This document discusses electron beam lithography. It begins with an introduction and overview of electron beam lithography, explaining that it uses a beam of electrons to selectively expose and develop a resist film in order to create very small structures. It then provides a schematic of the electron beam lithography process and describes the lithography process steps. The document also covers the advantages of high resolution and no diffraction limit but disadvantages of low throughput and high costs. It includes details on electron beam sources and lenses used.
Repurposing LNG terminals for Hydrogen Ammonia: Feasibility and Cost Saving
E beam lithography
1. Group 2: Trần Phúc Thành.
Cao Văn Phước.
Tống Văn Khoa.
2. Introduction.
Why E-beam lithography?
Schematic of e-beam lithography.
Lithography Process
Advantages and disadvantages.
Summary.
References.
3. - Electron beam lithography (often abbreviated as e-beam
lithography) is the practice of emitting a beam of electrons in
a patterned fashion across a surface covered with a film (called
the resist), ("exposing" the resist) and of selectively removing
either exposed or non-exposed regions of the resist
("developing").
- The purpose, as with photolithography, is to create very small
structures in the resist that can subsequently be transferred to
the substrate material, often by etching. It was developed for
manufacturing integrated circuits, and is also used for
creating nanotechnology architectures.
4.
5.
6. Lower resolution
systems can
use thermionic
sources, which are
usually formed from
LaB6. However,
systems with higher
resolution
requirements need to
use field electron
emission sources,
such as heated
W/ZrO2 for lower
energy spread and
enhanced brightness.
7. A magnetic lens is
a device for the
focusing or
deflection of
moving charged
particles, such
as electrons or ions
, by use of the
magnetic Lorentz
force. Its strength
can often be varied
by usage
of electromagnets.
8. - Sometime we aslo
use electrostatic lens
however, electrostatic
lenses have more
aberrations and so are
not used for fine
focusing.
-Systems of
electrostatic lenses can
be designed in the
same way as optical
lenses.
-Electrostatic lenses in
an electron diffraction
experiment.
9. Clean sample
◦ Remove
oils, organics, etc
(Acetone, IPA, ultraso
nic)
Spin coating of
photoresist on
surface of film
(positive or negative
resist) substrate
Deposited film
Photoresist
10. E-beam lithography
and develop
Etching
(multi-step
processes)
Evaporate metal
contacts
substrate
film
substrate
Deposited film
substrate
film
substrate
film
11. Direct writing with narrow beam
Electron projection lithography using a mask
:EPL
12. oIssues:
oThroughput of direct writing is very low : research
tool or low pattern density manufacturing
oProjection stepper (EPL) is in development stage
only (primarily by Nikon).
oMask making is the biggest challenge for the
projection method
oBack-scattering and second electron result in
proximity effect –reduce resolution with dense
patterns there is also the proximity effect
oOperates in high vacuum (10-6 –10-10 torr) –slow
and expensive
13. Raster Scan
The e-beam is swept across
the entire surface, pixel by
pixel
Beam is turned on and off
Beam is scanned across the
entire surface
14. Vector Scan
◦ The e-beam “jumps” from
one patterned area to the
next
◦ Adjustments to the beam
can also be made relatively
easily
◦ It takes longer for the
beam to settle, making it
more difficult to
◦ maintain accurate placing
for the beam
16. o Diffraction is not a limitation on resolution ( < 1 Å for
10-50 keV electrons)
o Resolution depends on electron scattering and beam
optics the size of the beam, can reach ~ 5 nm
17. 17
In EBL the resolution is not
limited by diffraction
In EBL backscattering
causes the electron beam
to broaden and expose a
large volume of resist then
expected.
The proximity effect places
a limit on the minimum
spacing between pattern
feature.
18. • The pattern is written directly onto the
electron-sensitive resist (no mask is used)
• More precise than photolithography or X-
Ray lithography
• Used to make high-resolution masks for
photolithography and X-Ray lithography
• Beats the diffraction limit of light,
minimum feature size around 5 nm
19. Very slow. Takes over 10 hours to scan
across the entire surface of a wafer
• Very costly. One e-beam system costs
upwards of 5 to 10 MILLION dollars
• Potential problems with electron
scattering:
–Electron energy: 100eV -> very slow,
inefficient, damage the substrate
–Electron energy: 10eV -> lower
penetration depth and lower resolution
20. S.M. Sze, Semiconductor Devices, Physics and
Technology, Willey, 2002.
C.Y. Chang and S.M. Sze, Eds., ULSI
Technology, McGraw-Hill, 1996.
S.M. Sze, Ed., VLSI Technology, McGraw-Hill,
1988.
Nguyễn Đức Chiến, Nguyễn Văn Hiếu, Công
nghệ chế tạo mạch vi điện tử, NXB Bách khoa,
2007.