|
Book Chapters
- Yan C. Lee Y, Jang H. and Ahn J.-H., "Graphene
films for unusual format electronics", a chapter in, " Graphene
systhesis and applications ", edited by Choi W and Lee J, CRC
press, (2011)
- Ahn J.-H., Kim, D. -H., and Rogers J.
A., "Micro and Nanostructured Semiconductor Materials for
Flexible and Stretchable Electronics", a chapter in, "
Comprehensive Semiconductor Science & Technology ", edited by
Bhattacharya Pallab, Elsevier, (2011)
- Ahn J.-H.,
Baca A. J., and Rogers J. A.,¡° Inorganic Nanomaterials for High
Performance Flexible Electronics¡±,
a chapter in,
"Application
of Physical Methods to Inorganic and Bioinorganic Chemistry",
edited by
Robert
A Scott and Charles M Lukehart, John Wiley, (2009).
- Ahn J.-H.,
Meitl M. A., Baca A. J., Khang D. Y., Kim H. S., and Rogers J. A.,¡°
Transfer Printing Techniques and Inorganic Single-Crystalline
Materials for Flexible and Stretchable Electronics¡±, a chapter
in, "Solution Processing of Inorganic Materials",
edited by David Mitzi, John Wiley & Sons, (2009).
- Sun Y., Ahn
J.-H. Rogers J.A., ¡°Printable semiconductors for flexible
electronics¡±, McGraw-Hill Yearbook of Science & Technology, 192-197
(2007).
Journal Papers
| 2012 |
22
|
K. T. Eun, et al., ¡°Mechanical
flexibility of zinc oxide thin-film transistors prepared by
transfer printing method¡±, Modern Physics Letters B,
26, 1250077(10 pages), (2012). |
21
|
A. K. Patra, et al., "Dynamic
spin injection into chemical vapor deposited graphene",
Appl. Phys. Lett., 101, 162407, (2012). |
20
|
Bhupendra K. Sharma, et al., "Load-Controlled Roll Transfer of Oxide
Transistor for Stretchable Electronics", Adv. Func. Mat.,
Published Online. |
| 19 |
Sanghoon Bae, et al., ¡°Graphene-based
transparent strain sensor¡±,
Carbon, in press. |
18
|
Jing Niu, et al., "Shifting
of surface plasmon resonance due to electromagnetic coupling
between graphene and Au nanoparticles", Optics Express,
20, 18, 19690-19696, (2012). |
17
|
Beom Joon Kim, et al., "Coplanar-Gate Transparent Graphene Transistors
and Inverters on Plastic", ACS Nano, Article
ASAP. |
16
|
Junggou Kwon, et al., "A High Performance PZT Ribbon-Based Nanogenerator
using Graphene Transparent Electrodes", Energy & Environmental
Science, 5, 8970-8975, (2012). |
15
|
Young In Jhon, et al., "The
mechanical responses of tilted and non-tilted grain boundaries
in graphene", Carbon, 50, 3708-3716, (2012). |
14
|
Seoung-Ki Lee, et al., "All Graphene based Thin Film Transistors
on Flexible Plastic Substrates",
Nano Lett., 12(7), 3472–3476, (2012). |
13
|
Chao Yan, et al., "Graphene-Based Flexible
and Stretchable Thin Film Transistors", Nanoscale,
4, 4870–4882, (2012). |
12
|
Yong-Jin Kim, et al., "Low-temperature
growth and direct transfer of graphene-graphitic carbon films on
flexible plastic substrates", Nanotechnology,
23, 344016(6pp), (2012). |
11
|
Byung-Jae Kim, et al., "Numerical Design of SiO2 Bridges in Stretchable Thin Film Transistors" Japanese
Journal of Applied Physics,
51,
01AG10-01AG10-3, (2012). |
10
|
Dolly Shin, et al., "Synthesis and applications of graphene electrodes" Carbon Letters, 13, 1, 1-16, (2012) (invited review article). |
9
|
Ji Tae Kim, et al., "Three-Dimensional
Writing of Highly Stretchable Organic Nanowires", ACS Macro Lett.,
1(3), 375–379, (2012). |
8
|
Sukang Bae, et al., "Towards industrial applications of graphene electrodes" Physica Scripta T146, 014024, (2012). |
7
|
Jing Niu, et al., "Graphene induced tunability of the surface plasmon resonance" Appl. Phys.
