Post on 05-May-2023
AC-MnO2-CNT composites for electrodes of electrochemical supercapacitors
Subagio A.1, a, Priyono1, Pardoyo2, Aswardi2, Yudianti R.3,
Subhan A.3, Taer E.4
1Department of Physics, Faculty of Science and Mathematics, Diponegoro University, Indonesia
2Department of Chemistry, Faculty of Science and Mathematics, Diponegoro University, Indonesia 3Center of Physics Research, LIPI, Indonesia
4Department of Physics, University of Riau, 28293 Simpang Baru, Riau, Indonesia
aagus_fadhil@yahoo.com
Keywords: activated carbon, composite, CNT, MnO2, specific capacitance, supercapacitors
Abstract. Electrodes for electrochemical supercapacitors were fabricated by doctor blade method of
composite of activated carbon (AC), MnO2 and carbon nanotubes (CNTs). The AC-MnO2-CNTs
composites were synthesized by solution processing method in pH variation of 3, 7 and 11. The
composites were characterized by X-ray diffraction, scanning electron microscopy, transmission
electron microscopy and impedance spectroscopy. The XRD pattern shown the crystalline structure
and the SEM image observed that the distribution of CNTs was homogeneous between carbon
particles. The electrodes were fabricated for supercapacitor cells with 316L stainless steel as current
collector and 1 M Na2SO4 as electrolyte. An electrochemical characterization was performed by
using an electrochemical impedance spectroscopy (EIS) method using a LCR Hi-Tester HIOKI
3522 instrument and the results showed an increase in the value of specific capacitance at the AC-
MnO2-CNT on the acidic condition.
Introduction
Supercapacitors as energy storage devices fill the gap between conventional batteries and
capacitors, i.e. they have high specific energy and power density [1]. Supercapacitors are
considered to have high-power electrical capacitance, excellent reversibility, long life and
potentially in the development of technologies that support applications including electric vehicles,
portable computers, and other devices [2]. There are two kinds of supercapacitors depending on
charge storage mechanism and active materials: (i) electrochemical double layer capacitors (EDLC)
and (ii) redox supercapacitors or pseudo-capacitors [3]. In EDLCs, carbon-based materials with
high specific surface area are most widely used and energy storage mechanism is based on simple
physical movement of ions to and from the carbon electrode surface. In redox supercapacitors,
metal oxides or conducting polymers are commonly employed and energy is stored through fast and
reversible electrochemical charge transfer process. The specific and area capacitance is dependent
primarily on the characteristics of the electrode material that is, surface area, pore size distribution,
i.e. active area in the pores on which the double-layer is formed. Thus, providing highly porous
carbon as an electrode material can offer high stability and cyclability in supercapacitors.
Material carbon nanotubes (CNT) is one nanomaterial that has excellent mechanical properties.
CNT structure, length and diameter as well as the direction of crystal growth properties of CNTs
provide elastic modulus which has 5 times greater than the strong steel and tensile strength up to
100 times greater. Carbon nanotubes are considered as composite electrode materials for
supercapacitors because of potential excellent mechanical properties and good electrical
conductivity [4].
The addition of a metal oxide on the carbonaceous increases the electrochemical performance of
electrode material. Metal oxide is a material that has properties suited to optimizing the
performance of a supercapacitor. RuO2 as an example, the specific capacitance is reported 720 F/g
Materials Science Forum Vol 827 (2015) pp 113-118 Submitted: 2014-10-26© (2015) Trans Tech Publications, Switzerland Revised: 2015-03-23doi:10.4028/www.scientific.net/MSF.827.113 Accepted: 2015-04-26
All rights reserved. No part of contents of this paper may be reproduced or transmitted in any form or by any means without the written permission of TransTech Publications, www.ttp.net. (ID: 182.255.0.6-25/05/15,05:26:47)
in a state of acid electrolyte. However, Ru is a type of precious metal and at the same time RuO2 is
a poison, which blocked commercialization [5]. Currently, manganese dioxide (MnO2) has attracted
due to its superior capacitive performance, abundance and environmental friendliness. The
theoretical specific capacitance of MnO2 is high (1232 F/g), however, it cannot be achieved even
for the ultra thin MnO2 film because the poor electrical and ionic conductivities greatly limit the
practical performance of MnO2 based materials for supercapacitors [6]. Furthermore, to increase the
capacitance supercapacitors and improve the transport of electrons and ions in the electrode
efficiently, MnO2 was made as a composite structure [7].
Many approaches have been applied to prepared MnO2-CNT composites for supercapacitors
application. A microwave assisted reaction was developed to synthesize the compocite based on the
mass of MnO2 along [8]. CNT has been modified by MnO2 using acetic acid to achieve a pH of 2.3
of the mixing process. The results showed CNT-MnO2 nanocomposite shows the specific
capacitance of 162.2 F/g [9]. Reddy et al. have prepared Au-MnO2/CNT hybrid coaxial arrays,
resulting in a specific capacitance of 68 F/g based on total massa of materials and current collectors
[10]. The MnO2 and SWNT composites have been successfully synthesized via a novel room
temperature route starting with KMnO4, ethanol and commercial SWNT. The MnO2:20 wt% SWNT
composite showing the best combination of coloumbic efficiency of 75% and specific capacitance
of 110 F/g [11].
