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University of Science, Vietnam National University (VNUHCM) Institute of Atomic and Molecular Sciences, Academia Sinica (Taiwan)
Center for Condensed Matter Sciences, National Taiwan University
The 2nd
International Workshop
on Energy Materials and
Nanotechnology
13 December 2016
F102, University of Science
Vietnam National University (VNUHCM)
HoChiMinh, Vietnam
2016
Following the 1st international Workshop on Materials Physics in Ho Chi Minh city in
2016, co-organized by University of Science (VNUHCM - Vietnam) and Institute of
Atomic and Molecular Sciences, Academia Sinica (Taiwan), the 2nd
international
Workshop on Energy Materials and Nanotechnology will be held in Ho Chi Minh city in
13th
December 2016.
The workshop also provides an opportunity for respected Taiwanese scientists and
Vietnamese colleagues in materials research society to share their findings, and exchange
cutting edge ideas and applications to establish a fruitful research with each other.
Committee
Prof. Chau Van Tao (Chairman) University of Science, Vietnam National
Univerity, HoChiMinh City (VNUHCM)
Assoc. Prof. Le Van Hieu Faculty of Materials Science, University of
Science, VNUHCM
Assoc. Prof. Nguyen Van Hieu Office of International Relations and Projects
Management, VNUHCM
Dr. Tran Van Man Office of Science and technology, VNUHCM
Prof. Jer-Lai Kuo Institute of Atomic and Molecular Sciences,
Academia Sinica, Taiwan
Secretariat board
Assoc. Prof. Phan Bach Thang Faculty of Materials Science, University of
Science, VNUHCM
Dr. Tran Duy Tap Faculty of Physics and Physics Engineering,
University of Science, VNUHCM
Scientific program
Time
8:00 – 8:30 Registration
8:30 – 8:40 Opening remarks 8:30 – 8:35 Professor Chau Van Tao – University of Science, VNUHCM
8:35 – 8:40 Prof. Kuei-Hsien Chen – National Taiwan University, Taiwan
Morning session
Session 1 Chairman: Dr. Tran Van Man
8:40 – 9:00
Challenges in CO2
conversion to selective
hydrocarbons: Using
graphene oxides and related
2D hybrids as examples
Prof. Li-
Chyong Chen
Center for Condensed
Matter Sciences
(CCMS), National
Taiwan University,
Taiwan
9:00 – 9:20
Electrochemical behavior of
metal oxide/nano carbon
composite as electrode
material for hybrid capacitor
Dr. Tran Van
Man
Faculty of Chemistry,
University of Science
9:20 – 9:40
Thermoelectric Performance
of Mg2(Si;Sn)
Prof. Kuei-
Hsien Chen
IAMS, Academia
Sinica & CCMS,
National Taiwan
University, Taiwan
9:40 – 10:00
Nicotinic acid as a new co-
adsorbent in dye-sensitized
solar cells
Dr. Nguyen
Tuyet Phuong
Faculty of Chemistry,
University of Science
10:00 – 10:20 Coffee Break
Session 2 Chairman: Prof. Kuei-Hsien Chen
10:20 – 10:40
Earth Abundant and Non-
toxic FeS2 Nanocrystals for
Photovoltaic and Catalytic
Applications
Prof. Chia-
Chun Chen
Department of
Chemistry, National
Taiwan Normal
University
10:40 – 11:00
Modulation of bandgap in
bilayer armchair graphene
ribbons by tuning vertical
and transverse electric fields
Dr. Vu Thanh
Tra
Faculty of Physics,
Can Tho University
10:00 – 11:20
Synthesis and Applications
of Organo Phosphorus
Flame Retardants
Dr. Hoang Thi
Dong Quy
Faculty of Materials
Science, University of
Science
11:20 – 11:30
Photography at University entrance gate
11:30 – 13:30 Lunch
Afternoon session
Session 3 Chairman: Dr. Vu Thanh Tra
13:30 – 13:50
Computational Material
Design of Two Dimensional
Materials and Their Energy
Applications
Prof. Jer-Lai
Kuo
Institute of Atomic and
Molecular Sciences,
Academia Sinica,
Taiwan
13:50 – 14:10
Electrode materials for
lithium-ion and sodium-ion
batteries
Dr. Le My
Loan Phung
Faculty of Chemistry,
University of Science
14:10 – 14:30
Fabrication of Polystyrene
Nanocomposite Based on
Reduced Graphene Oxide
By In Situ Micro-emulsion
Polymerization
Dr. Ha Thuc
Chi Nhan
Faculty of Materials
Science, University of
Science
14:30 – 15:00 Coffee Break
Session 4 Chairman: Prof. Chia-Chun Chen
15:00 – 15:20
Ballistic Thermal
Conduction and
Thermoelectrics
Dr. Chih-Wei
Chang
Center for Condensed
Matter Sciences,
National Taiwan
University, Taiwan
15:20 – 15:40
Influences of defects on
thermoelectric properties of
Indium and Gallium dually-
doped ZnO thin films
Assoc. Prof.
Phan Bach
Thang
Faculty of Materials
Science, University of
Science
15:40 – 16:00
High performance
supercapacitor based on
buckypaper/polyaniline/V2O
5 composite
Dr. Do Huu
Quyet
Saigon Hightech Park,
HoChiMinh city
16:00 – 16:20
Microstructures of graft-
type polymer electrolyte
membrane for fuel cell
application
Dr. Tran Duy
Tap
Faculty of Physics and
Physics Engineering,
University of Science
16:20 – 16:25
Closing remarks
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
1
Challenges in CO2 conversion to selective hydrocarbons:
Using graphene oxides and related 2D hybrids as examples
Li-Chyong Chen
Center for Condensed Matter Sciences, National Taiwan University, Taipei, Taiwan
Abstract
Global climate warming and environment pollution have stimulated scientists to develop innovative
high-efficiency and eco-friendly energy technologies, as alternatives to the conventional combustion-
based technologies currently used in many power plants and transportation vehicles. The vast amount of
carbon dioxide (CO2) emission from the conventional coal-burning power plants is a significant
environmental issue. Hence, photocatalytic conversion of CO2 to hydrocarbons makes possible
simultaneously harvesting solar energy for production of fuels or useful chemicals, as well as reducing
CO2 for a greener society, two birds with one stone for the pressing global energy and environmental
problems of our time.
Here, I will present the challenges on CO2 reduction, especially, the materials that can function
towards efficient photocatalytic conversion of CO2 to selective hydrocarbons close to practical
application. Case studies using graphene oxides (GOs) and their related 2D hybrids, as photo-catalysts,
will be presented. Several approaches have been employed to synthesize GOs and reduced GOs (rGOs)
with tunable bandgap and band alignment with respect to the CO2 reduction level. The functionalities of
the GOs/rGOs were investigated by UV-Vis, cyclic voltammetry, and x-ray photoemission spectroscopy.
Under visible light, the photocatalytic conversion of CO2 to methanol of GOs/rGOs is several-fold
higher than that of TiO2 (e.g., commercial P-25). Further, metal and metal sulfides, especially the 2D
materials such as MoS2, as well as optically active polymers, were deposited onto GO as co-catalysts or
sensitizers, to enhance the photocatalysis reaction. Besides methanol, other selective hydrocarbons
including acetaldehyde and ethanol were also detected. Total solar to fuel yield of ~200 times
enhancement over that of P-25 has been achieved. In all these GOs-2D hybrids, the photo-catalytic
performance is always much better than that of constituent component when used alone. Detailed
preparation and characterization of the catalysts will be presented. The role and interplay of the
constituent components will also be discussed.
Keywords: Solar fuel, CO2 reduction, Photocatalytic, Graphene oxide, 2D materials
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
2
Electrochemical behavior of metal oxide/nano carbon composite
as electrode material for hybrid capacitor
Tran Van Man1,2,3
, Le My Loan Phung1,3
1 Laboratory of Applied Physical Chemistry, VNUHCM-University of Science, HoChiMinh City, Vietnam
2 Office of Science and Technology, VNUHCM-University of Science, HoChiMinh City, Vietnam
3Department of Physical Chemistry, VNUHCM-University of Technology, HoChiMinh City, Vietnam
Abstract
Nowadays the electrochemical double layer capacitors (EDLCs) – or supercapacitor have a big
range of application in the start-stop devices and vehicles. In this work, we investigated the
properties and electoral behavior of some metal oxide/ nano carbon based composite using as
cathode materials for hybrid capacitor. We have synthesized the different oxides (MnO2, LMO,
LTO…) and studied the structure, the morphology of materials. The nanocarbon such as carbon
graphite, carbon nanotubes, super P (Timcal) and carbon blacks (Vulcan) were used to mix at
different ratios to make the electrode. The half-cell and full-cell capacitors have been assembled
and then have been studied the charge-discharge property at different scan rates: 1, 10, 20, 50
mV.s-1
by Cyclic Voltammetry (CV) and Galvanostatic charge/discharge. The results showed
that these materials could be used in improving the safety for novel supercapacitors with good
performance and durability.
Keywords: hybrid capacitor, metal oxide, nano carbon, specific capacity.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
3
Thermoelectric Performance of Mg2(Si;Sn)
Kuei-Hsien Chen*
Institute of Atomic and Molecular Sciences, Academia Sinica, Taiwan and
Center for Condensed Matter Sciences, National Taiwan University, Taiwan
Abstract
The search for high performance thermoelectric materials at various temperature range is highly
demanded due to the energy/environmental issues. In this work, Mg2(Si;Sn) samples of different
Si/Sn ratio were prepared by ball milling method followed by hot pressing up to 750 °C. A
series of experiments have been carried out to improve the thermoelectric performance of the
samples via controlling of the Stoichiometry and annealing temperature. Detailed
characterization including Hall measurement, Raman, TEM, XPS, UPS, all in different
temperatures, have been carried out to elucidate the mechanism of the enhanced thermoelectric
performance. Further incorporation of dopants such as Ge and Sb has been implemented to
enhance the thermoelectric performance up to a ZT of 1.37 at 450 °C.
References:
1. “Enhanced thermoelectric performance of GeTe-rich germanium antimony tellurides through the
control of composition and structure,” R. Sankar, D. P. Wong, C.S. Chi, W.L. Chien, J.S. Hwang, F.C.
Chou, L.C. Chen and K.H. Chen, CrystEngComm, 17, 3440, (2015).
2. “Improving the thermoelectric performance of metastable rock-salt GeTe-rich Ge-Sb-Te thin films
through tuning of grain orientation and vacancies,” I.N. Chen, C.W. Chong, L.M. Lyu, D.P. Wong,
W.L. Chien, A. Anbu, Y.F. Chen, L.C. Chen, and K.H. Chen, Physica Status Solidi A 1-8 / DOI
10.1002/pssa.201600274 (2016).
3. “Enhanced thermoelectric performance in percolated bismuth sulfide composite,” D.P. Wong, W.L.
Chien, C.Y. Huang, C.E. Chang, A. Ganguly, L.M. Lyu, J.S. Hwang, L.C. Chen, and K.H. Chen, RSC
Advances 6, 98952 (2016).
Keywords: Mg2Si, Mg2Sn, thermoelectric, high figure-of-merit
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
4
Nicotinic acid as a new co-adsorbent in dye-sensitized solar cells
Phuong Tuyet Nguyen,1*
Vinh Son Nguyen,1 Thu Anh Pham Phan,
1 Tan Nhut Van Le,
1 Duyen
My Le,1 Duy Dang Le,
1 Vy Anh Tran,
1 Tuan Van Huynh,
2 and Torben Lund
3
1Faculty of Chemistry, University of Science, Vietnam National University, Ho Chi Minh City, Vietnam
2Faculty of Physics and Engineering Physics, University of Science, Vietnam National University, Ho Chi Minh
City, Vietnam 3Department of Science, Systems and Models, Roskilde University, DK-4000, Denmark
Abstract
With the aim of introduction a new inexpensive co-adsorbent to improve solar cell performance,
the influence of nicotinic acid (NTA) used as a co-adsorbent in dye-sensitized solar cells (DSCs) was
investigated. The findings showed that low concentrations of NTA (<10 mM) increased the N719
ruthenium dye loading on the TiO2 electrode surface by 10–12%, whereas higher concentrations of NTA
lowered the dye loading. The adsorption of NTA onto the TiO2 electrode surface was studied by
attenuated total reflectance Fourier transform infrared spectroscopy and X-ray photoelectron
spectroscopy, and the blocking effect of NTA toward electron transfer between the electrode and 1,4-
dicyanonaphthalene (redox couple electrolyte probe) was investigated by cyclic voltammetry.
Subsequently, the performance of NTA in functional DSCs was evaluated by current–voltage (J–V) DSC
characterization and compared with that of DSCs fabricated with two well-established co-adsorbents i.e.,
chenodeoxycholic acid (CDA) and octadecylphosphonic acid (OPA). The findings showed that under
optimized co-adsorbent concentration (1 mM NTA, 0.03 mM CDA, 0.015 mM OPA), the efficiency of
the corresponding solar cells increased to the same extent. Specifically, the use of NTA at optimum
concentration improved the efficiency of the resulting DSC from 3.14 to 5.02%.
