Download JaegerLithographyCh2r3

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts
no text concepts found
Transcript
Solid State Devices
EE 3311
SMU
Chapter 2
Lithography
Revised 9 September 2015
Photolithographic Process
(a)
(b)
(c)
(d)
(e)
(f)
(g)
Substrate covered with silicon
dioxide barrier layer
Positive photoresist applied to
wafer surface
Mask in close proximity to
surface
Substrate following resist
exposure and development
Substrate after etching of oxide
layer
Oxide barrier on surface after
resist removal
View of substrate with silicon
dioxide pattern on the surface
Photolithographic Process
• Each mask step requires many
individual process steps
• Number of masks is a common
measure of overall process
complexity
Photomasks
CAD Layout
• Composite drawing of the masks
for a simple integrated circuit
using a four-mask process
• Drawn with computer layout
system
• Complex state-of-the-art CMOS
processes may use 25 masks or
more
3311 MOSFET Metal Level
List of Test Structures on 3311 Chip
This chip is a metal-gate, thick-oxide, PMOS process with boron diffused junctions
1-3. Wide thin-oxide devices of various L’s.
4-6. Narrow thin-oxide devices of various L’s.
7-9. Narrowest thin-oxide devices of various L’s.
10. Short field device.
11. Longer field device.
12. Longest field device.
13. Super-tiny thin-oxide device. Probably won’t work.
14. Bond pad on field oxide.
15. Larger-area metal on field oxide.
16. Metal-to-diffusion thin-oxide capacitor.
17. Diffusion capacitor.
18. Diffusion serpentine with four (Kelvin) contacts for diffusion sheet resistance.
19-20. Vertical and horizontal contact-to-diffusion alignment measurement device.
21. Metal-diffusion contact string. Use to check contact integrity.
22. Thin metal serpentine with four (Kelvin) contacts for metal sheet resistance. This device is probably
too narrow to be etched without breaking the connections.
23. Metal serpentine over diffusion serpentine. Use to check metal continuity and diffusion sheet
resistance.
24. Metal to diffusion alignment measurement device without gate oxide: use to automatically
measurement metal to diffusion alignment.
25. Metal to diffusion alignment measurement device with gate oxide: use to automatically measurement
metal to diffusion alignment, or gate oxide to diffusion alignment.
List of Test Structures on 3311 Chip, cont’d
26-30. Diffusion-to-diffusion spacing, going from widest on left to narrowest on right. Use to check if
diffusions are touching, or to measure punch-through.
31. Metal-to-diffusion capacitor. Metal to the left; diffusion to the right.
32. Enhancement-load ratioed inverter: Bond pads, going clockwise and starting at 12 o’clock: VDD;
output; VSS; input; VGG.
33. Sample-and-hold gate. Bond pads, going clockwise and starting at 2 o’clock: Sense transistor source
or drain; sense transistor drain or source; sample gate; input.
34. Alignment cross: thin oxide to diffusion.
35. Alignment cross: contact to thin oxide.
36. Alignment cross; metal to contact.
37. A lateral grounded-base PNP transistor. The emitter is at the top, and the collector is at the bottom.
The n-type substrate is the base.
38. A sixteen-stage shift-register. Bond pads, going clockwise and starting at 12 o’clock: VDD, VSS
Phase 2 Clock, Output, VGG, VDD, VSS, Input, Phase 1 Clock.
39. A ring oscillator with fifteen inverters and a buffer. Bond pads, going clockwise and starting at 1
o’clock: VDD; output from buffer; VSS; VGG.
40. Ring oscillator with thirty-five inverters plus output buffer connected to, but not in the ring. Bond
pads, going clockwise and starting at 1 o’clock: VDD; output from buffer; VSS; gate to provide input for
25 inverter ring; gate to provide input for 15 inverter ring; gate to provide input for 35 inverter ring; VGG.
The intermediate taps for inputs likely will not work since the input will be contending with the fixed
output of the previous stage.
Circuits 38, 39, and 40 may not work due to design-rule violations in the metal leads which results in many
of the circuit connections being not connected.
Note: many years ago we made some changes to the mask set so that circuits 38, 39 and 40 would have a
better chance of working. However, we just noticed that we are still using the old mask set for EE 3311.
Photo Masks
10X Reticle
• Example of 10X reticle for the metal
mask - this particular mask is ten
times final size (10 mm minimum
feature size - huge!)