For the MnO2 synthesis based on the direct reaction between the CNT and permanganate,
synthesis condition such as reaction time, CNT amounts, solution acidity, preparation method and
CNT oxidation degree will affect the properties of prepared supercapacitor materials. Therefore, the
goal of the present work is to optimize the parameter of synthesis condition, i.e. the pH variation of
the mixing process of activated carbon, MnO2 and CNT. Characterization of AC-MnO2-CNT
composite is done by using XRD, SEM, TEM and EIS method.
Experimental
The AC-MnO2-CNT composite materials were synthesized using sol-gel method. Briefly, 2
grams of KMnO4 were dissolved in 20 ml of demineralized water and stirred until for 15 minutes.
Next, 2 grams of purified CNT and activated carbon (AC) were dissolved in 10 ml of demineralized
water. To increasing dispersion of CNT, the surfactant sodium dodecyl sulfate (SDS) of 5% of the
weight of CNT was added. The resulting suspension was stirred for 15 minutes. KMnO4 solution
was slowly inserted into the sol of CNTs that have been made in a container in pH of 3, 7, and 11.
The AC-MnO2-CNT mixture was added by acetic acid for pH of 3, without addition of a solution
for pH of 7 and added by ammonium hydroxide for pH of 11. After conditioning in pH variation,
the AC-MnO2-CNT composites were stirred for 24 hours. Finally, the resulting AC-MnO2-CNT
composites were filtered and washed with ethanol to remove the residual of KMnO4. The solid
products were dried in a vacuum at 100 ºC for 5 h to obtain the powder of AC-CNT-MnO2.
Microstructures of AC-MnO2-CNT products that have been formed were characterized using X-
ray diffraction (XRD) with a CuKα target. Morphology of samples was examinained using a
scanning electron microscope (JEOL-6510LA) and transmission electron microscope. The specific
capacitance of products were investigated by LCR Hi-Tester HIOKI 3522 instrument.
Result and Discussion
In order to show actual size and formation of deposited MnO2 particle, Fig. 1 present TEM
image of the pristine CNTs and AC-MnO2-CNT composite material. From this result, our attempt to
prepare the AC-MnO2-CNT composite materials was successful and the deposited MnO2 grains
clumped together. It can be seen that agglomerated MnO2 particles with an average size of about 50
∼ 150 nm were attached to the CNT.
114 Functional Properties of Modern Materials
Fig 1. TEM images of (a) the pristine CNT and (b) AC-MnO2-CNT composite.
Fig. 2 shows the morphologies of the AC-MnO2-CNT composites. It can be seen obviously
that MnO2 are distributed on the surface of CNT, meanwhile the AC formed mounds as background
of the morphologies and will play a role as a storage of charge in supercapacitors.
Fig. 2. SEM images of the AC-MnO2-CNT composites in pH of (a) 3, (b) 7 and (c) 11.
To determine the crystal structure, X-ray diffraction (XRD) was employed and the XRD patterns
of the products obtained under different in pH of AC-MnO2-CNT composites are shown in Fig. 3.
The diffraction peaks at 2 theta of 25.66° and 42.50° can be attributed to the (002) and (100) planes
of AC-CNT with hexagonal graphite structure [12]. The diffraction peaks at 2 theta of 28.65°,
37.63° and 41.91° are corresponding to (310), (211) and (411) planes of α-MnO2 orientation
(JCPDS 44-0141), respectively [13]. The intensity of the MnO2 peaks is lower, indicating
amorphous structure. The amorphous structure will support electrolyte into the electrode matrix and
increases the contact between electrolyte and electrodes [9].
Fig. 3. X-ray diffraction patterns of AC-CNT-MnO2 composites in pH value.
(a) (b)
Materials Science Forum Vol. 827 115
Electrochemical impedance spectroscopy testing need preparation of an requires a procedure to
form a supercapacitor modeling. Preparation of composites made by mixing AC-MnO2-CNT with
hydrogel electrolyte made by poly vinyl alcohol and Na2SO4 with ratio of 1:9. Once formed pellets
were wet by the electrolyte, then later assembled into a simple double layer supercapacitors
modeling with SS foil as current collector and celgard as separator.
The main objective in this EIS characterization was to determine the ability of the specific
capacitance of the sample AC-MnO2-CNT modified by variation in pH value. After the samples
were modeled as a double layer supercapacitors, the samples were connected and energized AC of
0.1 V at a frequency range of 0.1 Hz -100 kHz. From the data processing results obtained the
difference value of specific capacitance (CS) of each particular frequency variations in the
supercapacitor, which was presented by the graph in Fig. 4.
Fig. 4. Curves of specific capacitance as function of frequency.