Keywords: Dye-sensitized solar cell, co-adsorbent, nicotinic acid, N719.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
5
Earth Abundant and Non-toxic FeS2 Nanocrystals for
Photovoltaic and Catalytic Applications
Chia-Chun J. Chen
1Department of Chemistry, National Taiwan Normal University,
Taipei 116, Taiwan 2Institute of Atomic and Molecular Sciences, Academia Sinica,
Taipei 106, Taiwan
Abstract
Colloidal pyrite FeS2 nanocrystals (NCs), which are abundant and nontoxic in nature, have
attracted attention for developing low-cost fabrications of catalytic electrode and photovoltaic
devices using solution processes. Soluble pyrite FeS2 NCs were successfully synthesized within
controlled sizes. In the photovoltaic applications, we have demonstrated a polymer solar cell
based on poly(3-hexylthiophene) (P3HT)/FeS2NCs hybrid and a heterojunction photodiode
consisting of a device structure of ITO/ZnO/FeS2NC/MoO3/Au. The both devices exhibited an
excellent photoresponse with a spectral response extended to NIR wavelengths. The promising
optoelectronic performance of the pyrite device has provided a crucial step toward the success in
producing colloidal pyrite NCs thin films for low-cost and large-area photoelectronics. Besides,
we also demonstrated other promising photovoltaic applications using FeS2 NCs pyrite ink to
fabricate a cost-effective counter electrode (CE) in dye-sensitized solar cells (DSSCs). FeS2 NC
has exhibited excellent electrochemical catalytic activity and remarkable stability in replacing
expensive Pt catalysts as a low-cost CE material in DSSCs. Devices using FeS2 NC-based CE
show promising power conversion efficiencies comparable to those using the Pt CE. Overall
results indicate that earth-abundant FeS2 NC is an interesting candidate of light absorbent and
catalysts, which can substantially lower the cost of photovoltaic and DSSCs in future commercial
applications. Other applications of FeS2 NCs for metal ion battery and hydrogen evolution
reaction will be also discussed in this talk.
References:
1. “Highly Active and Stable Hybrid Catalyst of Cobalt-doped FeS2 Nanosheets-Carbon Nanotubes for Hydrogen
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
6
Evolution Reaction” J. Am. Chem. Soc. 2015, 137, 1587-1592.
2. “Earth Abundant FeS2 Nanocrystals Ink as Catalytic Electrode for Dye-Sensitized Solar Cells” Angew. Chem.
Int. Ed, 2013, 52, 6694-6698.
3. “Solution-Processable Pyrite FeS2 Nanocrystals for the Fabrication of Heterojunction Photodiodes with Visible
to NIR Photodetection” Adv. Mater. 2012, 24, 3415-3420.
4. “Extended red light harvesting in a poly(3-hexylthiophene)/iron disulfide nanocrystal hybrid solar cell”
Nanotechnology. 2009, 20, 405207.
Dr. Chia-Chun J. Chen received his Ph.D. degree from Harvard
University in 1994 working with Professor Charlie Lieber. Then, he
joined Professor A. Paul Alivisatos group as a postdoctoral fellow in
Berkeley to study the physical property of nanocrystals. In 1996, he
returned back to Taiwan as an associate Professor. He now is the
Research Chair Professor at the Department of Chemistry, National
Taiwan Normal University, and the Adjunct Research Fellow at the Institute of Atomic and
Molecular Sciences, Academia Sinica, Taiwan. Professor Chen leads a researching team
working on various topics relating to syntheses, optoelectronic fabrications and biological
applications of nanomaterials. He has published over 120 papers in internationally top
referred journals and currently in charge of several research projects supported by Ministry
of Science and Technology of Taiwan.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
7
Modulation of bandgap in bilayer armchair graphene ribbons
by tuning vertical and transverse electric fields
Thanh-Tra Vu1*
, Thi-Kim-Quyen Nguyen2, Anh-Huy Huynh
1, Thi-Kim-Loan Phan
1,
Van-Truong Tran3, 4*
1Department of Physics, School of Education, Can Tho University, Can Tho, Vietnam
2School of Graduate, College of Natural Sciences, Can Tho University, Can Tho, Vietnam.
3C2N, Université Paris-sud, Université Paris Saclay, CNRS, 91405 Orsay, France
4EM2C, CentraleSupélec, Université Paris Saclay, CNRS, 92295 Châtenay Malabry, France
*[email protected] and [email protected]
Abstract
We investigate the effects of external electric fields on the electronic properties of bilayer
armchair graphene nano-ribbons. Using atomistic simulations with Tight Binding calculations
and the Non-equilibrium Green’s function formalism, we demonstrate that (i) in semi-metallic
structures, vertical fields impact more effectively than transverse fields in terms of opening
larger bandgap, showing a contrary phenomenon compared to that demonstrated in previous
studies in bilayer zigzag graphene nano-ribbons; (ii) in some semiconducting structures, if
transverse fields just show usual effects as in single layer armchair graphene nano-ribbons where
the bandgap is suppressed when varying the applied potential, vertical fields exhibit an
anomalous phenomenon that the bandgap can be enlarged, i.e., for a structure of width of 16
dimer lines, the bandgap increases from 0.255 eV to the maximum value of 0.40 eV when a
vertical bias equates 0.96 V applied. Although the combined effect of two fields does not enlarge
the bandgap as found in bilayer zigzag graphene nano-ribbons, it shows that the mutual effect
can be useful to reduce faster the bandgap in semiconducting bilayer armchair graphene nano-
ribbons. These results are important to fully understand the effects of electric fields on bilayer
graphene nano-ribbons (AB stacking) and also suggest appropriate uses of electric gates with
different edge orientations.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
8
Synthesis and Applications of
Organo Phosphorus Flame Retardants
DongQuy Hoang1, *
, Thu Hien Nguyen1, Huy Lam Pham
1, Thuy Linh Pham
1, JinhWan Kim
2
1 Faculty of Materials Science, University of Science, Vietnam National University, HoChiMinh City,
Vietnam 2 Department of Polymer Science and Engineering, Sungkyunkwan University, Suwon, South Korea
Abstract
To determine the effect of structures of organo-phosphorus flame retardants (FRs) on the
flame retardancy, a series of organo-phosphorus compounds was prepared and the chemical
structure of the products were confirmed by 1H- and 31P-NMR. Thermogravimetric analysis
(TGA) results reveal that organo-phosphorus compounds synthesized in this study show only one
step degradation in the range of 250 – 400 oC and work in the gas phase rather than do in the
condensed phase. The obtained products were blended with acrylonitrile-butadiene-styrene
copolymer (ABS) or polycarbonate (PC) and their flame retardancies were evaluated using UL-
94 vertical test. From UL-94 test results, V-0 ratings are achieved at 15-35 wt % loading of FR
for ABS and at much lesser amount of loading for PC. In both cases, it is clearly observed that
the flame retardancy is strongly dependent on the P content of FR.
Keywords: Biscyclic phosphorus, ABS, Flame retardancy, Spirobisphosphonate,
Spirobisphosphate.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
9
Computational Material Design of Two Dimensional Materials
and Their Energy Applications
Jer-Lai Kuo
Institute of Atomic and Molecular Sciences, Academia Sinica, Taiwan
Abstract
Two-dimensional materials have attracted attention from both fundamental aspects and
application. In this work, we will present some of our recent effort to using first-principles based
computational tools to design two-dimensional materials for energy applications. We have
explored new possible ionic two dimensional materials and discover some that have not been
synthesized yet. Furthermore, their potential applications to adsorption of Li (for battery and
hydrogen storage) and hydrogen evolution reactions (HER) are also examined.
[1] C-H Chang, C-F Fan, S-H Lin, J-L Kuo, Phys. Rev. B, 88, 195420 (2013)
[2] S-H Lin, and J-L Kuo, Phys. Chem. Chem. Phys., 16, 20763 (2014)
[3] Y-W Chen, YJ Du, and J-L Kuo, J. Phys. Chem. C, 118, 20383 (2014)
[4] D. B. Putungan, S-H Lin, and J-L Kuo, Phys. Chem. Chem. Phys., 17, 11367 (2015)
[5] D. B. Putungan, S-H Lin, and J-L Kuo, ACS App. Mate. & Int., 8, 18754 (2016)
Keywords: 2D Materials, Density Functional Methods, Energy Application.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
10
Electrode materials for lithium-ion and sodium-ion batteries
My Loan Phung Le1,2
, Le Thanh Nguyen Huynh1, Van Hoang Nguyen
1, Van Man Tran
1,2
1 Applied Physical Chemistry Laboratory (APCLAB), VNUHCM-University of Science, Ho Chi Minh City,
Vietnam 2 Department of Physical Chemistry, Faculty of Chemistry, VNUHCM-University of Science, Ho Chi Minh City,
Vietnam
Abstract
Since commercialization, lithium-ion batteries (LIBs) are the first-choice source of
electrochemical energy storage for portable electronic devices because of high energy density, high
voltage, and long-life cycle. On the other hand, sodium-ion batteries (NIBs) have recently received many
great attractions as a next generation power source storage beyond LIBs. Theoretically, NIBs may not
reach the energy density of LIBs because sodium is more than 3 times heavier than lithium and the
standard electrochemical potential of sodium (2.71 V) is lower than lithium (3.04 V) versus SHE.
However, more suitable applications of NIBs would be expected in the presence of a smart grid
systemwhere the operation cost and longevity of the battery are more important aspects of a whole
system. Our research works have been focused on the prospective transition metallic oxides in various
structures (layered, tunnel, amorphous…) which could reversible intercalate both of lithium and sodium
ions. For example, vanadium oxide V2O5 in bilayered structure showed an insertion-extraction reversible
of 1,5 ion Li+ (~350 mAh/g) in range of 1,5-4 V (vs. Li
+/Li) and 1,2 ion Na
+ (~200 mAh/g) in range of 1-
4 V (vs. Na+/Na). The oxide Na0.44MnO2 with tunnel structure exhibited a specific capacity of 160 mAh/g
in lithium-ion cells and 130 mAh/g in sodium-ion cells.
Keywords: energy storage, lithium-ion batteries, intercalated electrode material, sodium-ion
batteries.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
11
Fabrication of Polystyrene Nanocomposite Based on Reduced
Graphene Oxide By In Situ Micro-emulsion Polymerization
Tam Mai Thanh1, Khanh Van Khuat Thi
1, Chi Nhan HaThuc
2, Huy Ha Thuc
1
1Faculty of Chemistry, University of Sciences, Vietnam National University – Ho Chi Minh City, 227 Nguyen Van
Cu, District 5, Ho Chi Minh City, Viet Nam 2 Material of Sciences, University of Sciences, Vietnam National University – Ho Chi Minh City, 227 Nguyen Van
Cu, District 5, Ho Chi Minh City, Viet Nam
Email: [email protected]
Abstract
Nanocomposite based on graphene is one of the major areas of current research. In this study,
polystyrene/graphene nanocomposite was fabricated by in-situ micro-emulsion polymerization
combined with melting or solution blend. Graphene (RGO) used in this study was reduced by
system of HI and CH3COOH acid which have been published previously. TEM images of PS/
RGOHI-AcOH nanocomposites showed the exfoliated structure of graphene in the PS matrix
due to the strong interaction between RGOHI-AcOH and polystyrene (PS). In particular, the
sheet resistance of PS/RGOHI-AcOH is 482 Ω/ (with ~20wt% RGOHI-AcOH content) and its
decomposition temperature is 442oC (with 2w% RGOHI-AcOH content) compared with 416
oC
of pure PS and the glass transition temperature of nanocomposite (with 0.5w%RGOHI-AcOH
content) increased 20oC compared with the pure PS. In addition, the influence of graphene in
rheological property, creep resistant, recovery stress and mechanical properties of polystyrene
was also investigated in giving the interesting results.
Keywords: graphene nanocomposite, polystyrene nanocomposite, microemulsion,
polymerization.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
12
Ballistic Thermal Conduction and Thermoelectrics
Chih-Wei Chang
1 Center for Condensed Matter Sciences, National Taiwan University, Taipei, Taiwan
Abstract
Thermoelectric materials are always poor thermal conductors. Indeed, various phonon scattering
mechanisms are now used to shorten the phonon mean free paths and to create the thermal
resistances. However, the effects were thought to be incompatible with ballistic thermal
conduction, which was believed to exclusively occur at ultralow temperatures. Here I will
provide experimental evidence that unprecedented ballistic thermal conduction over 8.3μm can
be found in SiGe nanowires at room temperature. We find that phonon localizations induced by
alloy scatterings in SiGe nanowires result in an unexpected low percentage of excited phonons
participating the heat conduction process in these SiGe nanowires, thereby lengthen the average
phonon mean free path. The ballistic thermal conduction is also supported by other unusual
phenomena, including non-additive thermal resistance in series and contact thermal resistances
being independent of contact areas. The discovery could enable wave-engineering of phonons at
room temperature and stimulate many new designs of thermoelectric devices.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
13
Microstructures of graft-type polymer electrolyte membrane for
fuel cell application
Tran Duy Tap
1, Nguyen Chanh Thi
1, Phan Trong Thanh
1, Nguyen Van Vinh
1,
Vu Thi Thuy Dung1, Do Duy Khiem
2, Luu Anh Tuyen
2,
Nguyen Tien Cuong3, Vu Nguyen Khoi
3
1 University of Science Ho Chi Minh City, 227 Nguyen Van Cu, District 5, HCMC
2 Center for Nuclear Techniques HCMC, 217 Nguyen Trai, District 1, HCMC
3 VNU University of Science, 334 Nguyen Trai, Thanh Xuan, Hanoi, Vietnam
* Corresponding author: [email protected]
Abstract
The hierarchical structures of ETFE-PEMs were investigated using small- and ultra-small-angle
X-ray scattering experiments (SAXS and USAXS) (Fig. 1). The ETFE-PEMs with ion exchange
capacities (IECs) < 2.4 mmol/g possessed conducting graft domains around lamellar crystals,
with a d-spacing of 21.8–29.1 nm, and oriented crystallites (lamellar grains) with short and long
correlation distances of 218–320 nm and 903–1124 nm, respectively. The membranes with IECs
> 2.7 mmol/g showed a new phase of crystallite network domains with a d-range of 225–256 nm,
indicating a phase transition from oriented crystallite to crystallite network structures in the IEC
range of 2.4–2.7 mmol/g. Noted that for the ETFE-PEMs with high IECs, higher conductivity at
30% RH and compatible tensile strengths at 100% RH and 80 °C, compared with Nafion,
originated from the well-interconnected ion channels around the crystallites and the remaining
lamellar crystals and crystallites, respectively.