Lett., 100, 061116, (2012). |
6
|
Guang-Xin Ni, et al., "Quasi-Periodic
Nanoripples in Graphene Grown by Chemical Vapor Deposition and
Its Impact on Charge Transport", ACS Nano,
6(2),
1158–1164, (2012). |
5
|
Jong-Hyun Ahn, et al., "Stretchable electronics: materials,
architectures and integrations " J. of Physics D: Appl. Physics, 45, 103001,
(2012), (invited review article). |
4
|
Chao Yan, et al., "Mechanical
and Environmental Stability of Polymer Thin-Film-Coated Graphene",
ACS Nano, 6(3), 2096–2103, (2012). |
3
|
T.H. Han, et al., "Extremely Efficient Flexible
Organic Light-emitting Diodes with Modified Graphene Anode" Nature Photonics, 6, 105–110, (2012). |
2
|
W.S. Lim, et al., "Atomic layer etching of graphene for
full graphene device fabrication" Carbon,
50, 429-435, (2012). |
1
|
Kun Seok Lee, et al., "Flexible
and Platinum-Free Dye-Sensitized Solar Cells with
Conducting-Polymer-Coated Graphene Counter Electrodes",
Chemsuschem, 5, 379-382, (2012). |
| |
|
| 2011 |
9
|
Junmo kang, et al., "High-Performance Graphene-Based Transparent Flexible Heaters",
Nano Lett., 11, 5154–5158, (2011). |
8
|
Seoung-Ki Lee, et al., "Stretchable Graphene Transistors
with Printed Dielectrics and Gate Electrodes", Nano Lett.,
11, 4642–4646, (2011). |
7
|
D.K. Lee, et al., "A Numerical Study on the Mechanical Characteristics of Zinc Oxide-Based Transparent Thin Film Transistors", J. Nanosci. Nanotechnol. 11, 5870, (2011). |
6
|
K.S. Kim, et al., "Chemical
Vapor Deposition-Grown Graphene: The Thinnest Solid
Lubricant", ACS Nano, 5, 5107–5114, (2011). |
5
|
T. R. Nayak, et al., "Graphene
for Controlled and Accelerated Osteogenic Differentiation of
Human Mesenchymal Stem Cells", ACS Nano,
5, 4670–4678, (2011). |
4
|
D. K. Lee, et al., "Deformation Characteristics of an Organic Thin Film Transistor", J. Nanosci. Nanotechnol., 11, 239-242, (2011). |
| 3 |
Sun-Jung Byun, et al., "Graphenes Converted from Polymers", J. Phys. Chem. Lett., 2, 493-497, (2011). |
| 2 |
Shou-En Zhu, et al., "Graphene-Based Bimorph Microactuators", Nano Letters, 11, 977-981, (2011). |
1
|
Yi Zheng, et al., "Wafer-scale graphene/ferroelectric hybrid devices for low voltage electronics", Euro Phys. Lett., 93, 17002-p1~17002-p4, (2011). |
| 2010~ |
36
|
K Chun, et
al., "Highly
conductive, printable and stretchable composite films of
carbon nanotubes and silver", Nature Nanotechnology,
5, 853, (2010). |
35
|
Sukjae Jang, et al., "Flexible,
transparent single-walled carbon nanotube transistors with
graphene electrodes", Nanotechnology, 21,
425201, (2010). |
34
|
Beom Joon Kim, et al., "High-Performance
Flexible Graphene Field Effect Transistors with Ion Gel Gate
Dielectrics", Nano Letters, 10, 3464,
(2010). |
33
|
Kyungyea Park, et al., "Stretchable,
Transparent Zinc Oxide Thin Film Transistor",
Advanced Functional Materials, 20, 3577, (2010). |
32
|
S. C. Lee, et al.,
"Numerical Analysis on the Mechanical Properties of Organic
Thin Film Transistor", Modern Physics Letters B,
24, 1471, (2010). |
31
|
Jonghyun Rho, et al., "PbZrxTi1-xO3 Ferroelectric Thin Film
Capacitors for Flexible Nonvolatile Memory Applications", IEEE Electron
Device Letters., 31, 1017, (2010). |
30
|
Sukang Bae, et
al., "Roll-to-roll
production of 30-inch graphene film for ITO replacement",
Nat. Nanotech., 5, 574, (2010) (selected as
cover). |
29
|
Hasan M, et al., "Low
Temperature Aluminum Oxide Gate Dielectric on Plastic Film
for Flexible Device Application", Japanese Journal of
Applied Physics, 49, 05EA01, (2010). |
28
|
Seoung-Ki Lee, et al., "Mechanically
flexible thin film transistors and logic gates on plastic
substrates by use of single-crystal silicon wires from bulk
wafers.", Applied
Physics Letters, 96, 173501, (2010) (selected as
cover). |
27
|
Youngbin Lee, et al., ¡°Wafer
Scale Synthesis and Transfer of graphene films¡±,
Nano Letters, 10, 490-493, (2010). |
26
|
Hasan M, et al., "Hydrogen
Defect Passivation of Silicon Transistor on Plastic for High
Performance Flexible Device Application",
Electrochem. Solid St., 13(3), H80-H82, (2010). |
25
|
Kim H.S, et al., "Self-Assembled