Based on the data obtained specific capacitance (CS), the greatest value of the CS of the AC-
MnO2-CNT composite in pH condition of acid, neutral and alkaline were 7.86, 0.93 and 0.55 F/g,
recpectively. Measurement of specific capacitance that occurs in acidic reaction condition increased
significantly compared to neutral and alkaline state was related to the formation of MnO2 cathodic
reduction reaction. In reaction to the atmosphere slightly acidic and neutral atmosphere, ion MnO4-
with +7 oxidation number would be reduced to MnO2 precipitate with oxidation number +4, while
in a state of MnO4- alkaline ions would be reduced to manganate (MnO4
2-) which was described by
the following reaction:
1) The reduction reaction MnO4- acidic condition:
MnO4- + 4H
+ + 3e MnO2 + 2H2O
2) The reduction reaction MnO4- neutral condition:
MnO4- + 2H2O MnO2 + 4OH
-
3) The reduction reaction MnO4- alkaline condition:
MnO4- + 4OH
- 4MnO4
2- + 2H2O +O2
This reaction has been evidenced from the XRD pattern of AC-MnO2-CNT composite that the
presence of MnO2 has the greatest intensity was at the AC-MnO2-CNT composite in acidic
conditions. The MnO2 produced was in the form of α-MnO2 as the crystallographic groups of
MnO2. In general α-MnO2 is a type of crystal that comes into the group of the tetragonal crystal.
The stability of α-MnO2 structure is dependent on the protonation effect of the crystal. The presence
of high H+ ion at low pH is a condition in which crystals of this type exist in the most stable state.
116 Functional Properties of Modern Materials
The presence of H+ ions will support and stabilize cavities in the crystal structure of α-MnO2. The
ability of the double layer capacitance supercapacitors conductivity associated with strength and
mobilization of ions in accessing all parts of the electrode active material contained in the
supercapacitor cells. Strength conductivity is expressed through the movement of ions in an electric
field. If the number of ions increases, the current flow in the cell also increases. The presence of H+
ions on the structure of α-MnO2 will give a donations more ions inside the cell so that the
conductivity of supercapacitor cell will be increases [14]. Unfortunately, in this work the specific
capacitance of model was still lower. The decrease in the CNT amount will decrease the total mass
of the MnO2 coated due to a reduced surface area or a lower conductivity. As a result, the specific
capacitance decreases [15].
Summary
In this work, we designed and prepared the AC-MnO2-CNT composite materials for
supercapacitors. The process of modification of AC-MnO2-CNT in acidic pH atmosphere can
increase the ability of electrically with a maximum value of the specific capacitance of 7.86 F/g,
where in neutral and alkaline atmosphere obtained a maximum specific capacitance were 0.93 and
0.55 F/g, respectively.
References
[1] E. Iwama, P.L. Taberna, P. Azais, L. Brégeon, P. Simon, Characterization of commercial
supercapacitors for low temperature applications, Journal of Power Sources 219 (2012), 235-
239.
[2] J.R. Miller, P. Simon, Electrochemical capacitors for energy management, Science 321 (2008),
651-652.
[3] Y. J. Kang, B. Kim, H. Chung, W. Kim, Fabrication and characterization of flexible and high
capacitance supercapacitors based on MnO2/CNT/papers, Synthetic Metals 160 (2010), 2510-
2514.
[4] T. Laha, A. Agarwal, S. Seal, Synthesis and characterization of plasma spray formed carbon
nanotube reinforced aluminum composite, Journal of Materials Science and Engineering 381
(2004), 249-258.
[5] [5] H. Wang, C. Peng, J. Zheng, F. Peng, H. Yu, Design synthesis and the electrochemical
performance of MnO2/CNT as supercapacitor material, Journal of Materials Research Bulletin
48 (2013), 3389-3393.
[6] S.C. Pang, M.A. Anderson, T.W. Chapman, Novel electrode materials for thin‐film
ultracapacitors: comparison of electrochemical properties of sol‐gel‐derived and
electrodeposited manganese dioxide, Journal of the Electrochemical Society 147 (2), 444-450.
[7] L. Yang, L. Huanqiao, Facile synthesis and electrochemical properties of MnO2/carbon
nanotube, Journal of Particuolog (2012), 1-5.
[8] J. Yan, Z. Fan, T. Wei, J. Cheng, B. Shao, K. Wang, L. Song, M. Zhang, Carbon
nanotubes/MnO2 composites synthesized by microwave-assisted method for supercapacitors
with high power and energy densities, Journal of Power Sources 149 (2009), 1202-1207.
[9] H. Wang, C. Peng, H. Yu, J. Yang, Facile synthesis of MnO2/CNT nanocomposite and its
electrochemical performance for supercapacitors, Journal of Materials Science and Enginering
B. 176 (2011), 1073-1078.
[10] A.L.M. Reddy, M.M. Shaijumon, S.R. Gowda, P.M. Ajayan, Multisegmented Au-
MnO2/carbon nanotubes hybrids coaxial arrays for high-power supercapacitors applications, J.
Phys. Chem. C. 114C (2009), 658-663.
[11] V. Subramanian, H. Zhu, B. Wei, Synthesis and electrochemical characterizations of
amorphous manganese oxide and single walled carbon nanotube composites as supercapacitor
electrode materials, Electrochemistry Communications 8 (2006), 827–832.
[12] S. Suzuki, Synthesis and aplications of carbon nanotubes and their composites, Croatia: Intech
Open, 2013.