• Used in step-and-repeat operation
• One mask for each lithography level
in process
Photomasks
Final Mask
• Mask after reduction and
“step-and-repeat”
operation
• Final size emulsion mask
with 400 copies of the
metal level for the
integrated circuit
ITRS Lithography Projections
Table 2.5 -- ITRS Lithography Projections
Year
2001
2003
2005
2008
2011
2014
Dense Line Half-Pitch (nm)
150
120
100
70
50
35
Worst Case Alignment Tolerance
52
42
35
25
20
15
100
80
65
45
30
20
9
8
6
4
3
2
Equivalent Oxide Thickness (nm)
1.5 - 1.9
1.5 - 1.9
1.0 - 1.5
0.8 - 1.2
0.6 - 0.8
0.5 - 0.6
Lithography Technology Options
248 nm DUV
248 nm + PSM
193 nm + PSM
157 nm +PSM
EUV
EUV
193 nm DUV
157 nm
E-beam projection
E-beam projection
E-beam projection
E-beam projection
E-beam direct write
E-beam direct write
E-beam direct write
Proximity x-ray
EUV
Ion Projection
Ion Projection
Ion Projection
Ion Projection
Mean + 3 s (nm)
Minimum Feature Size F (nm)
Microprocessor Gate Width
Critical Dimension Control (nm)
Mean + 3 s - Post Etching
Proximity x-ray
DUV - deep ultraviolet;
EUV - extreme ultraviolet; PSM - phase shift mask;
Innovation
Contamination
• Human hair (~100
microns) at the same
scale as the integrated
circuit with 10 mm
feature size
• Today’s feature size
100 nm - 100 times
smaller!
Clean Room Specifications
Table 2.1
Clean Room Ratings by Class of Filtration
Class
Number of 0.5-mm
3
3
particles per ft (m )
10,000
1,000
100
10
1
10000 (350,000)
1000 (35,000)
100
(3,500)
10
(350)
1
(35)*
Number of 5-mm
3
3
particles per ft (m )
65 (23,000)
6.5 (2,300)
0.65 (230)
0.065 (23)
0.0065 (2.3)
*It is very difficult to measure particulate counts below 10/ft3
Common Wafer
Surface Orientations
Wafer Cleaning
• Wafers must be cleaned of chemical and particulate contamination
before photo processing
• Example of “RCA” cleaning procedure in table below
Photoresist Deposition
Automated Production Systems
•
Rite Track 88e wafer processing system (Courtesy of Rite Track Services, Inc.
Mask Alignment
• Each mask must be
carefully aligned to the
previous levels
• Some form of
alignment marks are
used
• Automated alignment
and exposure in
production lines
Resists for Lithography
• Resists
– Positive
– Negative
• Exposure Sources
– Light
– Electron beams
– Xray sensitive
Oxide Etching Profiles
(a) Isotropic etching - wet chemistry - mask undercutting
(b) Anisotropic etching - dry etching in plasma or reactive
ion etching system
Mask Undercut
Etching Approaches
Dry Plasma Systems
(a) Conceptual drawing
for a parallel plate
plasma etching
system
(b) Asymmetrical
reactive ion etching
(RIE) system
Plasma Etching
Characteristics
• Anisotropic etching
• Minimizes chemical
waste
• Etching
• Cleaning
• Resist removal
“ashing”
1 atm = 760 mm Hg = 760 torr = 1.013 x 10 5 Pa
1 Pa = 1 N/m2 = 0.0075 torr
Mask Fabrication
• Masking processes
–
–
–
–
Direct step on wafer
Contact printing
Proximity printing
Projection printing
Printing Techniques
• Contact printing damages the reticle
and limits the number of times the
reticle can be used
• Proximity printing eliminates
damage
• Projection printing can operate in
reduction mode with direct step-onwafer, eliminating the need for the
reduction step presented earlier
Photoresist and Pattern Transfer
Resist Sensitivity
Typical Photoresist Cycle
Wafer Steppers
Figure 2.13 The true complexity of a wafer stepper is
apparent in this system drawing. (Courtesy of ASM
Lithography, Inc.