Nanodielectrics and Silicon Nanomembranes for Low Voltage,
Flexible Transistors and Logic Gates on Plastic Substrates",
Applied Physics Letters, 95, 183544, (2009). |
24
|
Lee S.I., et al.,
¡°
Effect of Homopolymer Molecular Weight on Order-Order
Transition in Block Copolymer and Homopolymer Blends¡±,
J. Nanosci. Nanotechnol. 9,
7499, (2009). |
23
|
Kim J.E., et al., "Interfacial
Change on Morphological Transitions in Styrene-Isoprene
Diblock Copolymer",
Euro. Polym. J, 45, 2450, (2009). |
22
|
Kim T.-H., et al.,
¡°Kinetically Controlled, Adhesiveless Transfer
Printing Using Microstructured Stamps¡±,
Applied Physics Letters, 94, 113502, (2009). |
21
|
Kim K.S., et al., "Large-Scale Pattern Growth of
Graphene Films for Stretchable
Transparent Electrodes", Nature, 457, 706, (2009) |
20
|
Park S. I., et al., "Theoretical and
Experimental Studies of Bending of Inorganic Electronic
Materials on Plastic Substrates ", Advanced
Functional Materials, 18, 2673, (2008). |
19
|
Ahn J.-H., et al., "Defect Tolerance in
Transistors that Use Semiconductor Nanomaterials and
Ultrathin Dielectrics", Advanced Functional Materials,
18, 2535, (2008). (selected as
inside cover) |
18
|
Kim D.H., et al., ¡°CMOS integrated Circuits
Incorporating Monolithically Integrated Stretchable Wavy
Interconnects", Applied Physics Letters, 93,
044102, (2008). |
17
|
Baca A.J., et al.,
¡°Semiconductor Wires and Ribbons for High Performance
Flexible Electronics¡±, Angew. Chem. Int. Ed., 47,
5524, (2008). |
16
|
Kim D.H., et al., ¡°Stretchable and Foldable
Silicon Integrated Circuits¡±, Science, 320, 507,
(2008). |
15
|
Kim D.H., et al.,
¡°Complementary
Logic Gates and Ring Oscillators on Plastic Substrates by
Use of Printed Ribbons of Single-Crystalline Silicon¡±, IEEE
Electron Device Letters, 29, 73, (2008). |
14
|
Ahn J.-H., et al.,
¡°Bendable
Integrated Circuits on Plastic Substrates by Use of Printed
Ribbons of Single-Crystalline Silicon¡±, Applied
Physics Letters, 90, 213501, (2007). (selected as cover
article) |
13
|
Ahn J.-H.,
et al.,
¡°Heterogeneous Three
Dimensional Electronics by Use of Printed Semiconductor
Nanomaterials¡±, Science, 314,
1754, (2006). |
12
|
Lee K.J., et al.,
¡°Bendable GaN High Electron
Mobility Transistoron Plastic Substrates
¡±, Journal of
Applied Physics, 100, 124507, (2006). |
11
|
Ahn J.-H., et al.,
¡°High Speed, Mechanically Flexible Single Crystal
Silicon Thin Film Transistors on Plastic Substrates¡±, IEEE Electron
Device Letters., 27, 460, (2006). |
10
|
Yang W.-Y., et al.,
¡°Supramolecular Barrels from Amphiphilic Rigid-Flexible
Macrocycles¡±, Nature
Materials, 4, 399, (2005). |
9
|
Kim J.-K., et al.,¡°Liquid
Crystalline Assembly from Rigid Wedge-Flexible Coil Diblock
Molecules.¡±, Angew. Chem.
Int. Ed. 44, 328, (2005) |
8
|
Jin, L.-Y., et al.,
¡°Structural Inversion in 3-D Hexagonal Organization of
Coil-Rod-Coil Molecule.¡±, Chem. Commun.
1197, (2005) |
7
|
Jin L.-Y., et al.,
¡°Shape-Persistent Macromolecular Disks from Reactive
Supramolecular Rod-Bundles¡±, J. Am. Chem. Soc.
126, 12208, (2004) |
6
|
Ahn J.-H., et al., ¡°Mechanism
of morphological transition from Lamellar/Perforated layer
to Gyroid phase¡±, Macromolecular
Research, 11, 152, (2003) |
5
|
Ahn J.-H., et al.,
¡°Effect
of Polyisoprene Molecular Weight on Morphological Transition
in Binary Blends of Styrene-Isoprene Diblock Copolymer and
Polyisoprene¡±,
Macromolecules, 35, 10238, (2002). |
4
|
Ahn J.-H.,
et al.,
¡°The effect of block lengths on micellestructure in blends
of styrene-isoprene diblock copolymer and poly(vinyl
methylether)¡±, Polymer,
43, 3345, (2002). |
3
|
Ahn J.-H., et al.,
¡°Micelle Formation in Mixtures of Styrene-Isoprene Diblock
Copolymer and Poly(vinyl methyl ether)¡±,
Macromolecules, 34, 4459, (2001). |
2
|
Ahn J.-H., et al., ¡°Structure of shear-induced
perforatedlayer phase in styrene-isoprene diblock copolymer
melts¡±, Macromolecules,
33, 641, (2000). |
1
|
Ahn J.-H., et al.,¡°Phase
behaviors in blends of poly(vinyl methyl ether) andpoly(styrene-co-butadiene)¡±, Euro.
Polym. J., 33, 1113, (1997). |
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