Materials Science Forum Vol. 827 117
[13] Y. Zhang, G. Li, Y. Lv, L. Wang, A. Zhang, Y. Song, B. Huang, Electrochemical investigation
of MnO2 electrode material for supercapacitors, International Journal of Hydrogen Energy 36
(2011) 11760-11766.
[14] X. Zang, X. Sun, H. Zhang, D. Zhang, Y. Ma, Microwave-assisted reflux rapid synthesis of
MnO2 nanostructures and their application in supercapacitors, Journal of Electrochimica Acta
87 (2012) 637-644.
[15] D.Z.W. Tan, H. Cheng, S.T. Nguyen, H.M. Duong, Controlled synthesis of MnO2/CNT
nanocomposites for supercapacitor applications, Materials Technology: Advanced Functional
Materials 29 No. 2A (2014), A107-A109.
118 Functional Properties of Modern Materials
AC-MnO2-CNT composites forelectrodes of electrochemical
by Agus Subagio
Submission date: 12-Nov-2019 06:41PM (UTC+0700)Submission ID: 1212178494File name: AC-MnO2-CNT_composites_for_electrodes_of_electrochemical.pdf (5M)Word count: 2473Character count: 13859
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AC-MnO2-CNT composites for electrodes of electrochemicalORIGINALITY REPORT
PRIMARY SOURCES
Wang, Hongjuan, Cheng Peng, Jiadao Zheng,Feng Peng, and Hao Yu. "Design, synthesis andthe electrochemical performance ofMnO2/C@CNT as supercapacitor material",Materials Research Bulletin, 2013.Publication
R Nandhini, P.A. Mini, B. Avinash, S.V. Nair,K.R.V. Subramanian. "Supercapacitorelectrodes using nanoscale activated carbonfrom graphite by ball milling", Materials Letters,2012Publication
Yong Zhang, Guang-yin Li, Yan Lv, Li-zhenWang, Ai-qin Zhang, Yan-hua Song, Bei-liHuang. "Electrochemical investigation of MnO2electrode material for supercapacitors",International Journal of Hydrogen Energy, 2011Publication
Yaohui Wang, Hao Liu, Xueliang Sun, IgorZhitomirsky. "Manganese dioxide–carbonnanotube nanocomposites for electrodes of
5 1%
6 1%
7 1%
8 <1%
9
electrochemical supercapacitors", ScriptaMaterialia, 2009Publication
Shimamoto, Kazushi, Kiyoharu Tadanaga, andMasahiro Tatsumisago. "All-Solid-StateElectrochemical Capacitors Using MnO2/CarbonNanotube Composite Electrode", ElectrochimicaActa, 2013.Publication
Tiwari, J.N.. "Zero-dimensional, one-dimensional, two-dimensional and three-dimensional nanostructured materials foradvanced electrochemical energy devices",Progress in Materials Science, 201205Publication
Singu, B.S., and K.R. Yoon. "Porousmanganese oxide nanospheres forpseudocapacitor applications", Journal of Alloysand Compounds, 2016.Publication
Shadpour Mallakpour, Maryam Madani."Functionalized-MnO 2 /chitosannanocomposites: A promising adsorbent for theremoval of lead ions", Carbohydrate Polymers,2016Publication
Kazemi, Sayed Habib, M.A. Kiani, Mostafa
<1%
10 <1%
11 <1%
12 <1%
13 <1%
Ghaemmaghami, and Hojjat Kazemi. "Nano-architectured MnO2 Electrodeposited on the Cu-decorated Nickel Foam substrate asSupercapacitor Electrode with Excellent ArealCapacitance", Electrochimica Acta, 2016.Publication
Ganguly, Abhijit, Surojit Chattopadhyay, Kuei-Hsien Chen, and Li-Chyong Chen. "Productionand Storage of Energy with One-DimensionalSemiconductor Nanostructures", CriticalReviews in Solid State and Material Sciences,2014.Publication
Yu-Hsuan Liu, Hsing-Cheng Hsi, Kung-Cheh Li,Chia-Hung Hou. "Electrodeposited ManganeseDioxide/Activated Carbon Composite As a High-Performance Electrode Material for CapacitiveDeionization", ACS Sustainable Chemistry &Engineering, 2016Publication
Submitted to Bahcesehir UniversityStudent Paper
Hanlin Cheng, Hai M. Duong, Daniel Jewell."Three dimensional manganese oxide on carbonnanotube hydrogels for asymmetricsupercapacitors", RSC Advances, 2016Publication
14 <1%
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Wang, Jian-Gan, Feiyu Kang, and Bingqing Wei."Engineering of MnO2-based nanocompositesfor high-performance supercapacitors", Progressin Materials Science, 2015.Publication
Jiang, Hao, Liping Yang, Chunzhong Li, ChaoyiYan, Pooi See Lee, and Jan Ma. "High–rateelectrochemical capacitors from highly graphiticcarbon–tipped manganese oxide/mesoporouscarbon/manganese oxide hybrid nanowires",Energy & Environmental Science, 2011.Publication
oa.upm.esInternet Source
ira.lib.polyu.edu.hkInternet Source
Pandolfo, A.G.. "Carbon properties and theirrole in supercapacitors", Journal of PowerSources, 20060619Publication
Submitted to University College LondonStudent Paper
Zengpeng Li, Enhui Liu, Yinhai Zhu, TiantianHu, Zhenyu Luo, Tiantian Liu. "Enhancedsupercapacitive performance of porousactivated carbon derived from polyaniline