• Wafer stepping systems
widely used
• Must be completely isolated
from sources of vibration
• High degree of
environmental control
needed
• Often in their own clean
room
Wafer Steppers
(cont.)
i-line
g-line
Lens System
Figure 2.15
Spectral Content of Xe-Hg lamp (Courtesy of SVG)
Minimum Feature Size
and Depth of Field
Minimum Feature Size F = 0.5
Depth of Field DF = 0.6
l
NA
l
(NA)
2
Numerical Aperture NA = sin q
l = wavelength of exposure source
ITRS Lithography Projections
Table 2.5 -- ITRS Lithography Projections
Year
2001
2003
2005
2008
2011
2014
Dense Line Half-Pitch (nm)
150
120
100
70
50
35
Worst Case Alignment Tolerance
52
42
35
25
20
15
100
80
65
45
30
20
9
8
6
4
3
2
Equivalent Oxide Thickness (nm)
1.5 - 1.9
1.5 - 1.9
1.0 - 1.5
0.8 - 1.2
0.6 - 0.8
0.5 - 0.6
Lithography Technology Options
248 nm DUV
248 nm + PSM
193 nm + PSM
157 nm +PSM
EUV
EUV
193 nm DUV
157 nm
E-beam projection
E-beam projection
E-beam projection
E-beam projection
E-beam direct write
E-beam direct write
E-beam direct write
Proximity x-ray
EUV
Ion Projection
Ion Projection
Ion Projection
Ion Projection
Mean + 3 s (nm)
Minimum Feature Size F (nm)
Microprocessor Gate Width
Critical Dimension Control (nm)
Mean + 3 s - Post Etching
Proximity x-ray
DUV - deep ultraviolet;
EUV - extreme ultraviolet; PSM - phase shift mask;
Innovation
End of Lithography Slides
for EE 3311
Phase Shifting Masks
Pattern transfer of two
closely spaced lines
(a) Conventional mask
technology - lines not
resolved
(b) Lines can be resolved
with phase-shift
technology
Inspection
SEM, TEM, STM
“A picture is worth a
thousand words”
– Optical microscopy
– Scanning electron
microscopy (SEM)
– Transmission electron
microscopy (TEM)
– Scanning tunneling
microscopy (STM)
SEM images of a three-dimensional micro-electro-mechanical system
(MEMS) structure (Courtesy of Sandia National Laboratories).
Inspection TEM
Figure 2.18
Cross-sectional high-resolution TEM images for MOS structures with (a) 27-Å and (b) 24-Å Image. Polysilicon grains are easily noticeable in (a);
the Si/SiO2 and poly-Si/SiO2 interfaces are shown in part (b). On a local atomic scale, thickness variations of 2-3 Å are found which are a direct
result of atomic steps at both interfaces. Copyright 1969 by International Business Machines Corporation; reprinted with permission from Ref. [9].
Layout of a Class Chip
Basic 4-Mask Process
PMOS Metal-Gate Process
1. p-diffusion
2. Thin oxide
3. Contacts
4. Metal
Four Mask Class Process
p-diffusion
Contacts
Thin oxide
Metal
Layout of Class Chip
Metal Gate PMOS Process
G
J
F
H
I
G
G
A
D
B
C
G
E
G
A. Thick oxide capacitor
B. Thin Oxide Capacitor
C. Van der Pauw structure
D. Resistor 1
E. Resistor 2
F. Diode
G. PMOS transistors
H. PMOS logic inverter
I. Lateral pnp transistor
J. Kelvin contact structure
Our Class Process
Diode & Resistor Fabrication
Top view of an integrated pn diode.
Our Class Process
Diode Fabrication (cont.)
(a) First mask exposure (b) Post-exposure and development of photoresist
(c) After SiO2 etch (d) After implantation/diffusion of acceptor dopant.
Our Class Process
Diode Fabrication (cont.)
(e) Exposure of contact opening mask, (f) after resist development and etching of contact
openings, (g) exposure of metal mask, and (h) After etching of aluminum and resist removal.
Layout of Class Chip
Metal Gate PMOS Process
G
J
F
H
I
G
G
A
D
B
C
G
E
G
A. Thick oxide capacitor
B. Thin Oxide Capacitor
C. Van der Pauw structure
D. Resistor 1
E. Resistor 2
F. Diode
G. PMOS transistors
H. PMOS logic inverter
I. Lateral pnp transistor
J. Kelvin contact structure
References
End of
Lithography Section