corrected
uncorrected
high dose
low dose
1µm
Proximity effect
depends on beam energy, substrate, pattern
various strategies for proximity correction, e.g. dose variation

43. Displacement and distortion of exposed structures!
Charging e- e-
insulator
resist
Displacement and distortion of exposed structures!

44. Use of conducting layers
1. resist/metal/substrate
2. metal/ resist/substrate
insulator
resist
metal e-
insulator
metal
resist
3. conductive polymer
/resist/substrate:
disadvantage:
sputtering or evaporation system required for metal deposition
insulator
resist
conductive polymer
additional spin coating step, but no metal etching required

45. Exposure Results
Optical Images after exposure

46. Process technology pattern transfer spin coating
substrate
resist
spin coating
exposure
developing
wafer
coating or stripping step
after x process steps
remover
lift-off
etching
metal
pattern
transfer

47. Lift-Off Tips & Tricks obtain an undercut resist profile by
use a double layer resist
use low beam energy
over-developing
over-exposure
use an aspect ratio of resist:metal as large as possible
if possible use evaporation, not sputtering

48. Etching Tips & Tricks Resist Wafer Wafer obtain cross-sections without
undercut or overcut by
use high beam energy
avoide over-exposure and over-developing
apply postbake to improve resist stability during etching
for organic resists avoid etching processes with oxygen
Wafer
Resist
Wafer

49. Process technology pattern transfer spin coating Raith support
substrate
resist
spin coating
exposure
developing
Raith support
special
knowledge, e.g. EBL resist database
remover
lift-off
etching
metal
pattern
transfer
general
knowledge
& support

50. Raith application lab: Typical instrumentation
substrate
spin coating
exposure
developing
Cleaning
Instrumentation
Film thickness
measurement
Cleaning
Spin coating
Exposure
Developing
Inspection
wet bench
(eye-) shower for
accidents with acids
storage for chemicals
stove / hotplate
refrigerator
spin coater
Film Thickness Probe
Raith EBL system
optical microscope
sputtering machine
process step
Spin coating
Film thickness
measurement
Exposure
Developing
Inspection

51. Outline Nanolithography … at the moment situation EBL sytems
History – Capabilities – Components
EBL writing strategies
Process technology
Electron–resist–interactions
Process simulation
Proximity effect and Charging
Lift off / etching
EBL application examples

52. Customer Applications: Nanodevices
Nanoelectronics
Basic Research
Optical Properties
CNT
Single electron device,
Université de Louvain
SiO2 Nanowires, Uni Alberta
Meta material,
Uni Karlsruhe
Photonics
Nanomechanics
EBL
Photonic Crystal,
Uni Eindhoven
Single Electron Transport, LMU Munich

53. Mix & Match exposure (Overlay)
t-gate HEMT, Courtesy F. Robin, ETH Zürich

54. Mix & Match with/without accurate stage
A): no registration
after global
alignment:
highly
accurate
stage is
a must!
B): Best overlay required
or inaccurate stage:
Apply local
registration
after global
alignment
Global Wafer Marker
Local Writefield Marker

55. Mix & Match exposure: Example
automatic
mark scan
HEMT Structures
Step: large electrodes with 200 nm gap
Step: Overlay of 80 nm gate line

56. Applications – 3D lithography
Christchurch
New Zealand, 3D pattern in
negative resist (OM and AFM image)
M. Konijn, University of Canterbury, Christchurch, New Zealand

57. Application – high resolution map
Colombo St
50 microns = 1/20 mm
50 nm = 1/20,000 mm
nm-map, R. Blaikie, University of Canterbury, New Zealand

58. Outline Thanx for listening! Nanolithography … at the moment situation
EBL sytems
History – Capabilities – Components
EBL writing strategies
Process technology
Electron–resist–interactions
Process simulation
Proximity effect and Charging
Lift off / etching
EBL application examples
Thanx for listening!