21 <1%
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Hao Zhang. "Supercapacitors Based on 3DNanostructured Electrodes", Three-DimensionalNanoarchitectures, 2011Publication
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AC-MnO -CNT composites for electrodes of electrochemicalsupercapacitors (Conference Paper)
, , , , , ,
Department of Physics, Diponegoro University, IndonesiaDepartment of Chemistry, Diponegoro University, IndonesiaCenter of Physics Research, LIPI, Indonesia
AbstractElectrodes for electrochemical supercapacitors were fabricated by doctor blade method of composite of activatedcarbon (AC), MnO and carbon nanotubes (CNTs). The AC-MnO -CNTs composites were synthesized by solutionprocessing method in pH variation of 3, 7 and 11. The composites were characterized by X-ray diffraction, scanningelectron microscopy, transmission electron microscopy and impedance spectroscopy. The XRD pattern shown thecrystalline structure and the SEM image observed that the distribution of CNTs was homogeneous between carbonparticles. The electrodes were fabricated for supercapacitor cells with 316L stainless steel as current collector and 1 MNa SO as electrolyte. An electrochemical characterization was performed by using an electrochemical impedancespectroscopy (EIS) method using a LCR Hi-Tester HIOKI 3522 instrument and the results showed an increase in thevalue of specific capacitance at the ACMnO - CNT on the acidic condition. © (2015) Trans Tech Publications,Switzerland.
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Materials Science ForumVolume 827, 2015, Pages 113-1182nd International Conference on Functional Materials Science, ICFMS 2014; Lombok; Indonesia;12 November 2014 through 13 November 2014; Code 127199
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Subagio, A.a Priyonoa Pardoyob Aswardib Yudianti, R.c Subhan, A.c Taer, E.d
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Engineeringcontrolled terms:
Activated carbon Capacitance Capacitors Carbon nanotubes Characterization
Composite materials Electrochemical impedance spectroscopy Electrodes Electrolytes
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Transmission electron microscopy X ray diffraction Yarn
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Iwama, E., Taberna, P.L., Azais, P., Brégeon, L., Simon, P.
(2012) Journal of Power Sources, 219, pp. 235-239. .doi: 10.1016/j.jpowsour.2012.07.029
Miller, J.R., Simon, P.
(2008) Science, 321 (5889), pp. 651-652. .doi: 10.1126/science.1158736
Kang, Y.J., Kim, B., Chung, H., Kim, W.
(2010) Synthetic Metals, 160 (23-24), pp. 2510-2514. .doi: 10.1016/j.synthmet.2010.09.036
Laha, T., Agarwal, A., McKechnie, T., Seal, S.
(2004) Materials Science and Engineering A, 381 (1-2), pp. 249-258. .doi: 10.1016/j.msea.2004.04.014
2
ISSN: 02555476ISBN: 978-303835547-2CODEN: MSFOESource Type: Book seriesOriginal language: English
DOI: 10.4028/www.scientific.net/MSF.827.113Document Type: Conference PaperVolume Editors: Triyana K.,Nugroho A.A.,Triyana K.,RisdianaSponsors:Publisher: Trans Tech Publications Ltd
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Wang, H., Peng, C., Zheng, J., Peng, F., Yu, H.
(2013) Materials Research Bulletin, 48 (9), pp. 3389-3393. .doi: 10.1016/j.materresbull.2013.05.015
Pang, S.-C., Anderson, M.A., Chapman, T.W.
(2000) Journal of the Electrochemical Society, 147 (2), pp. 444-450. .doi: 10.1149/1.1393216
Yang, L., Huanqiao, L.Facile synthesis and electrochemical properties of MnO /carbon nanotube(2012) Journal of Particuolog, pp. 1-5.
Yan, J., Fan, Z., Wei, T., Cheng, J., Shao, B., Wang, K., Song, L., (...), Zhang, M.
(2009) Journal of Power Sources, 194 (2), pp. 1202-1207. .doi: 10.1016/j.jpowsour.2009.06.006
Wang, H., Peng, C., Peng, F., Yu, H., Yang, J.
(2011) Materials Science and Engineering B: Solid-State Materials for Advanced Technology, 176 (14), pp.1073-1078. .doi: 10.1016/j.mseb.2011.05.043
Reddy, A.L.M., Shaijumon, M.M., Gowda, S.R., Ajayan, P.M.
(2010) Journal of Physical Chemistry C, 114 (1), pp. 658-663. .
doi: 10.1021/jp908739q
Subramanian, V., Zhu, H., Wei, B.
(2006) Electrochemistry Communications, 8 (5), pp. 827-832. .doi: 10.1016/j.elecom.2006.02.027
Suzuki, S.(2013) Synthesis and Aplications of Carbon Nanotubes and Their Composites. .Croatia: Intech Open
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Zhang, Y., Li, G.-Y., Lv, Y., Wang, L.-Z., Zhang, A.-Q., Song, Y.-H., Huang, B.-L.
