Title: 1 Department of Materials Science
11 Department of Materials Science
Engineering, Chungnam National University,
Daejeon 305-764 Korea2 Department of Physics,
Andong National University, Andong 760-749, Korea
FABRICATION AND MAGNETIC PROPERTIES OF
ELECTRODEPOSITED Co-NANOWIRE ARRAYS USING
SELF-ASSEMBLED DIBLOCK COPOLYMER TEMPLATES
- Abstract
- In recent, there is a considerable interest in
the fabrication of the magnetic nanowire arrays
due to potential applications in magnetic
recording media, sensors. We produced template
for nanowire arrays using diblock copolymers
composed of polystyrene and polymethylmethacrylate
, P(S-b-MMA), with volume fraction of PS of 0.7.
The 1 solutions of P(S-b-MMA) in toluene were
spin-coated onto gold-coated silicon wafer. The
diblock copolymer films were annealed for 24
hours at 200 oC under an applied electric field
of 1 kV between aluminized Kapton film placed on
the film and bottom gold electrode. The annealed
diblock copolymer films observed by AFM showed
that PMMA cylinders with about 10 nm-diameter are
hexagonally packed by self-assembly in a PS
matrix due to the nature of self-assemble. The
nanoporous PS films, 1.1 Tera holes/in2, were
obtained by removing the PMMA cylinders through
deep ultraviolet exposure and rinsing with acetic
acid. - The Co-nanowire arrays were fabricated by
electrodeposition into the nanoporous PS films in
potentiostatic mode with three electrode
configurations. The electrodeposition solutions
were 50g/l of CoSo4, 80g/l of NaSo4 and 40g/l of
H3BO3 . Hysteresis curves of Co-nanowire arrays
measured by VSM, revealed the perpendicular
magnetic anisotropy to substrate.
We have fabricated the nanotemplate. 11.76
nm diameter 26.47 nm distance 1.1 Tera
holes/in2
- There is a considerable interest in the
fabrication of the magnetic nanowire arrays and
dots due to potential applications in ultra-high
density magnetic recording media and sensors. - Nanofabrication
- Lithography is central to the top-down
fabrication - Self-assembled nanostructures are powerful route
to the bottom-up fabrication (Topical Review
J.I. Martin et. al. JMMM, 256, 449, 2003) - Electrodeposited Co-nanowire arrays using
self-assembled diblock copolymer template - T.P. Russell et. al. Science, 290, 2126, 2000.
- Terabit density, high aspect ratio
- Simple and low cost technique
PS-PMMA
Au
- Magnetic property of the Co-nanowire arrays
- Diblock copolymer
- Consists of two different polymer chains
- Self-assembly
- Various structures with composition after
annealing
Co nanowire
Co film
H
H
H
Shape Anisotropy Crystalline Anisotropy
- Process
- Solution of diblock copolymer
- Polystyrene and Polymethylmethacrylate( PS-PMMA)
with fPS0.71 - 1 solutions of PS-PMMA in toluene
- Spin coating
- Onto gold-coated silicon wafer
- 4000 rpm for 30 sec
- Annealing under electric field
- 1 kV
- 200 oC during 1day
- UV etching
- Deep ultraviolet exposure for 90min.
- Rinsing with acetic acid.
- ED Solution
- 50g/l CoSo4, 80g/l NaSo4 , 40g/l H3BO3
- ED Condition
- - 1.0 V vs SCE
- Fabrication System
- Spin coating System
- Spin coater
- Annealing system under high electric field
- Temperature control
- Heating block
- Vacuum chamber
- High voltage power supply (max. 2kV)
- UV etching system
- UV Lamp and stand
- Chamber
- Electrodeposition system
- Potentio state
- ED Cell
- 3 electrodes configuration
- Magnetic property of the Co-nanowire arrays
- Hc vs magnetization angle
Co-nanowire
Co-film
Co -nanowires are well grown perpendicular to
substrate
ED Cell
- We have fabricated the nanotemplate
- 11.76 nm diameter
- 26.47 nm distance
- 1.1 Tera holes/in2
- We have fabricated the Co-nanowire arrays
- Few hundred nm length
- Perpendicular magnetic anisotropy to substrate
UV Etching
Self-assembled PMMA in PS matrix
Pores in PS matrix