10-2
10-1
100
101
10-2
100
102
104
106
100
101
10-1
101
103
10-2
10-1
101
103
105
107
II
I
Original ETFE
Grafted ETFE 19%
Dry ETFE-PEM 19%
Wet ETFE-PEM 19%
a) Vung I Vung II
I(q)(c
m-1)
q (nm-1)
II
b)
I
c)
Fig. 1. SAXS profiles of Original ETFE, Grafted-ETFE, Dry and Wet ETFE-PEM with grafting
degree of 19%, coressponding the ion exchange capacity (IEC) of 1.3 mmol/g.
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
14
High performance supercapacitor based on
buckypaper/polyaniline/V2O5 composite
Toan Phuoc Tran and Quyet Huu Do*
Research Laboratories of Saigon Hi-Tech Park, Ho Chi Minh City, Vietnam.
* Corresponding author:[email protected]
Tel: +84 8 37360889 - Fax: +84 8 37360890
Abstract
Polyaniline (PANI) and Vanadium oxide were coated on carbon nanotube within its
nanoporous sheet (buckypaper) by in situ electrochemical polymerization. The composite was
then used to fabricate aqueous supercapacitor showing high capacitance and extended working
voltage. Outstanding capacitance of 399 F/g could be achieved at high weight loading of PANI,
which is favored for high volumetric capacitance of the device. This is due to the fact that the
composites consisting of carbon materials and electro-active species with highly specific surface
area, significantly enhance the energy density of supercapacitors, and such supercapacitors
exhibit both double-layer and pseudocapacitance.
Keywords: polyaniline, Vanadium oxide, carbon nanotubes, composite electrode,
electrochemical supercapacitor
The 2nd HCMUS – IAMS Workshop on
Energy Materials and Nanotechnology Vietnam
2016
15
Influences of defects on thermoelectric properties of Indium and
Gallium dually-doped ZnO thin films
Nhat Hong Nguyen Tran1,2
, Truong Huu Nguyen1, Yi-ren Liu
3, Masoud Aminzare
3, Anh Thanh
Tuan Pham2, Sunglae Cho
4, Deniz P. Wong
3, Kuei-Hsien Chen
3, Tosawat Seetawan
5, Ngoc Kim
Pham6, Hanh Kieu Thi Ta
6, Thu Bao Nguyen Le
7, Vinh Cao Tran
1 and Thang Bach Phan
1,6,*
1 Laboratory of Advanced Materials, University of Science, Vietnam National University, HoChiMinh City, Vietnam 2 Faculty of Applied Science, University of Technology, Vietnam National University, HoChiMinh City, Vietnam
3 Institute of Atomic and Molecular Sciences, Academia Sinica, Taiwan 4 Department of Physics, University of Ulsan, Korea
5 Center of Excellence on Alternative Energy, Research Development Institute, Program of Physics, Faculty of Science and Technology, Sakon
Nakhon Rajabhat University, 680 Nittayo, Mueang District, Sakon Nakhon, 74000, Thailand 6 Faculty of Materials Science, University of Science, Vietnam National University, HoChiMinh City, Vietnam
7 Department of Mathematics and Physics, University of Information Technology, Vietnam National University, Ho Chi Minh City, Viet Nam
Abstract
In this paper, we investigated the effect of single and multi-dopants on thermoelectrical properties
of the host ZnO films. Incorporation of single dopant Ga in the ZnO films improved the conductivity and
mobility but lowered the Seebeck coefficient. Dual Ga and In doped ZnO thin films shows slightly
decreased electrical conductivity but improved Seebeck coefficient. The variation of thermoelectric
properties is discussed in terms of film crystallinity, which is subjected to the dopants’ radius. Small
amount of In dopants with large radius may introduce localized regions in the host film, affecting
thermoelectric properties. The point defects are (
), (
) and
(
) in the undoped ZnO, GZO and IGZO thin films, respectively. Local
compressive strain is developed around the Ga and In ions due to its 3+ charge. As discussed in the above
part relating to the electrical properties, we suggest that random distribution of Ga and In dopant in the
ZnO lattice structures induced these above point defects as localization regions affecting the total thermal
conductivity.
Keywords: crystalline IGZO thin film, dual doping, Seebeck coefficient, thermal conductivity, localized
states.
1
CURRICULUM VITAE October, 2016
Kuei-Hsien Chen
Distinguished Research Fellow, Institute of Atomic and Molecular Sciences, Academia Sinica,
No. 1, Roosevelt Rd., Sec. 4, Taipei, 10617, Taiwan
Tel: +886-2-2366-8232 Fax: +8862-2362-0200 E-mail: [email protected]
Education Background:
B. S., Electrical Engineering, 1981, National Taiwan University Ph. D., Applied Science, 1989, Harvard University (E. Mazur), Cambridge, MA, USA
Employment History:
Senior Researcher, Science Research Laboratory, Somerville, MA, USA (1989) Researcher, General Electric R&D Center, Schenectady, NY, USA (1990 ~ 1992) Associate Research Fellow, IAMS, Academia Sinica (1993 ~ 2001) Research Fellow, IAMS, Academia Sinica (2001 ~ 2015) Adjunct Research Fellow, Center for Condensed Matter Sciences, NTU (2002 ~ present) Academic Deputy Director, IAMS, Academia Sinica (2012 ~ 2016) Acting Director, IAMS, Academia Sinica (2016 ~) Distinguished Research Fellow, IAMS, Academia Sinica (2015 ~)
Current Fields of Interest:
Advanced materials for energy applications, including CZTS for photovoltaic and LIB, carbon nanostructures for electrocatalysis and phtocatolysis, and thermoelectric materials.
Honors, Awards, and Recognitions:
Ho Chin Tui Outstanding Honorary Award in Materials Science, 2012. Outstanding Scholar Awards of the Foundation for the Advancement of Outstanding Scholarship, 2008-2013. Certificate of Appreciation for Peer Review by ACS, 2011. Best Poster Award, MRS-2009, Boston, 2009. First Prize in Science as Art Contest, MRS-2008, Boston, 2008. Outstanding Poster Award, ICONSAT 2006, New Delhi, India, 2006. Outstanding Research Award, National Science Council, Taiwan, 2004. Outstanding Publication Award by IAMS, Academia Sinica, 2002, 2004, 2006. Young Scholar Research Award, Academia Sinica, 2000. National Science Council Research Award, 1994-2000.
Academic Activities:
Board committee member of International Academy of Electrochemical Energy Science (IAOEES), 2014 ~ present Member of the Advisory Editorial Board, Chemical Engineering & Techonology (Wiley-VCH), 2012 ~ present International Reviews in Reviewer for Advanced Materials, Nanoletters, Nanoscale, Chem. Phys. Lett., J. Appl. Phys., Appl. Phys. Lett., and Applied Phys. Organizer or Co-organizers of 18 International Conferences.
Publication Statistics:
2
418 Referred papers, 97 International conference Invited/Keynote/Plenary talks, 10 book chapters, and 16 patents; Total citation: 10900+; H-index: 53; Average citation: 28.66. Among all the publications, 11 papers have been listed by Thomson Reuters Essential Science Indicators as highly cited (top 1%) papers.
Represented Publications:
1. “Catalytic growth and characterization of gallium nitride nanowires,” C.-C. Chen, C.-C. Yeh, C. H.
Chen, M. Y. Yu, H. L. Liu, J. J. Wu, K. H. Chen, L. C. Chen, J. Y. Peng, and Y. F. Chen, J. Am. Chem.
Soc. 123, 2791 (2001).
2. “Heterostructures of ZnO-Zn coaxial nanocables and ZnO nanotubes,” J. J. Wu, S. C. Liu, C. T. Wu, K.
H. Chen and L. C. Chen, Appl. Phys. Lett. 81, 1312 (2002).
3. “Ultrafine platinum nanoparticles uniformly dispersed on arrayed CNx nanotubes with high
electrochemical activity,” C. L. Sun, L. C. Chen, M. C. Su, L. S. Hong, O. Chyan, C. Y. Hsu, K. H.
Chen, T. F. Chang and L. Chang, Chem. of Mater. 17, 3749 (2005).
4. “Photosensitive gold-nanoparticle-embedded dielectric nanowires,” M. S. Hu, H. L. Chen, C. H. Shen,
L. S. Hong, B. R. Huang, K. H. Chen, and L. C. Chen, Nature Materials 5, 102 (2006).
5. “Anomalous blueshift in emission spectra of ZnO nanorods with sizes beyond quantum confinement
regime,” C. W. Chen, K. H. Chen, C. H. Shen, J. J. Wu, W. F. Pong, and L. C. Chen, Appl. Phys. Lett.
88, 241905 (2006).
6. “Improved broadband, and quasi-omnidirectional anti-reflection properties with biomimetic silicon
nanostructures,” Y. F. Huang, S. Chattopadhyay, Y. J. Jen, C. Y. Peng, T. A. Liu, Y. K. Hsu, C. L. Pan, H.
C. Lo, C. H. Hsu, Y. H. Chang, C. S. Lee, K. H. Chen and L. C. Chen, Nature Nanotechnology 2, 770
(2007).
7. “High performance of low electrocatalysts loading on CNT directly grown on carbon cloth for DMFC,”
C. H. Wang, H.-Y. Du, Y. T. Tsai, C. P. Chen, C. J. Huang, L. C. Chen, K. H. Chen, and H. C. Shih, J.
Power Sources 171, 55 (2007).
8. “Anti-reflecting and photonic nanostructures,” S. Chattopadhyay, Y. F. Huang, Y. J. Jen, K. H. Chen and
L. C. Chen, an invited review article in A. G. Cullis and S. S. Lau, Eds., Materials Sci. and Engin.
Report, Elsevier 69, 1-35 (2010).
9. “Flexible supercapacitor based on polyaniline nanowires/carbon cloth with both high gravimetric and
area-normalized capacitance,” Y.Y. Horng, Y.C. Lu, Y.K. Hsu, C.C. Chen, L.C. Chen and K.H. Chen, J.
Power Sources 195, 4418 (2010).
10. “Tunable photoluminescence from graphene oxide,” C.T. Chien, S.S. Li, W.J. Lai, Y.C. Yeh, H.A. Chen,
L.C. Chen, K.H. Chen, T. Nemoto, S. Isoda, M. Chen, T. Fujita, M. Chhowalla, and C.W. Chen,
Angewandte Chemie 51, 6662 (2012).
11. “Graphene oxide as a promising photocatalyst for CO2 to methanol conversion,” H.C. Hsu, Indrajit
Shown, H.Y. Wei, Y.C. Chang, H.Y. Du, Y.G. Lin, C.A. Tseng, C.H. Wang, L.C. Chen, Y.C. Lin, K.H.
Chen, Nanoscale 5, 262 (2013).
12. “Highly efficient visible light photocatalytic reduction of CO2 to hydrocarbon fuels by Cu -NPs
decorated graphene oxide,” I. Shown, H.C. Hsu, Y.C. Chang, C.H. Lin, P.K. Roy, A. Ganguly, C.H.
Wang, J.K. Chang, C.I. Wu, L.C. Chen, K.H. Chen, Nano Letters 14, 6097-6103 (2014).
13. “Bifacial sodium-incorporated treatments: tailo ring deep traps and enhancing carrier transport
properties in Cu2ZnSnS4 solar cells,” Y.R. Lin, V. Tunuguntla, S.Y. Wei, W.C. Chen, D.P. Wong, C.H.
Lai, L.K. Liu, L.C. Chen and K.H. Chen, Nano Energy 16, 438 (2015).
14. “Improving the thermoelectric performance of metastable rock-salt GeTe-rich Ge-Sb-Te thin films
through tuning of grain orientation and vacancies,” I.N. Chen, C.W. Chong, L.M. Lyu, D.P. Wong, W.L.
Chien, A. Anbu, Y.F. Chen, L.C. Chen, and K.H. Chen, Physica Status Solidi A 1-8 / DOI
10.1002/pssa.201600274 (2016).
15. “Enhanced thermoelectric performance in percolated bismuth sulfide composite,” D.P. Wong, W.L.
Chien, C.Y. Huang, C.E. Chang, A. Ganguly, L.M. Lyu, J.S. Hwang, L.C. Chen , and K.H. Chen, RSC
Advances 6, 98952 (2016).