(2011) International Journal of Hydrogen Energy, 36 (18), pp. 11760-11766. .doi: 10.1016/j.ijhydene.2011.06.020
Zhang, X., Sun, X., Zhang, H., Zhang, D., Ma, Y.
(2013) Electrochimica Acta, 87, pp. 637-644. .doi: 10.1016/j.electacta.2012.10.022
Tan, D.Z.W., Cheng, H., Nguyen, S.T., Duong, H.M.
(2014) Materials Technology, 29 (A2), pp. A107-A113. .
doi: 10.1179/1753555714Y.0000000175
© Copyright 2015 Elsevier B.V., All rights reserved.
13
Electrochemical investigation of MnO electrode material for supercapacitors2
Cited 107 times
View at Publisher
14
Microwave-assisted reflux rapid synthesis of MnO nanostructures and theirapplication in supercapacitors
2
Cited 60 times
View at Publisher
15
Controlled synthesis of MnO /CNT nanocomposites for supercapacitor applications2
Cited 21 timeshttp://www.maneyonline.com/doi/pdfplus/10.1179/1753555714Y.0000000175
View at Publisher
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Materials Science ForumScopus coverage years: from 1984 to 1986, from 1994 to 2019Publisher: Trans Tech Publications LtdISSN: 0255-5476Subject area: Materials Science: General Materials Science Engineering: Mechanical Engineering
Engineering: Mechanics of Materials Physics and Astronomy: Condensed Matter Physics
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▻7,206 Documents
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Category Year QuartileCondensed Matter Physics 1999 Q3Condensed Matter Physics 2000 Q3Condensed Matter Physics 2001 Q3Condensed Matter Physics 2002 Q3
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The SJR is a size-independent prestige indicator thatranks journals by their 'average prestige per article'. It isbased on the idea that 'all citations are not createdequal'. SJR is a measure of scienti�c in�uence ofjournals that accounts for both the number of citationsreceived by a journal and the importance or prestige ofthe journals where such citations come from Itmeasures the scienti�c in�uence of the average articlein a journal it expresses how central to the global
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Cites per document Year ValueCites / Doc. (4 years) 1999 0.555Cites / Doc. (4 years) 2000 0.529Cites / Doc. (4 years) 2001 0.528Cites / Doc. (4 years) 2002 0.533Cites / Doc. (4 years) 2003 0.564Cites / Doc. (4 years) 2004 0.561Cites / Doc. (4 years) 2005 0.547Cites / Doc. (4 years) 2006 0.466Cites / Doc. (4 years) 2007 0.397Cites / Doc. (4 years) 2008 0.368
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Evolution of the total number of citations and journal'sself-citations received by a journal's publisheddocuments during the three previous years.Journal Self-citation is de�ned as the number of citationfrom a journal citing article to articles published by thesame journal.
Cites Year ValueS lf Cit 1999 219
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Year International Collaboration1999 22.242000 19 58
Citable documents Non-citable documents
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1999 2002 2005 2008 2011 2014 2017
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0.225
0.3
0.375
0.45
0.525
0.6
0.675
0.75
1999 2002 2005 2008 2011 2014 2017
0
2k
4k
1999 2002 2005 2008 2011 2014 2017
0.2
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0.6
0.8
1999 2002 2005 2008 2011 2014 2017
7
14
21
28
1999 2002 2005 2008 2011 2014 2017
0
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1999 2002 2005 2008 2011 2014 2017
0
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2nd International Conference on Functional Materials Science 2014 The Development of Advanced Research on Materials Science in Indonesia
November 12-13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Organized by Universitas Padjadjaran, Universitas Gadjah Mada
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran
Sumedang, 45363 INDONESIA, Telp./Fax.: +62 22 7796014, E
INVITATION LETTER
To Agus Subagio
On behalf of the organizing committee of 2
Science 2014 (ICFMS 2014), we would like to invite you to
held in Lombok, Indonesia on November 12
We are pleased to confirm that your paper entitled
electrodes of electrochemical supercapacitors
ICFMS 2014.
Please refer to Conference Program
presentation.
All presented and accepted manuscripts from the ICFMS 2014 will be published in
Science Forum, which is indexed by Elsevier: SCOPUS, Ei Compendex (CPX), Cambridge
Scientific Abstracts (CSA), Chemical Abstracts (CA), Google and Google Scholar, I
CPCI, Web of Science), Institut
uploading your manuscript will be sent to your e
We are looking forward to seeing you in Lombok
Best Regard,
Dr. Risdiana, M. Eng.
Chairman of Organizing Committee
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Universitas Gadjah Mada, Institut Teknologi Bandung, Institut Teknologi Sepuluh Nopember
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran, Jl. Raya Bandung
ax.: +62 22 7796014, E-mail : icfms2014@gmail.com
INVITATION LETTER
On behalf of the organizing committee of 2nd International Conference on Functional Materials
we would like to invite you to participate in ICFMS 2014, to be
held in Lombok, Indonesia on November 12-13, 2014.
onfirm that your paper entitled: AC-MnO2-CNT composites for
electrodes of electrochemical supercapacitors, has been accepted to be presented in
Conference Program and Presentation Guideline
All presented and accepted manuscripts from the ICFMS 2014 will be published in
, which is indexed by Elsevier: SCOPUS, Ei Compendex (CPX), Cambridge
Scientific Abstracts (CSA), Chemical Abstracts (CA), Google and Google Scholar, I
, Institution of Electrical Engineers (IEE). Your login credentials for
will be sent to your e-mail.