1
Li-Chyong Chen (林麗瓊)
Current Position and Affiliation:
Distinguished Research Fellow and Director,
Center for Condensed Matter Sciences (CCMS),
National Taiwan University
Work Address, Telephone & Email:
No. 1, Roosevelt Road, Section 4, Taipei, Taiwan 106
Phone: 886-2-3366-5200; Mobile: 0920-291314; E-mail: [email protected]
Education:
(1) Ph. D. in Applied Physics (1983-1989), Harvard University, Cambridge, MA, USA
(2) B. S. in Physics (1977-1981), National Taiwan University, Taipei, Taiwan
Professional Employment History:
(1) Director (2012-present), Distinguished Research Fellow (2007-present), Research
Fellow (2000-2007), and Associate Research Fellow (1994-2000) in CCMS; Teaching
Assistant (1981-1983) in Department of Physics, National Taiwan University
(2) Technical Member: Materials Scientist (1989-1994), General Electric, Corporate
Research and Development, Materials Research Center, Schenectady, NY, USA
Board Members, Awards & Honors:
(1) Member of the Board of Directors, Materials Research Society, USA (3yrs term,
2017-2019)
(2) Academician of Asia-Pacific Academy of Materials (2015)
(3) Series Editor, Member of the Series Board, WSPC Series in Nanoscience and
Nanotechnology, World Scientific Publishers (2015-present)
(4) Advisory Editorial Board, Book Series on Energy and Sustainability, Cambridge
University Press and the Materials Research Society (2013-present)
(5) Acharya Vinova International Award in Materials Science and Technologies, VBRI,
India (2013)
(6) Ho Chin-Tui Outstanding Scholar Award, Ho Chin-Tui Foundation, Taiwan (2012)
(7) Outstanding Scholar Award, Foundation for the Advancement of Outstanding
Scholarship, Taiwan (2010-2015)
(8) Outstanding Research Award, National Science Council, Taiwan (2010-2013)
(9) Fellow, the Materials Research Society, USA (2010)
(10) Laureate of the Khwarizmi International Award (2009)
(11) International Federation of Inventors’ Association Lady Prize (2009)
(12) Distinguished Visiting Research Fellow, Royal Academy of Engineering, UK (2008)
(13) Outstanding Scholar Research Project, Natl. Science Council, Taiwan (2008-2011)
2
(14) Honorary Doctor, Linköping University, Sweden (2007)
(15) Outstanding Research Award, National Science Council, Taiwan (2006)
(16) Fellow, the Physical Society of ROC in Taiwan (2006)
(17) Research Achievement Award, National Taiwan University, Taiwan (2004)
(18) Editorial Advisory Board, Critical Reviews in Solid State and Materials Sciences,
Taylor and Francis (2004-present)
(19) Academia Sinica Young Scholar Research Award, Taiwan (2000)
(20) Reinhold Rudenberg Memorial Prize, Harvard, USA (1989)
(21) IBM Predoctoral Fellowship, USA (1986-1988)
Expertise Areas and Research Interests:
Nanomaterials, Thin Film Technologies, Energy, Optoelectronics, and Sensing
Research Outputs:
Overall > 370 papers, 15 invited book chapters or review articles, 14 patents;
Total citations > 11,150 & H-index = 53
Major Publications in Most Recent Years:
(1) ‘Enhanced Solar Cell Performance of Cu2ZnSn(S,Se)4 Thin Films through Structural
Control by Using Multi-metallic Stacked Nanolayers and Fast Ramping Process for
Sulfo-selenization’, W. C. Chen, C. Y. Chen, et al., K. H. Chen* and L. C. Chen*, Nano
Energy, doi: 10.1016/j.nanoen.2016.09.022 (2016).
(2) ‘Understanding the Interplay between Molecule Orientation and Graphene Using
Polarized Raman Spectroscopy’, C. Y. Chen, D. P. Wong,
et al., K. H. Chen,
L. C. Chen*
and Y. F. Chen*, ACS Photonics 3, 985 (2016).
(3) ‘Beaded−stream−like CoSe2 Nanoneedle Array for Efficient Hydrogen Evolution
Electrocatalysis’, C. P. Lee, et al., K. H. Chen* and L. C. Chen*, J. Mater. Chem. A 4,
4553(2016).
(4) ‘Directly-grown Hierarchical Carbon Nanotube@Polypyrrole Core-shell Hybrid on
Carbon Cloth as a High-performance Flexible Supercapacitor with High Cycle Stability’,
Yesi, Indrajit Shown, et al., Li-Chyong Chen*, Kuei-Hsien Chen*, ChemSusChem 9,
370 (2016). Invited paper
(5) ‘Bifacial Sodium-incorporated Treatments: Tailoring Deep Traps and Enhancing Carrier
Transport Properties in Cu2ZnSnS4 Solar Cells’, Yi-Rung Lin, et al., Li-Chyong Chen*
and Kuei-Hsien Chen*, Nano Energy 16, 438 (2015).
(6) ‘Nontoxic Solvent Based Sol-Gel Cu2ZnSnS4 Thin Film for High Efficiency and
Scalable Low-cost Photovoltaic Cells’, Venky Tunuguntla, et al., Li-Chyong Chen* and
Kuei-Hsien Chen*, J. Mater. Chem. A 3, 15324 (2015). Inside back cover
(7) ‘Design for Approaching Cicada-wing Reflectance in Low- and High- Index
Biomimetic Nanostructures’, Y. F. Huang, Y. J. Jen, Li-Chyong Chen, Kuei-Hsien
3
Chen*, and Surojit Chattopadhyay*, ACS Nano 9, 301 (2015).
(8) ‘Highly Efficient Visible Light Photocatalytic Reduction of CO2 to Hydrocarbon Fuels
by Cu-NPs Decorated Graphene Oxide’, Indrajit Shown, Hsin-Cheng Hsu, et al.,
Li-Chyong Chen*, Kuei-Hsien Chen*, Nano Lett.14, 6097 (2014).
(9) ‘Novel Iron Oxyhydroxide Lepidocrocite Nanosheet as Ultrahigh Power Density Anode
Material for Asymmetric Supercapacitors’, Yin-Chu Chen, Yan-Gu Lin, et al.,
Kuei-Hsien Chen* and Li-Chyong Chen*, Small 10, 3803 (2014).
(10) ‘Direct Assessment of the Mechanical Modulus for Graphene Co-doped with Low
Concentrations of Boron-Nitrogen by a Non-contact Approach’, S. H. Pan, et al., L. C.
Chen* and Y. L. Chueh*, Nanoscale 6, 8635 (2014). Inside back cover
(11) ‘Effect of Chemical Doping of Boron and Nitrogen on the Optical and Electrochemical
Properties of Carbon Nanotubes’, D. Jana, C. L. Sun, L. C. Chen* and K. H. Chen,
Progress in Materials Science 58, 565 (2013).
(12) ‘Band Gap Engineering of Chemical Vapor Deposited Graphene by in-situ BN Doping’,
C. K. Chang, et al., L. C. Chen* and K. H. Chen*, ACS Nano 7, 1333 (2013).
(13) ‘High-K Nanophase Zinc Oxide on Biomimetic Si Nanotip Array as Super-capacitors’,
H. C. Han, et al., L. C. Chen*, Nano Lett.13, 1422 (2013).
(14) ‘Graphene Oxide as a Promising Photocatalyst for CO2 to Methanol Conversion’,
Hsin-Cheng Hsu, et al., Li-Chyong Chen and Kuei-Hsien Chen*, Nanoscale 5, 262
(2013). Highly cited
(15) ‘Vitalizing Fuel Cells with Vitamin: Pyrolyzed Vitamin B12 as Non-precious Catalyst of
Low Symmetry for Enhanced Oxygen Reduction Reaction’, S. T. Chang, et al., L. C.
Chen*, and K. H. Chen*, Energy Environ. Sci. 5, 5305 (2012).
(16) ‘Pyrolyzed Cobalt Corrole as a Potential Non-Precious Catalyst for Fuel Cells’, H. C.
Huang, et al., L. C. Chen and K. H. Chen*, Adv. Func. Mater. 22, 3500 (2012).
(17) ‘Plasmonic Ag@Ag3(PO4)1−x Nanoparticle Photosensitized ZnO Nanorod-array
Photoanodes for Water Oxidation’, Y. G. Lin, et al., L. C. Chen* and K. H. Chen*,
Energy Environ. Sci. 5, 8917 (2012).
(18) ‘Top Laminated Graphene Electrode in a Semitransparent Polymer Solar Cell by
Simultaneous Thermal Annealing/Releasing Method’, Y. Y. Lee, et al., K. H. Chen, L. C.
Chen, H. L. Chen, and C. W. Chen*, ACS Nano 5, 6564 (2011).
(19) ‘Anti-reflecting and Photonic Nanostructures’, S. Chattopadhyay, et al., K. H. Chen and
L. C. Chen*, Mater. Sci. and Eng. Rev. 69, 1 (2010). Highly cited
(20) ‘Flexible Supercapacitor Based on Polyaniline Nanowires/Carbon Cloth with both High
Gravimetric and Area-normalized Capacitance’, Y. Y. Horng, et al., L. C. Chen*, K. H.
Chen*, J. Power Sources 195, 4418 (2010). Highly cited
National Taiwan Normal University , Taipei, Taiwan
Chia-Chun, Chen 陳家俊
Address:
Department of Chemistry
88, Sec. 4, Tingzhou Rd., Taipei City 11677, Taiwan
Phone: +886-2-7734-6173
Fax: +886-2-8931-6363
Email: [email protected]
Professional Position:
2014--: NTNU Chair Professor, 臺灣師範大學 講座教授
Department of Chemistry, National Taiwan Normal University, Taipei, Taiwan
2009-2014: Distinguished Professor,
Department of Chemistry, National Taiwan Normal University, Taipei, Taiwan
2002--: Adjunct Research Fellow, 中央研究院 合聘研究員
Institute of Atomic and Molecular Sciences, Academia Sinica, Taipei, Taiwan
2001-2009: Professor,
Department of Chemistry, National Taiwan Normal University, Taipei, Taiwan
1999-2001: Associate Professor,
Department of Chemistry, National Taiwan Normal University, Taipei, Taiwan
1996-2001: Associate Professor,
Department of Chemistry, National Chung-Cheng University, Chia-Yi, Taiwan
1994-1996: Postdoctoral Fellow,
Department of Chemistry University of California (with Professor A. P. Alivisatos), Berkeley,
CA, USA
Education:
Dec. 1994: Ph. D. in Chemistry,
Department of Chemistry, Harvard University (with Prof. C. M. Lieber), Cambridge, MA, USA
Major Honors and Awards:
2014 Outstanding Research Award (科技部傑出研究獎)
2006 Y. Z. Hsu Research Award
2004 IAMS Annual Award for Outstanding Research
2001 Excellent Researcher of the Year, Tsinghua Chemistry Foundation
Scientific Expertise and Current Research Activities:
Energy Applications of Nanoparticles: Li ion Battery, Hydrogen Evolution Catalysts, Al ion Battery
Bio-medical Applications using Nanomaterials: Biosensor, Bio-imaging
New Synthetic Approaches for Nanostructures
National Taiwan Normal University , Taipei, Taiwan
Selected Publications:
1. D-Y Wang, Y-T Jiang, H-A Chen, K-C Ho, C.-C. Chen, H. Dai “Highly Active and Stable Hybrid
Catalyst of Cobalt-doped FeS2 Nanosheets-Carbon Nanotubes for Hydrogen Evolution
Reaction” J. Am. Chem. Soc. 2015, 137, 1587-1592.
2. D.-Y. Wang, H.-L. Chou, Y.-C. Lin, F.-J. Lai, C.-H. Chen, J.-F. Lee, B.-J. Hwang, Chia-Chun
Chen, 2012: Simple Replacement Reaction for the Preparation of Ternary Fe1−xPtRux
Nanocrystals with Superior Catalytic Activity in Methanol Oxidation Reaction. J. Am. Chem.
Soc., 134(24), 10011-10020.
3. T.-R. Kuo, V.-A. Hovhannisyan, Y.-C. Chao, S.-L. Chao, S.-J. Chiang, S.-J. Lin, C.-Y. Dong,
Chia-Chun Chen, 2010: Multiple Release Kinetics of Targeted Drug from Gold Nanorods
Embedded Polyelectrolytes Conjugates Induced by Near-infrared Laser Irradiation. J. Am.
Chem. Soc., 132(40), 14163-14171.
4. S.-W. Chou, Y.-H. Shau, P.-C. Wu, Y.-S. Yang, D.-B. Shieh, Chia-Chun Chen, 2010: In vitro and
in vivo Studies of FePt Nanoparticles for Dual Modal CT/MRI Molecular Imaging. J. Am. Chem.
Soc., 132(38), 13270-13278.
5. D.-Y. Wang, C.-H. Chen, H.-C. Yen, Y.-L. Lin, P.-Y. Huang, B.-J. Hwang, Chia-Chun Chen, 2007:
Chemical Transformation from FePt to Fe1-xPtMx (M = Ru, Ni, Sn) Nanocrystals by a Cation
Redox Reaction: X-ray Absorption Spectroscopic Studies. J. Am. Chem. Soc., 129(6),
1538-1540.
6. Chia-Chun Chen, Y.-P. Lin, C.-W. Wang, H.-C. Tzeng, C.-H. Wu, Y.-C. Chen, C.-P. Chen, L.-C.
Chen, Y.-C. Wu, 2006: DNA-Gold Nanorod Conjugates for Remote Control of Localized Gene
Expression by Near Infrared Irradiation. J. Am. Chem. Soc., 128(11), 3709-3715.
7. C.-C. Lin, Y.-C. Yeh, C.-Y. Yang, C.-L. Chen, G.-F. Chen, Chia-Chun Chen, Y.-C. Wu 2002:
Selective Binding of Mannose-Encapsulated Gold Nanoparticles to Type I Pili in Escherichia
Coli. J. Am. Chem. Soc., 124(14), 3508-3509.
8. H.-M. Lin, Y.-L. Chen, J. Yang, Y.-C. Liu, K.-M. Yin, J.-J. Kai, F.-R. Chen, L.-C. Chen, Y.-F. Chen,
Chia-Chun Chen, 2003: Synthesis and Characterization of Core-Shell GaP@GaN and
GaN@GaP Nanowires. Nano. Lett., 3(4), 537-541.
9. Chia-Chun Chen, C.-C. Yeh, C.-H. Chen, M.-Y. Yu, H.-L. Liu, J.-J. Wu, K.-H. Chen, L.-C. Chen,
J.-Y. Peng, Y.-F. Chen, 2001: Catalytic Growth and Characterization of Gallium Nitride
Nanowires. J. Am. Chem. Soc., 123(12), 2791-2798.
10. Chia-Chun Chen, A. B. Herhold, C. S. Johnson, A. P. Alivisatos, 1997: Size dependence of
structural metastability in semiconductor nanocrystals. Science (Washington), 276(5311),
398-401.
11. Chia-Chun Chen, C. M. Lieber,* 1993: Isotope effect and Superconductivity in Metal-Doped
C60 Superconductors. Science (Washington), 259(5095), 655-658.
12. Chia-Chun Chen, S. Kelty, C. M. Lieber,* 1991: (RbxK1-x)3C60 Superconductors: Formation of
a Continuous Series of Solid Solutions. Science (Washington), 253(5022), 886-888.
1
Curriculum Vitae
Jer-Lai Kuo
Office Address Institute of Atomic and Molecular Sciences, Academia Sinica
No. 1, Roosevelt Rd., Sec. 4, Taipei, 10617, Taiwan
(e-mail) [email protected]
(office) (886) 2-2366-8207 (fax) (886) 2-2362-0200
Degrees Aug 1995 Bachelor of Science, Department of Physics,
National Taiwan University, Taipei, Taiwan
Aug 1997 Master of Science, Department of Physics,
National Taiwan University, Taipei, Taiwan (Prof. T.M. Wu and Prof. S. H. Lin)
Jan 2003 Doctor of Philosophy, Chemical Physics Program,
Ohio State University, Columbus, OH, U.S.A (Prof. Sherwin J. Singer)
Academic Appointments Jan 2003 Postdoctoral Fellow, Center for Molecular Modeling,
University of Pennsylvania. Prof. Michael L. Klein
Dec 2004 Assistant Professor, School of Physical and Mathematical Sciences,
Nanyang Technological University, Singapore
April 2009 Associate Research Fellow, Institute of Atomic and Molecular Science
Academia Sinica, Taipei, Taiwan
March 2014 Research Fellow, Institute of Atomic and Molecular Science
Academia Sinica, Taipei, Taiwan
Award & Honors Jan 2002 Presidential Pre-doctoral Fellowship, Ohio State University
July/2008 Young Researcher Award, Nanyang Technological University, Singapore
Sept/2009 Young Scholar Award, Foundational for Advancement of Outstanding Scholars , Taiwan
Mar/2011 The Distinguish Lecture Award in Physical Chemistry, The Chemical Society of Japan
For work on theoretical models of aqueous systems
Jan/2012 Career Development Award, Academia Sinica
Mar/2012 The Distinguish Lecture Award in Theoretical Chemistry, The Chemical Society of Japan
For work on theoretical chemistry
June/2012 Junior Researcher Award, Academia Sinica
July/2013 Young Scholars' Creativity Award,
Foundational for Advancement of Outstanding Scholars, Taiwan
Dec/2013 Promising Scientist Award of CMOA
Apr/2014 Young Scholar Award, Shui-Mu Foundation of Chemistry, Taiwan
Sept/2016 Mid-career Award, Asian Consortium on Computational Materials Science, Japan
Curriculum Vitae
Chih-Wei Chang Associate research fellow Center for Condensed Matter Sciences National Taiwan University No. 1, Roosevelt Rd., Sec. 4 Taipei 10617, Taiwa TEL: 02-33665293 Email: [email protected] http://homepage.ntu.edu.tw/~cwchang137/index.html Education: Ph.D., Physics, 2006, University of California at Berkeley Thesis: Electrical and Thermal Transport Measurements on Nano-structured Materials M.S., Physics, 1998, National Taiwan University, Taiwan. Thesis: Thermoelectric Power Studies on Colossal Magnetoresistance Materials B.S., Physics, 1996, National Taiwan University, Taiwan. Experiences 2014-present: Associate research fellow, Center for Condensed Matter Sciences, National Taiwan University 2009-2014: Assistant research fellow, Center for Condensed Matter Sciences, National Taiwan University 2007-2009: Postdoctoral researcher, Nanoscale Science and Engineering Center, University of California at
Berkeley. 2001-2006: Ph.D. student/Research assistant, Department of Physics, University of California at Berkeley. 2000-2001: Research assistant, Center for Condensed Matter Science, National Taiwan University. 1998-2000: (military service) Second Lieutenant in Arsenal 203. 1996-1998: Teaching assistant, Physics Department, National Taiwan University. Honors 2015 Ta-You Wu Memorial Award 2014 Y.Z. Hsu Scientific Paper Award 2014 Innovation Award for Young Investigators 2014 Junior Research Investigators Award, Academia Sinica 2010 Recruiting Outstanding Young Scholar Award by the Foundation for the Advancement of Outstanding
Scholarship 2009 Gold-Jade Fellow of Kenda Foundation, Taiwan Invited talks 1. (Keynote speaker): Phononics 2015, Paris, France 2. (Invited speaker): The second international conference on phononics and thermal energy science, Shanghai,
China (2014). 3. (Invited speaker and tutorial lecturer): The first international conference on phononics and thermal energy
science, Shanghai, China (2013). 4. (Invited speaker): The 7th International Conference on Advanced Materials and Devices, Jeju, Korea (2011).
Fields of specialty Nanoscale heat transfer, Nanophotonics Representative publications (for the past five years)
1. P. Y. Li, Y. Tsao, Y. J. Liu, Z. X. Lou, W. L. Lee, S. W. Chu, and C. W. Chang*, “Unusual imaging properties of superresolution microspheres”. Opt. Express 24, 16479 (2016).
2. T. K. Hsiao, B. W. Huang, H. K. Chang, S. C. Liou, M. W. Chu, S. C. Lee, and C. W. Chang*, "Micron-scale ballistic thermal conduction and suppressed thermal conductivity in heterogeneously-interfaced nanowires". Phys. Rev. B 91, 035406 (2015).
3. T. K. Hsiao, H. K. Chang, S. C. Liou, M. W. Chu, S. C. Lee, and C. W. Chang*, "Observation of room temperature ballistic thermal conduction persisting over 8.3μm in SiGe nanowires". Nature Nanotech. 8, 534 (2013).
4. Y. K. Chang, Z. X. Lou, K. D. Chang, and C. W. Chang*, “Universal scaling of plasmonic refractive index sensors”, Opt. Express 21, 1804 (2013).
5. V. Lee, R. K. Chen and C. W. Chang*, “Probing the limit of one-dimensional heat transfer under extreme bending strain”. Phys. Rev. B. 87, 035406 (2013).
University of Science, VNUHCM
LE VAN HIEU, Associate Professor, PhD Department of Magnetic and Biomedical Materials
Full name: LE VAN HIEU
Academic title:
Senior Lecturer - Associate Professor
Position:
Dean – Faculty of Materials Science
Head – Department of Magnetic and Biomedical Materials
Education:
PhD: Saint Petersburg National University, Russia, 1993. Speciality: Optics - Plasma Physics and Chemistry
BSc: VNUHCM - University of Science, Vietnam, 1981. Speciality: Optics and Spectroscopy
Phone: +84-08-3835 0831 Email: [email protected]
1. Research Areas:
Hybrid thin film solar cell
Electronic and optical materials
Magnetic material for biomedical applications
Photocatalyst and antibacterial materials
Biosensors
Computational materials
2. Faculty/Department/Laboratory/Office
Department of Magnetic and Biomedical Materials - Faculty of
Materials Science
3. Research Activities
Synthesis of antibacterial nanocomposite materials PP/TNTs/Ag,
Research Project of HCMC Science and Technology Department,2015.
Synthesis of magnetic nanoparticle iron oxide Fe3O4 coated SiO2 with
functionalized surface for early detection of metastasis breast cancer
cell, VNUHCM-JAIST Joint Research Project 2014.
Synthesis of conducting polymer thin films, an inorganic nanorod
materials and organic/inorganic heterojunctions for solar cell
applications , Key research project of VNUHCM (B2011-18 - 3TĐ).
4. Research Achievements and Awards
2nd
Place Award – Award of Vietnam Science and Technology
Creation 2010 (VIFOTEC - 2010).
5. Education lectures
Emission Electronics and its Application (MSc. Degree)
Thermodynamics of Materials (MSc. Degree)
Quantum Mechanics (BSc. Degree)
Electrodynamics (BSc. Degree)
Electronics and Plasma Physics (BSc. Degree)
Thin film Physics (BSc. Degree)
6. SCI Selected Publications:
Huu Phuc Dang, Quang Ho Luc, Van Hieu Le, Tran Le, The Journal of
Alloys and Compounds, 687 ,1012-1020, (2016).
T.K.Hanh Ta, M.ThuongTrinh, N.V. Long, T.T. My Nguyen, T.L.
Thuong Nguyen, L.Thuoc Tran, B.Thang Phan, Derrick Mott, Shinya
Maenosono, Hieu.T.V and Van Hieu Le, Colloids and Surfaces A:
Physicochem. Eng. Aspects 504 ,1–8, (2016).
Huu Phuc Dang, Q. Ho Luc, Tran Le, and Van Hieu Le, Journal of
Nanomaterials, Volume 2016, Article ID 7825456,(2016).
K. Ngoc Pham, Minsu Choi, C.Vinh Tran, T. Do Nguyen, Van Hieu Le,
Taekjib Choi, Jaichain Lee, and B.Thang Phan, J. of Electronics
Materials, DOI: 10.1007/s11664-015-3889-z, (2015).
C.H.Tien; T.V. Man; H.V.Linh; P.X.T.Tung; D.T.T.Thuy; L. V. Hieu,
Int.J. Nanotechnol., Vol.12,Nos.5/6/7, pp 347-356, (2015).
H.Tien Cao, X.T.Tung Pham, V.Linh Ha and Van Hieu Le, Adv. Nat.
Sci.: Nanosci. Nanotechnol. 5, 045017 (2014)
T.T.T. Van, S. Turrell, B. Capoen, L.V. Hieu, M. Ferrari, D. Ristic, L.
Boussekey, C. Kinowski, J. of Materials Science, 49, 8226-8233 (2014).
Pham Van Viet, Bach Thang Phan, Le Van Hieu, Cao Minh Thi, J. of
Nanoscience and Nanotechnology, 15,1-5 (2014).
T. H. C. Son, L. K. Top, N. T. D. Tri, H. T. C. Nhan, L. Q. Vinh, B. T.
Phan, S. S. Kim, and Le Van Hieu, Met. Mater. Int. 20, 2, 337 (2014).
VNUHCM-University of Science
TRAN Van Man, PhD Department of Physical Chemistry – Faculty of Chemistry
Full name: TRAN Van Man
Academic title: Assistant Professor
Position:
Head – Department of Physical
Chemistry
Head – Office of Science &
Technology
Education:
PhD: Grenoble Institute of
Technology, France, 2009
M.Sc: VNUHCM - University of
Science, Vietnam, 2003
Phone: +84 – (903) – 066 075
Email: [email protected]
1. Research Areas: Materials for energy
Physico-chemical properties of nanomaterials
Kinetics of electrochemical reaction
Fuel Cell
Rechargeable battery and supercapacitor
2. Faculty/Department/Laboratory/Office Department of Physical Chemistry, Faculty of Chemistry
VNUHCM KeyLab - Applied Physical Chemistry
3. Research Activities
Energy recovery from bamboo biomass by coupling advanced oxidation and biological process:
application to a sugar solution contaminated with furfurals, ONRG project Grant Number
N62909-14-1-N214 (2013–2016).
Hybridization of rechargeable battery and electrochemical capacitor, ONRG project and
VNUHCM Bilateral joint research Grant Number N62909-13-1-N235 and HS2013-76-01 (2013–
2016).
Nano catalysts based on nanometals ansd nano carbon for electrodes in PEMFC, MOST project
ĐT.NCCB-ĐHƯD.2011-G11 (2011–2016).
4. Education lectures General Physics, Kinetics of Electrochemical Reactions, Energy.
5. Selected Publications: Nguyen Luong Nhat Phu, Ha The An, Tran Van Man, Nguyen Thi Phuong Thoa, Le Van
Thang, Performance characteristics for oxygen reduction reaction of nanostructured Pt100-xCox
supported on Vulcan carbon and carbon nanotubes catalysts, International Journal of Nanotechnology, Vol. 12 (5-6-7) 1/2015.
Thi Giang Huong Nguyen, Thi Van Anh Pham, Thi Xuan Phuong, Thi Xuan Binh Lam, Van
Man Tran, Thi Phuong Thoa Nguyen, Nano-Pt/C electrocatalysts: synthesis and activity for
alcohol oxidation, IOP-Advances in Natural Sciences: Nanoscience and Nanotechnology, 2013,
Vol. 4 p. 035008.
Thanh Nhan Tran, Thi Van Anh Pham, Van Man Tran, My Loan Phung Le, Thi Phuong Thoa
Nguyen, Synthesis of amorphous silica and sulfonic acid functionalized silica used as reinforced phase for polymer electrolyte membrane, IOP-Advances in Natural Sciences: Nanoscience and
Nanotechnology Vol. 4, 045007, 2013
Vu Thi Hong Phuong, Tran Van Man, Le My Loan Phung, Nanostructured Platinum and Carbon Supported Pt-Ni Catalyst for Polymer Electrolyte Fuel Cell, ECS Transactions Vol. 64
(3), 2014.