We are looking forward to seeing you in Lombok
Chairman of Organizing Committee
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
Institut Teknologi Sepuluh Nopember, and Universitas Indonesia
Jl. Raya Bandung-Sumedang km. 21 Jatinangor,
International Conference on Functional Materials
participate in ICFMS 2014, to be
CNT composites for
has been accepted to be presented in
Presentation Guideline for preparing your
All presented and accepted manuscripts from the ICFMS 2014 will be published in Material
, which is indexed by Elsevier: SCOPUS, Ei Compendex (CPX), Cambridge
Scientific Abstracts (CSA), Chemical Abstracts (CA), Google and Google Scholar, ISI (ISTP,
ion of Electrical Engineers (IEE). Your login credentials for
2nd International Conference on Functional Materials Science 2014 The Development of Advanced Research on Materials Science in Indonesia
November 12-13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Organized by Universitas Padjadjaran, Universitas Gadjah Mada
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran
Sumedang, 45363 INDONESIA, Telp./Fax.: +62 22 7796014, E
ACCEPTANCE
To Agus Subagio
On behalf of the organizing committee of 2
Science 2014 (ICFMS 2014), we would like to invite you to attend ICFMS 2014, to be held in
Lombok, Indonesia on November 12
We are pleased to confirm that your paper entitled:
electrodes of electrochemical supercapacitors
contributed speaker in the Oral session
Please refer to Conference Program
presentation.
We are looking forward to seeing you in Lombok
Best Regard,
Dr. Risdiana, M. Eng.
Chairman of Organizing Committee
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Universitas Gadjah Mada, Institut Teknologi Bandung, Institut Teknologi Sepuluh Nopember
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran, Jl. Raya Bandung
ax.: +62 22 7796014, E-mail : icfms2014@gmail.com
ACCEPTANCE LETTER
On behalf of the organizing committee of 2nd International Conference on Functional Materials
Science 2014 (ICFMS 2014), we would like to invite you to attend ICFMS 2014, to be held in
Lombok, Indonesia on November 12-13, 2014.
are pleased to confirm that your paper entitled: AC-MnO2-CNT composites for
electrodes of electrochemical supercapacitors, has been accepted to be presented as a
session.
Conference Program and Presentation Guideline
We are looking forward to seeing you in Lombok
Chairman of Organizing Committee
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
Institut Teknologi Sepuluh Nopember, and Universitas Indonesia
Jl. Raya Bandung-Sumedang km. 21 Jatinangor,
International Conference on Functional Materials
Science 2014 (ICFMS 2014), we would like to invite you to attend ICFMS 2014, to be held in
CNT composites for
has been accepted to be presented as a
Presentation Guideline for preparing your
2nd International Conference on Functional Materials Science 2014 The Development of Advanced Research on Materials Science in Indonesia
November 12-13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Organized by Universitas Padjadjaran, Universitas Gadjah Mada
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran
Sumedang, 45363 INDONESIA, Telp./Fax.: +62 22 7796014, E
Important Information
� Please prepare your full paper in strict accordance with the camera ready format by
downloading the TEMPLATE OF FULL PAPER
abstract and full paper preparation
(http://situs.opi.lipi.go.id/icfms2014/
� There is no different in invitation letter
and POSTER presentation.
� Duration of presentation in Oral S
discussion. The following facilities will be provided digital projector and laptops with
Windows OS and Microsoft Office Power Point 2010 (we prefer presentations on CD
or USB flash memory)
� Presentation in Poster session
3 minutes and second is poster session in 90 minutes.
(layout: portrait). The poster board will be full white board. Authors need to be present
at their posters for discussion with attendees during the session
� Registration Fees:
Participants/Delegates
International With Paper
International Without Paper
International Extra One Paper
Local With Paper
Local Without Paper
Local Extra One Paper
Accompanying Person
Note: *) Extra page: USD 30 (IDR 300,000) per page
**) USD=United State Dollar, IDR: Indonesian Rupiah
Payment Entitlements
• Participants/delegates are charged based on their institution/affiliation not
nationality of first author.
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Universitas Gadjah Mada, Institut Teknologi Bandung, Institut Teknologi Sepuluh Nopember
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran, Jl. Raya Bandung
ax.: +62 22 7796014, E-mail : icfms2014@gmail.com
Please prepare your full paper in strict accordance with the camera ready format by
TEMPLATE OF FULL PAPER from “Proceeding - Instructions for
abstract and full paper preparation” in conference web
http://situs.opi.lipi.go.id/icfms2014/)
invitation letter, certificate and publication between ORAL
Oral Session is 15 minutes including 5 minutes for
The following facilities will be provided digital projector and laptops with
Windows OS and Microsoft Office Power Point 2010 (we prefer presentations on CD
Poster session is divided into 2 activities. First is short
3 minutes and second is poster session in 90 minutes. The poster size is A1 size
). The poster board will be full white board. Authors need to be present
at their posters for discussion with attendees during the session.