University of Science, VNUHCM
TRAN DUY TAP, PhD Department of Nuclear Physics
Full name: TRAN DUY TAP Academic title: Full Lecturer - PhD Position:
Group leader of applied nuclear technology in material science, Department of Nuclear Physics
Education:
PhD: The University of Tokyo, Japan, 2013.
MSc: VNUHCM - University of Science, Vietnam, 2008.
BSc: VNUHCM - University of Science, Vietnam, 2005.
Phone: +84-1218071485 Email: [email protected]
1. Research Areas:
Development of polymer electrolyte membranes for hydrogen type fuel cells
and characterization the hierarchical structure-property relationship for high
fuel cell performance using quantum beam analysis and direct observations
(Small and Ultra small angle X-ray scattering (SAXS/USAXS), Wide angle Xray scattering (WAXS), Nuclear magnetic resonance (NMR), Positron
annihilation lifetime spectroscopy (PALS), Doppler broadening spectroscopy
(DBS), Fourier transform infrared spectroscopy (FT-IR), Atomic force
microscope (AFM), Scanning electron microscope (SEM), Polarized light
microscopy (PLM), Titration analysis (TA), Thermal gravimetric analysis (TGA), Differential scanning calorimetry (DSC), Electrochemical impedance
spectroscopy (EIS), Mechanical testing).
Physics and application of low-dimensional structures using quantum beam
analysis and direct observations.
Structure − property relationship for high performance polymer.
2. Faculty/Department/Laboratory/Office Department of Nuclear Physics - Faculty of Physics
3. Education lectures Radiation technology.
Applied nuclear techniques in industry .
Applied nuclear techniques in agriculture, medicine, and biology.
Quantum, atomic, and nuclear physics.
4. Selected Publications: Tran Duy Tap, Shin-ichi Sawada, Shin Hasegawa, Kimio Yoshimura, Yojiro
Oba, Masato Ohnuma, Yosuke Katsumura, Yasunari Maekawa, Hierachical
structure-property relationships in graft-type fluorinated polymer electrolyte
membranes using small- and ultrasmall-angle X-ray scattering analysis, Macromolecules, 47, 2373-2383, 2014.
Tran Duy Tap, Shin-ichi Sawada, Shin Hasegawa, Yosuke Katsumura, and
Yasunari Maekawa, Poly(ethylene-co -tetrafluoroethylene) (ETFE)-based
graft-type polymer electrolyte membranes with different ion exchange
capacitieswith various IEC: Relative humidity dependence for fuel cell applications, Journal of Membrane Science, 447, 19-25, 2013.
L. A. Tuyen, Z. Kajcsos, K. Lázár, T. D. Tap , D. D. Khiem, and P. T. Phuc,
Positron annihilation characteristics in multi-wall carbon nanotubes with
different average diameters, Journal of Physics: Conference Series 443, 012065, 2013.
Tran Duy Tap, S. Sawada, S. Hasegawa, K. Yoshimura, Y. Oba, M. Ohnuma,
Y. Katsumura, and Y. Maekawa, Wide-q observation in small angle X-ray
scattering of ETFE-based graft-type polymer electrolyte membranes, JAEA-Review 2012-046, 32, January, 2013.
A. T. Luu, Zs. Kajcso, N. D. Thanh, T. Q. Dung, M. V. Nhon, K. Lazar, K.
Havancsak, G. Huhn, Z. E. Horvath, T. D. Tap , L. T. Son, and P. T. Phuc,
Multi-wall carbon nanotubes investigated by positron annihilation techniques and microscopies for further production handling, Physica Status Solidi C, 6,
2578-2581, 2009.
M. Maekawa, Tran Duy Tap, and A. Kawasuso, Characterization of defects
by the helium and hydrogen implantation using a slow positron beam, JAEA
Review 2008-055, 153, November, 2008.
5. Pictures of research activities
Radiation-induced graft polymerization of styrene onto an ETFE substrate and the subsequent sulfonation to prepare ETFE-PEM.
Schematic illustrations of the morphology change in the higher-order structures of the ETFE-PEMs as a function
of the IEC as the results of SAXS measurements.
Small angle X-ray scattering (SAXS) profiles of the grafted-ETFE with GDs of 0−117%.
University of Science, VNU-HCM
Short introduction about Researcher/Professor
Full name: Hà Thúc Chí Nhân
Male
Female
Academic title: PhD. Position:
Vice dean – Materials
Science Faculty
Head of Materials
Fundamental Laboratory -
Materials Science Faculty
Education:
PhD: University of
Savoie, France, 2008
Master: University of
Maine, France 2005
BSc: University of
Science, National University of HCM city -
Vietnam, 2004 Phone: (0084) 08 38 350 831
Cell phone: 0906 628 356 Email:
1.Research Areas:
Study on synthesis and elaboration of composite and nanocomposite based on polymer and
natural fillers.
Study on synthesis and elaboration of biodegradable/ biocompatible or antibacterial materials
– Application in packaging and biomedical field.
Study on the adsorption of heavy metals and organic pollutants by nano materials –
Application for water treatment domain.
2. Faculty/Department/Laboratory/Office: Faculty of Materials Science/ Laboratory of fundamental
Laboratory.
3. Research Activities
Project, PI: Synthesis of Graphene from Graphit oxide by monoglyceride agent – Application
on elaboration of nanocomposite based on polystyrene/grapheme - VNU-HCM C 2015-2016.
Participant project: Study on elaboration of PP/TiO2/Ag composite and its antibacterial property – project of Department of Science and Engineering 2016 - HoChiMinh city,
Vietnam
Participant project: Elaboration of biodegradable material based on Poly(Vinyl Alcohol) and
starch - VNU-HCM C, 2013-2015.
Participant project: Graphene synthesis and polystyrene / grapheme nanocomposite - Key
projects VNUHCM, 2012-2014.
Participant project: Study on synthesis of Hybrid Nanorod-Polymer Solar Cells - Key projects VNUHCM, 2011-2013.
Project, PI: Synthesis of nano-structure organoclay/Application for nanocomposite materials -
Key projects VNUHCM, 2010-2012.
Saigon Hightech Park - Vietnam: Member of Scientific committee
Vinaplastic Association: Member of Scientific committee
4. Research Achievements and Awards
Certificate of Merit from President of Vietnam National University - HoChiMinh City (2013).
Excellent Young Lecturer of Vietnam National University - HoChiMinh City (VNU-HCM),
2013.
Excellent Young Lecturer of HoChiMinh City, 2011, 2013, 2014.
5. Education lectures:
Physical states and mechanical properties of polymer materials.
Polymer processing technology
Polymer Composite and Nanocomposite
6. Selected Publications:
Dang Mao Nguyen, Thi Vi Vi Do, Anne-Cecile Grillet, Huy Ha Thuc,
Chi Nhan Ha Thuc; International Biodeterioration & Biodegradation, volume 115, 257-265 (2016).
D.M. Nguyen, T.T. Vu, Anne-Cécile Grillet, H. Ha Thuc, C.N. Ha Thuc; Carbohydrate
Polymers, Volume 136, 2016, Pages 163–170 (2015).
C. N. Ha Thuc, Huu Tien Cao, Mao Dang Nguyen, Mai Anh Tran, Laurent
Duclaux, Anne-Cecile Grillet, and H. Ha Thuc; Journal of Nanomaterials Volume
2014, Article ID 302735, 11 pages
Van Hai Le, Chi Nhan Ha Thuc and Huy Ha Thuc; Nanoscale Research Letters, 8:58 (2013).
D.T. Tran, D.M. Nguyen, C.N. Ha Thuc and T.T. Dang Composite Interfaces, Volume 20,
Issue 5, 2013, pages 343-353.
L. Cui, K.N. Hui, K.S. Hui, S.K. Lee, W. Zhou, Z.P. Wan, Chi-Nhan Ha Thuc; Materials
Letters 75, 175–178 (2012).
Q.X. Xia, K.S. Hui, K.N. Hui, D.H. Hwang, Jai Singh, Y.R. Cho, S.K. Lee, W. Zhou, Chi-
Nhan Ha Thuc, Y.G. Son, Z.P. Wan; Materials Letters 78, 180–183 (2012).
C. N. Ha Thuc, A-C. Grillet, L. Duclaux, L. Reinert, H. Ha Thuc; Applied Clay Science, Volume 49, Issue 3, Pages 229-238 (2010).
D. Derouet, C. N. Ha Thuc, J. Appl. Polym. Sci. 109, 2113-2127 (2008).
University of Science,VNUHCM
Short introduction about Researcher/Professor (For International Activities)
Full name: NGUYEN Tuyet
Phuong
Male Female X
Academic title : Dr.
Position: Viec-dean
Education:
. PhD: Roskilde University,
Denmark, 2009 – 2012
. Master: VNUHCM-US, 2004 –
2007
. BSc: VNUHCM-US, 1999 –
2003
Phone: +84.909011274
Email: [email protected]
1.Research Areas:
- Photovoltaics; Dye-sensitized Solar Cells;
- Organometallic complexes;
- Photo-catalyst materials;
- Electrochemistry;
- Surface modification.
2. Faculty/Department/Laboratory/Office:
Department of Inorganic and Applied Chemistry
Faculty of Chemistry
4.Research Achievements and Awards:
2012-2017: Young Affiliate of TWAS
2010: JSPS Scholarship, Japan.
2007: Danish International Development Assistance
Fellowship, Denmark.
2003: Texas Tech Scholarship, USA
20022005: Vietnamese Government Scholarship.
5. Education lectures:
- General Chemistry 1 (VNUHCM-US)
- Fundamental of Inorganic Chemistry 1 (VNUHCM-US)
- Lab course: Analytical Chemistry A (Roskilde University)
- Lab course: General Chemistry A and B (VNUHCM_US)
- Lab course: Inorganic Chemistry 1 and 2 (VNUHCM-US)
6.Selected Publications:
13. Phuong Tuyet Nguyen, Vinh Son Nguyen, Vy Anh Tran, Thu Anh
Pham Phan, Tuan Van Huynh, Torben Lund, Nicotinic acid as a new
co-adsorbent in dye-sensitized solar cells, Applied Surface Science
392 441-447 (2017)
12. Søren Hassing, Kit D. Jernshøj, Phuong Tuyet Nguyen, Torben
Lund, In vitro polarized resonance Raman study of N719 and N719-
TBP in Dye-sensitized Solar Cells, Journal of Technology Innovations
in Renewable Energy 5 21-32 (2016)
11. Vinh Son Nguyen, Trinh Diem Thi Duong, Phuong Tuyet Nguyen,
So-Nhu Le, Reduction of Graphene oxide by TiO2 nanotubes
photocatalyst, Science & Technology Development Journal 18 231-
238 (2015) (ISSN 1859-0128)
10. Torben Lund, Phuong Tuyet Nguyen, Thomas Ruhland,
Modification of TiO2 based dye-sensitized solar cell photo anodes by
electrochemical grafting, Journal of Electroanalytical Chemistry 758
85-92 (2015)
9. Torben Lund, Phuong Tuyet Nguyen, Hai Minh Tran, Peter Pechy,
Shaik M Zakeeruddin, Michael Grätzel, Thermal stability of the DSC
Ruthenium dye C106 in robust electrolytes, Solar Energy 110 96-104
(2014)
8. Søren Hassing, Kit D. Jernshøj, Phuong Tuyet Nguyen, Torben
Lund, Investigation of the stability of Ruthenium-Based Dye (N719)
utilizing the polarization properties of dispersive Raman modes and/
or of the fluorescent emission, J. Phys. Chem. C 117 23500-23506
(2013)
7. Phuong Tuyet Nguyen, Poul Erik Hansen, Torben Lund, The effect
of 4-tert-butylpyridine and Li+ on the thermal degradation of TiO2 –
bound ruthenium dye N719, Solar Energy 88 23-30 (2013)
6. Poul Erik Hansen, Phuong Tuyet Nguyen, Krake Jacob, Jens
Spanget Larsen, Torben Lund, Dye-sensitized solar cells and
complexes between pyridines and iodines: A NMR, IR and DFT
study, Spectrochimica Acta Part A 98 247-251 (2012)
5. Anders Rand Andersen, Janne Halme, Torben Lund, Muhammad
Imran Asghar, Phuong Tuyet Nguyen, Kati Miettunen, Erno
Kemppainen, Ole Albrektsen, Charge transport and photocurrent
generation characteristics in dye solar cells containing thermally
degraded N719 dye molecules, J. Phys. Chem. C 115 15598-15606
(2011)
4. Phuong Tuyet Nguyen, Binh Xuan Thi Lam, Anders Rand Andersen,
Poul Erik Hansen, Torben Lund, Photovoltaic performance and
characteristics of dye sensitized solar cells prepared with the N719
thermal degradation products [Ru(L-H)2(NCS)(4-tert-
butylpyridine)][N(Bu)4] and [Ru(L-H)2(NCS)(1-
methylbenzimidazole)][N(Bu)4], Eur. J. Inorg. Chem. 2533–2539
(2011)
3. Phuong Tuyet Nguyen, Anders Rand Andersen, Eivind Morten
Skou, Torben Lund, Dye stability and performances of dye-sensitized
solar cells with different nitrogen additives at elevated temperatures –
Can sterically hindered pyridines prevent dye degradation? Solar
Energy Materials & Solar Cells 94 1582-1590 (2010)
2. Tran Minh Hai, Nguyen Tuyet Phuong, Nguyen Thai Hoang,
Nguyen Thi Phuong Thoa, Torben Lund, Interaction between 4-tert-
butylpyridine and the I3-/I
- redox electrolyte of dye-sensitized solar
cell and the effect of these interaction to the stability of dye-sensitizer
N719, Journal of Chemistry 48 (4C) 175-181 (2010)
1. Phuong Tuyet Nguyen, Rikke Degn, Hoang Thai Nguyen, Torben
Lund, Thiocyanate ligand substitution kinetics of the solar cell dye Z-
907 by 3-methoxypropionitrile and 4-tert-butylpyridine at elevated
temperatures, Solar Energy Materials & Solar Cells 93 1939–1945
(2009)
University of Science, VNUHCM
Hoang Thi Dong Quy - PhD Department of Polymer and Composite Materials – Faculty of Materials Science
Full name: HOANG THI DONG QUY
Academic title: Lecturer
Position:
Head – Department of Polymer
and Composite Materials
Education:
PhD: SungKyunKwan
University – South Korea, 2009
MSc: VNUHCM - University of
Science, Vietnam, 2005
BSc: VNUHCM - University of
Science, Vietnam, 2000
Phone: +84 – 934274547
Email: [email protected]
1. Research Areas:
Flame retardancy of polymer-compozite-nanocompozite materials
Composite and Nanocomposite materials
Functional polymer materials
2. Faculty/Department/Laboratory/Office Department of Polymer and Composite Materials - Faculty of Materials Science
3. Research Activities Chitosan/Oligochitosan-nano hybrid materials: preparation, properties, and biomedical
applications, VNUHCM, 2016-2017.
Flame retarding behaviors of novel phosphorus salt flame retardants and application of them to flammable polymer, composite based on PVC-wood flour and UP materials, NAFOSTED, 2014-
2016.
Flame retarding behaviors of novel halogen-free flame retardants and application of them to flammable polymer, composite based on PVC-wood flour and UP synthesized from recycle PET, VNUHCM, 2013-2015.
Synthesis, applications and properties of metal salts for fire retardant materials, VNUHCM, 2011-2012.
4. Education lectures General Chemistry, Fundamental of Polymer, Polymer and Composite Materials, Additive
Polymer, Material characterization.
6. ISI Publications: Hoang D and Kim J. Synthesis and applications of biscyclic phosphorus flame retardants.
Polymer Degradation and Stability, 2008;93:36-42.
Hoang D, Kim J, and Jang BN. Synthesis and performance of cyclic phosphorus-containing flame retardants. Polymer Degradation and Stability, 2008;93:2042-7.
Hoang D and Kim J. Flame retardation performances of novel aryl cyclicphosphorus flame retardants when applied to highly flammable polymers. Macromolecular Research, 2013:21(2):184-193.
Hoang D, Kim W, and Kim J. Flame-retarding behaviors of novel spirocyclic pentaerythritol based phosphorus compounds. Macromolecular Research, 2015:23(5):442-448.
Hoang D, Kim W, and Kim J. Flame retardancies of novel organo-phosphorus flame retardants based on DOPO derivatives when applied to ABS. Macromolecular Research, 2015:23(7):579-591.
Hoang D, Kim W, Hai V, Nguyen C, Giang T , An H, and Kim J. Synthesis, Flame Retardancy, and Thermal Degradation Behaviors of Novel Organo-Phosphorus Compounds Derived from
9,10-Dihydro-9-oxa-10-phosphaphenanthrene-10-oxide (DOPO). Macromolecular Research, 2016:24(1):66-73.
Hoang D, Nguyen TH, An HZ, and Kim J. Organo-Phosphorus Flame Retardants for Unsaturated Polyester Derived from Recycled Poly(ethylene terephthalate). Macromolecular Research, 2016:246):537-546.
Hoang D, Tran TV, Tran NQ, Nguyen CK, Nguyen TH, Truong MD, Tran DL, Le VT, and Nguyen DH. Functionalization of Fe3O4 nanoparticles with biodegradable chitosan-grafted-mPEG for paclitaxel delivery. Green Processing and Synthesis, 2016:5:459–466.
Hoang D, Pham TL, Nguyen TH, An HZ, and Kim J. Organo-Phosphorus Flame Retardants for Poly(vinyl chloride)/Wood Flour Composite. Polymer Composites, Wiley, Early view (DOI
10.1002/pc.24026).
Nguyen NT, Hoang D, Nguyen ND, Nguyen QH, Nguyen DH. Preparation, characterization, and antioxidant activity of water-soluble oligochitosan. Green Processing and Synthesis, 2016 (Accepted)
Can Tho University
Vu Thanh Tra, Doctor -Dr
Department of Physics, School of Education, Can Tho University, Can Tho, Viet Nam.
Full name: VU THANH TRA
Academic title: Doctor - Full Lecturer
Position:
Deputy Head of Department,
Physics Department, School of
Education, Can Tho University
Education:
Dr: National Chiao Tung
University, Taiwan, 2012.
BSc: Can Tho University, Viet
Nam, 2004
Phone: +84 916777386
Email: [email protected]
1. Research Areas: Complex oxide thin film and nanostructures for next generation devices.
Oxide thin film heterostructure and interface phenomena for new functionality.
Nanoscale characterization of complex oxides.
Low temperature physics
Topological defects in strongly correlated systems.
X – ray Absorption (XAS) study of multiferroic and superconducting materials
Computational physics
2. Faculty/Department/Laboratory/Office Physics Department, School of Education, Can Tho University, Can Tho, Viet Nam.
3. Research Activities and funding Theoretical study of the band structure and the electronic transport in graphene and graphene-
like materials based nanostructures, NAFOSTED (2016– 2018).
4. Research Achievements and Awards
The thesis prize of the outstanding international graduate student awards of National Chiao
Tung University 2012.
Vietnam government scholarship for excellent studies, from 09/2008 to 09/2012
Odon Vallet scholarship, for excellent graduated students, 2006 and 2007 (Master student)
Odon Vallet scholarship, for excellent studies at 13th Viet Nam School of Physics Nha
Trang, 25 December 2006, Viet Nam
Odon Vallet scholarship, for excellent studies at School of Nanophysics
Certificate of Merit, CTU, for excellent graduation level, 2004
Certificate of Merit, CTU, for excellent students in 2002-2003 and 2003-2004
Odon Vallet scholarship, for excellent studies, 2003 (Bachelor student)
5. Education lectures Mathematics methods, Electrodynamics, Quantum Mechanics, Professional English Physics,
Solid state of Physics
6. SCI Selected Publications:
C. Y. Wu, V. T. Tra, Y. F. Chen, J. K. Lee, and J. J. Lin , J. Appl. Phys. 108, 123708 (2010).
Y. Y. Chu, Y. F. Liao, V. T. Tra, J. C. Yang, W. Z. Liu, J. Y. Lin, Y. H. Chu, J. H. Huang, J.
Weinen, S. Agrestini, K. D. Tsuei, and D. J. Huang, Appl. Phys. Lett. 99, 262101 (2011).
B. C. Huang, Y. P. Chiu, P. C. Huang, W. C. Wang, V. T. Tra, J. C. Yang, Q. He, J. Y. Lin, C.
S. Chang, and Y. H. Chu, Phys. Rev. Lett. 109, 246807 (2012).
V. T. Tra, J. W. Chen, P. C. Huang, B. C. Huang, Y. Cao, C. H. Yeh, H. J. Liu, E. A. Eliseev,
A. N. Morozovska, J. Y. Lin, Y. C. Chen, M. W. Chu, P. W. Chiu, Y. P. Chiu, L. Q. Chen, C.
L. Wu, and Y. H. Chu, Adv. Mater. 25, 3357-3364 (2013).
H. J. Liu, V. T. Tra, Y. J. Chen, D. Yi, R. Huang, H. J. Lin, C. T. Chen, J. Y. Lin, and Y. H.
Chu, Adv. Mater. 25, 4753 (2013).
W. S. Chang, H. J. Liu, V. T. Tra, J. W. Chen, T. C. Wei, W. Y. Tzeng, Y. M. Zhu, H. H. Kuo,
Y. H. Hsieh, J. C. Lin, Q. Zhan, C. W. Luo, J. Y. Lin, J. H. He, C. L. Wu, and Y. H. Chu, ACS
Nano 8, 6242 (2014).
(Invited) V. T. Tra, J. C. Yang, Y. H. Hsieh, J. Y. Lin, Y. C. Chen, and Y. H. Chu, Phys. Status
Solidi RRL 8, 478 (2014).
C. Y. Huang, J. Zhou, V. T. Tra, R. White, R. Trappen, A. T. N’Diaye, M. Spencer, C. Frye,
G. B. Cabrera, V. Nguyen, J. Lebeau, Y. H. Chu, and M. B. Holcomb, J. Phys. Condens.
Matter., 27, 504003 – 504011 (2015).
J. Zhou, C. A. Jenkins, M. Marcus, V. T. Tra, R. Trappen, S. Polisetty, E. Wolfe, C. Frye, D.
Chen, J. Y. Lin, Y. H. Chu, and M. B. Holcomb, Phys. Rev. Lett., 107, 141603 – 141607
(2015).
V. T. Tra, J. C. Lin, D. S. Tsai, T. T. Lin, B. C. Huang, W. L. Hsu, H. J. Wu, R. Huang, N. V.
Chien, R. Yoshida, J. Y. Lin, Y. Ikujara, Y. P. Chiu, S. Gwo, D. P. Tsai, J. H. He, and Y. H.
Chu, Advanced Materials, DOI: 10.1002/adma.201503499.
S. W. Huang, L. Andrew Wray, Horng-Tay Jeng, V. T. Tra, J. M. Lee,M. C. Langner, J. M.
Chen, S. Roy, Y. H. Chu, R. W. Schoenlein, Y.-D. Chuang &J.-Y. Lin, Scientific Reports,
5:16690 | DOI: 10.1038/srep16690.
J.Zhou, V.T.Tra, S.Dong, R., M.A. Marcus, C.Jenkins, C.Frye, E.Wolfe, R.White, S.Polisetty,
J.Y.Lin, J.M.LeBeau, Y.H.Chu and M.B.Holcomb, Applied Physics Letters 107, 141603 (2015)
C-Y Huang, J Zhou, V T Tra, R White, R Trappen, A T N’Diaye, M Spencer, C Frye, G B
Cabrera, V Nguyen, J M LeBeau, Y-H Chu, M B Holcomb, Journal of Physics: Condensed
Matter 27 , 504003 – 504011,(2015).
V.T.Tra , D.S.Tsai , T.T.Lin , P.C.Huang , W.L.Hsu ,H.J.Wu , R.Huang , N.V.Chien ,
R.Yoshida , J.Y.Lin , Y.Ikuhara ,Y.P.Chiu , S.Gwo , D.P.Tsai , J.H.He , and Y.H.Chu,
Advanced Materials, , 28, 764–770, (2016).
Junfeng He, Padraic Shafer, Thomas R. Mion1, V. T. Tra, Qing He, J. Kong, Y.-D.
Chuang,W.L. Yang, M.J. Graf, J.-Y. Lin, Y.-H. Chu, E. Arenholz, Rui-Hua He, Nature
Communications, | DOI: 10.1038/ncomms10852
V. T. Tra, Tran Van Truong, Semicond. Sci. Technol. 31 (2016) 085002 (8pp)
V. T. Tra, J. Y. Lin, Y. J. Chen, Y. T. Liu, W. C. Kuo, Y. Y. Chin, H. J. Lin, J. M. Chen, J. M.
Lee, J. F. Lee, P. S. Shi, M. G. Jiang, J. Y. Juang, C. T. Chen, H. T. Jeng, and Y. H. Chu,
submitted.
H. Do, V. T. Tra, J. Y. Lin, and Y. H. Chu, , submitted.
University of Science, VNUHCM
Le My Loan Phung, Assistant Professor - PhD Department of Physical Chemistry – Faculty of Chemistry
Full name: LE MY LOAN PHUNG Academic tit le: Lecturer – University of
Science Position:
Head of Applied Physical Chemistry Laboratory – Key Laboratory of Viet
Nam National University of Ho Chi Minh city (VNU-HCM)
Education:
PhD: Grenoble Institute of Technology, France, 2010
BSc: University Toulon – Var, France, 2006
Phone: +84 – (902) – 359 089 Email: [email protected]
1. Research Areas:
Innovative synthesis of electrolyte & electrode materials for Li-batteries and Na-batteries
Structure and electrochemical characterization of electrolyte and electrode
Synthesis and study of carbon based composite electrode, transition metal oxide for supercapacitor
Assembly and fabrication process of batteries/supercapacitors
2. Faculty/Department/Laboratory/Office
Department of Physical Chemistry – Faculty of Chemistry
Laboratory of Applied Physical Chemistry
3. Research Activities 03/2016 – 04/2016: Visiting Researcher in Kyushu University within the research subject: Liquid
Type Electrolytes for Na-ion Battery” at Institute for Materials Chemistry and Engineering.
11/2015: Visiting Professor in Related Sakura Program, Kyushu University
01/09/2015 – 01/09/2017: Rhône-Alpes bilateral France – Viet Nam project, “Development of innovative electrolytes based on imidazolium ionic liquids for sodium batteries”
01/04/2012-01/04/2014: Project leader: “Study the effects on electrolyte properties of quaternary ammonium based ionic liquids used in lithium batteries”, project funding from National Foundation for Science and Technology Development (NAFOSTED)
01/04/2011-01/04/2013: Project leader: “Elaboration of cathode materials based on manganese dioxide for lithium batterie”, project funding from National University of Ho Chi Minh city (VNU-HCM).
1/05/2010-1/05/2011: Participant in research project: “Fabrication process of dye sensitized solar cell”, project funding from National University of Ho Chi Minh city
1/11/2011–1/05/2012: Participant in industrial project: “Diagnostic of degradation phenomena of SOFC fed with biogas by Raman spectroscopy coupled with electrochemical measurement”, project funding from National Research Agency (ANR), France
4. Research Achievements and Awards Scientist in Good International Publication – Vietnam National University - HoChiMinh City
(VNU-HCM), 2010, 2015.
20/09/2014: Travel grant from ONRG for participant International Conference on Diamond and Carbon in Melia, Spain, 7 – 11 September 2014.
5. Education lectures
General Chemistry, Basic Physical Chemistry, Sustainable Energy, Applied Electrochemistry .
6. SCI Selected Publications: V.M. Tran, A.T. Ha, My Loan Phung LE, Journal of Nanomaterials, vol. 2015, Article ID
609273, 12 pages, 2015. doi:10.1155/2015/609273
T.V. Le, H.T . Nguyen, A.T. Luu, V.M. Tran, Phung Loan My Le, Acta Metall. Sin. (Eng. Lett.)
V. T . LE, V. M. Tran, My Loan Phung LE et al., Materials Research, manuscript ID is MR-2015-0164.R1.
D. Muller-Bouvet, R. Baddour-Hadjean, M. Tanabe, J. P. Pereira-Ramos, L. T. N. Huynh, M. L. P. Le , Jean Pierre Pereira Ramos, Electrochimica Acta, 2015 (176), 586 – 593.
M. Bolloli, J. Kalhoff, F. Alloin, D. Bresser, My Loan Phung Le, B. Langlois, S. Passerini, Jean-Yves Sanchez, J. Phys. Chem. C, DOI: 10.1021/acs.jpcc.5b07514.
LE My Loan Phung, TRAN Ngoc Anh, NGO Hoang Phuong Khanh, NGUYEN Truong Giang, TRAN Van Man, Journal of Chemistry Solution, 2015, 44 (12), pp 2332 – 2343.
T.H. Pham, My Loan Phung Le , T .H. Nguyen, T .P.T . Nguyen, Journal of Electrochemical
Society, 161 (4), 2014, H1-H5.
A.N.Tran, T.N.V Do, Loan-Phung Le My, T.N. Le, Journal of Fluorine Chemistry, 2014, 164, 38 – 43.
V.M. Tran, T.A. Ha, Phung My Loan Le , Adv. Nat. Sci.:Nanosci. Nanotechnol., 2014, 5, 025005.
T.A. Ha, V.M. Tran, Phung My Loan Le , Advances in Natural Sciences: Nanoscience and Nanotechnology 2013 Vol. 4, p.035004 (5pp).
H. D. Nguyen, T .T .T . Mai, N.B. Nguyen, T .D. Dang, My Loan Phung Le , T .T . Dang, V. M.Tran, IOP-Advances in Natural Sciences: Nanoscience and Nanotechnology 4 (2013) pages 015016.
My Loan Phung LE, F. Alloin, P. Strobel, J-C. Leprêtre, L. Cointeaux, Carlos Pérez del Valle, Ionics, 2012, Vol. 18, pp. 817-827.
My Loan Phung LE, L. Cointeaux, P. Strobel, J-C. Leprêtre, P. Judenstein, F. Alloin, Journal of Physical Chemistry C, 2012, Vol. 116 (14), pp. 7712-7718.
My Loan Phung Le , T .X.B Lam, Q.T . Pham, T .P.T . Nguyen, Adv. Nat. Sci: Nanosci. Nanotechnol, 2011, 2, p025014.
My Loan Phung Le , P. Strobel, F. Alloin, C. Colin, 2011, 72, p124 – 135.
My Loan Phung Le , P. Strobel, F. Alloin, T. Pagnier, Electrochim. Acta, 2010, 56, p592-599.
My Loan Phung Le , F. Alloin, P. Strobel, J-C. Leprêtre, Carlos Pérez del Valle, Patrick Judeinstein, J. Phys. Chem. B, 2010, 114(2), p894-903.
Quyet Huu Do - PhD Laboratories of Nanotechnology – Laboratories of Saigon Hi-tech park
Quyet Huu Do - PhD Laboratories of Nanotechnology –
SHTPLABS
Education:
8/2013
Doctor of Philosophy – Industrial &
Manufacturing Engineering
High Performance Materials Institute,
Florida State University, Tallahassee,
FL, USA
7/2009
Master of Engineering – Electronic
Materials Science and Engineering
Kyungpook National University,
Daegu, Korea
7/2007
Bachelor of Engineering –
Engineering Physics
Center for Talented Engineer
Training, Hanoi University of
Science and Technology, Hanoi,
Vietnam
Phone: +84 – (9) – 87479117
Email: [email protected]
1. Research Areas:
My research focuses on development of new materials and fabrication methods
for applications in a wide range of technological areas from energy to
environmental and electronics technologies. Research activities involve materials
design, synthesis and characterization, device fabrication and testing, and
theoretical modeling and simulation. The goal of my research is to obtain
fundamental understanding of the processing – structure – property relationship,
which can be used to guide the development of new high performance devices.
2. Faculty/Department/Laboratory/Office
Laboratories of Nanotechnology – Laboratories of Saigon Hi-tech park
3. Research Activities
Fabrication of supercapacitor based on CNT/Nano Si/PANI composite
electrodes,Department of Science and Techonology, Ho Chi Minh City, Grant
number 222/2014/HĐ-SKHCN (12/2014-12/2016)
Saigon Hightech Park - Vietnam: Members of Scientific committee
4. SCI Selected Publications:
1. Quyet Huu Do and Changchun Zeng. Reactive deposition of ultrathin conformal
vanadium pentoxide within CNT buckypaper in supercritical fluid CO2 for
electrochemical capacitor, (2015) Nanotechnology in revision.
2. Jesse Smithyman, Quyet Huu Do, Changchun Zeng and Zhiyong Liang. Ultra-fast
aqueous Li-ion redox energy storage from vanadium oxide-carbon nanotube yarn
electrodes, (2015) Journal of Power Sources 277 59 – 63
3. Quyet Huu Do, Changchun Zeng, Jesse Smithyman, Richard Liang, and Jim P.
Zheng. Toward binder-free electrochemical capacitor electrodes of vanadium oxide -
nanostructured carbon by supercritical fluid deposition: precursor adsorption and
conversion, and electrode performance, (2014) Journal of Power Sources 248 1241–
1247. doi: 10.1016/j.jpowsour.2013.10.010
4. Quyet Huu Do, Changchun Zeng, Thomas R. Fielitz, O. Arda Vanli, Chuck Zhang ,
and Jim P. Zheng. Vanadium oxide – carbon nanotube composite electrodes for energy
storage by supercritical fluid deposition: experiment design and device performance,
(2013) Nanotechnology 24 315401.
5. Quyet Huu Do, Changchun Zeng, Chuck Zhang, Ben Wang, and Jim Zheng. Supercritical fluid deposition of vanadium oxide on multi -walled carbon nanotube buckypaper for supercapacitor electrode application, (2011) Nanotechnology 22 365402. (Journal highlight)
6. Quyet Huu Do, Young-Woo Heo, Jun-Hyung Lee and Jeong-Joo Kim. Solubility
and conductivity of (Al, Ga) co–doped ZnO, (2009) Journal of Ceramic Processing
Research 10 Special 1, s75-s81.
University of Science, VNUHCM
Phan Bach Thang, Associate Professor - PhD Department of Thin Film and Nanomaterials – Faculty of Materials Science
Full name: PHAN BACH THANG
Academic title: Full Lecturer
Position:
Vice Dean – Faculty of Materials
Science
Head – Department of Nano and
Thin Film Materials
Vice Head – Laboratory of
Advanced Materials
Education:
PhD: SungKyunKwan
University – South Korea, 2009
BSc: VNUHCM - University of
Science, Vietnam, 2001
Phone: +84 – (121) – 790 7700
Email: [email protected]
1. Research Areas: Thin film process and properties of nanolaminate oxide for oxide electronics.
Physical properties and mechanisms of multifunctional artificial oxide system for emerging non-volatile semiconductor memories (ReRAM): SrTiO3, ZnO, T iO2, CrOx, WOx…
Thermoelectric thin films materials
Memristive Biosensor
2. Faculty/Department/Laboratory/Office Department of Nano and Thin Film Materials - Faculty of Materials Science
Laboratory of Advanced Materials
3. Research Activities Study on fabrication of Memristive –Biosensor applied in biomedical analysis, Bilateral joint
research VNUHCM – VAST, HS2015-18-02 (2015–2017).
Investigating Electrical conduction and reversible resistance switching mechanisms of Transition Metal Oxides WOx for fabricating Random Access Memory, Key projects VNUHCM, B2013-18-
02 (2012–2014).
Electrical conduction and resistance switching mechanisms of Chromium oxide thin film, NAFOSTED, 103.02-2012.50 (2012–2014).
Electrical conduction and resistance switching mechanisms of nanostructural Cr-doped SrTiO3 and ZnO, T iO2 thin films applied in Electronic Memory Device, NAFOSTED, 103.99-2010.12
(2010–2012).
Journal of Korean Electrical and Electronics Engineers: Editorial Member
Saigon Hightech Park - Vietnam: Members of Scientific committee
4. Research Achievements and Awards Scientist in Good International Publication – Vietnam National University - HoChiMinh City
(VNU-HCM), 2009, 2012, 2014.
Excellent Young Lecturer – Vietnam National University - HoChiMinh City (VNU-HCM), 2011, 2013.
Excellent Young Lecturer – HoChiMinh City, 2011, 2013.
5. Education lectures General Physics, Fundamental Materials Science, Magnetic Materials, Electronic Materials,
Defect chemistry in metal oxides.
6. SCI Selected Publications: B. T. Phan and J. Lee, Appl. Phys. Lett. 93, 222906 (2008).
B. T. Phan and J. Lee, Appl. Phys. Lett. 94, 232102 (2009).
J. W. Seo, B. T. Phan , J. Stahn, J. Lee, and C. Panagopoulos, Phys. Rev. B. 82, 140405 (R) (2010).
J. W. Seo, B. T. Phan , J. Lee, H. D. Kim and C. Panagopoulos, Appl. Phys. Lett. 98, 171910 (2011).
B. T. Phan , T . Choi, A. Romanenko, J. Lee, Solid-State Electronics, 75, 43-47 (2012).
Kim Ngoc Pham, T rung Do Nguyen, Thi Kieu Hanh Ta, Khanh Linh Dao Thuy, Van Hieu Le, Duy Phong Pham, Cao Vinh Tran , Derrick Mott, Shinya Maenosono, Sang Sub Kim, Jaichan Lee, Duc Thang Pham and Bach Thang Phan , Eur. Phys. J. Appl. Phys. 64, 30102 (2013).
Hung Minh Le, Nam Hoang Vu, Bach Thang Phan, Comp. Mater. Sci, Computational Materials Science, 90, 171 (2014).
Ngoc Kim Pham, Do Trung Nguyen, Bang Tam Thi Dao, Kieu Hanh Thi Ta, Vinh Cao Tran, Van Hieu Nguyen, Sang Sub Kim, Shinya Maenosono, and Bach Thang Phan , Journal of
Electronic Materials. 43, No.7, 2747 (2014).
Duy Phong Pham, Bach Thang Phan, Van Dung Hoang, Huu Truong Nguyen, Thi Kieu Hanh Ta, Shinya Maenosono and Cao Vinh Tran, Thin Solid Films. 570, 16-19 (2014).
Thi Bang Tam Dao, Kim Ngoc Pham, Yi-Lung Cheng, Sang Sub Kim, Bach Thang Phan , Current Applied Physics. 14, 1707-1712 (2014).
Duy Phong Pham, Huu Truong Nguyen, Bach Thang Phan , Van Dung Hoang, Shinya Maenosono and Cao Vinh Tran, Thin Solid Films, 583, 201 (2015).
Kim Ngoc Pham, Minsu Choi, Cao Vinh Tran, Trung Do Nguyen, Van Hieu Le, Taekjib Choi, Jaichain Lee, and Bach Thang Phan, Journal of Electronic Materials. 44, 10, 3395 (2015).
Thi Kieu Hanh Ta, Minh-Thuong Trinh, Nguyen Viet Long, Thi Thanh My Nguyen, Thi Lien Thuong Nguyen, Cao Vinh Tran, Bach Thang Phan, Derrick Mott, Shinya Maenosono, Hieu Tran-Van and Van Hieu Le, Synthesis and Surface Functionalization of Anti-T-Cell Antibody
Coupled Fe3O4-SiO2-GPS-CDI Core-Shell Nanoparticles For Potential Applications in Bone Marrow Transplantation, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 54, 376 (2016).
Meena Rittiruam, Tosawat Seetawan, Sirakan Yokhasing, Korakot Matarat , Phan Bach
Thang, Manish Kumar, Jeon Geon Han, La/Sm/Er Cation Doping Induced Thermal Properties of SrTiO3 Perovskite, Inorganic chemistry, 55, 8822 (2016).
Hong Nhat Nguyen Tran, Huu Truong Nguyen, Yi-ren Liu, Masoud Aminzare, Thanh Tuan Anh Pham, Cao Vinh Tran, Sunglae Cho, Deniz P. Wong, Kuei-Hsien Chen, Tosawat Seetawan and Bach Thang Phan, Thermoelectric properties of Indium and Gallium dually -doped ZnO thin
films, ACS Applied Materials and Interface, Accepted (2016).