Early Bird Rate
Before September 20, 2014 September 20, 2014 on wards
USD 300
USD 75
USD 200
IDR 1,500,000
IDR 750,000
IDR 1,000,000
USD 75
*) Extra page: USD 30 (IDR 300,000) per page
**) USD=United State Dollar, IDR: Indonesian Rupiah
Participants/delegates are charged based on their institution/affiliation not
nationality of first author.
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
Institut Teknologi Sepuluh Nopember, and Universitas Indonesia
Jl. Raya Bandung-Sumedang km. 21 Jatinangor,
Please prepare your full paper in strict accordance with the camera ready format by
Instructions for
between ORAL
5 minutes for
The following facilities will be provided digital projector and laptops with
Windows OS and Microsoft Office Power Point 2010 (we prefer presentations on CD
is divided into 2 activities. First is short presentation in
The poster size is A1 size
). The poster board will be full white board. Authors need to be present
Normal Rate
September 20, 2014 on wards
USD 350
USD 75
USD 200
IDR 2,000,000
IDR 750,000
IDR 1,000,000
USD 75
Participants/delegates are charged based on their institution/affiliation not
2nd International Conference on Functional Materials Science 2014 The Development of Advanced Research on Materials Science in Indonesia
November 12-13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Organized by Universitas Padjadjaran, Universitas Gadjah Mada
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran
Sumedang, 45363 INDONESIA, Telp./Fax.: +62 22 7796014, E
• Cancellations are not allowed,
• Extra one paper is only applicable for the same first author.
• The Registration Fee should be excluded the transfer fee and bank charges.
Bank transfer fee/charge should be paid by the participants.
• Presenters who do not pay in full by
the schedule and their abstract will not be printed in the Program and Abstract
Book.
• Registration fee includes seminar materials, banquet, lunch, morning and
afternoon teas, attending all technica
Conference Series: Materials Science and Engineering (MSE).
• At least one author for each accepted full paper must register.
Method of Payment
Payment can be made by Bank Transfer to the following bank account.
• Account Name : Lusi Safriani
• Account Number : 0022950297
• Swift code : BNINIDJA
• Bank Name : BNI UNPAD BANDUNG
Please send a confirmation of payment (copy proof of payment) to
lusi.safriani@phys.unpad.ac.id
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
13, 2014, Lombok, Indonesia
http://situs.opi.lipi.go.id/icfms2014/
Universitas Gadjah Mada, Institut Teknologi Bandung, Institut Teknologi Sepuluh Nopember
Contact : Department of Physics, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran, Jl. Raya Bandung
ax.: +62 22 7796014, E-mail : icfms2014@gmail.com
Cancellations are not allowed, and return of payment is not possible.
Extra one paper is only applicable for the same first author.
The Registration Fee should be excluded the transfer fee and bank charges.
Bank transfer fee/charge should be paid by the participants.
not pay in full by 12 October 2014 will not be included in
the schedule and their abstract will not be printed in the Program and Abstract
Registration fee includes seminar materials, banquet, lunch, morning and
afternoon teas, attending all technical sessions and publication in IOP
Conference Series: Materials Science and Engineering (MSE).
At least one author for each accepted full paper must register.
Payment can be made by Bank Transfer to the following bank account.
Lusi Safriani
0022950297
BNINIDJA
BNI UNPAD BANDUNG
Please send a confirmation of payment (copy proof of payment) to
lusi.safriani@phys.unpad.ac.id
International Conference on Functional Materials Science 2014 Development of Advanced Research on Materials Science in Indonesia
Institut Teknologi Sepuluh Nopember, and Universitas Indonesia
Jl. Raya Bandung-Sumedang km. 21 Jatinangor,
and return of payment is not possible.
The Registration Fee should be excluded the transfer fee and bank charges.
will not be included in
the schedule and their abstract will not be printed in the Program and Abstract
Registration fee includes seminar materials, banquet, lunch, morning and
l sessions and publication in IOP
Conference Series: Materials Science and Engineering (MSE).
At least one author for each accepted full paper must register.
Payment can be made by Bank Transfer to the following bank account.
Program
11 November 2014
15.00 – 18.00 Registration
1st day – 12 November 2014
Time Agenda
07.00 – 07.55 Registration
07.55 – 09.00 First Parallel Session
Time Room A Room B Room C Room D
07.55 – 08.00 Welcoming
address
Welcoming
address
Welcoming
address
Welcoming
address
08.00 - 08.15 FMM-A-1 FMM-B-1 FMM-C-1 FMM-D-1
08.15 - 08.30 FMM-A-2 FMM-B-2 FMM-C-2 FMM-D-2
08.30 - 08.45 FMM-A-3 FMM-B-3 FMM-C-3 FMM-D-3
08.45 - 09.00 FMM-A-4 FMM-B-4 FMM-C-4 FMM-D-4
09.00 – 09.10 Coffee Break
09.10 – 09.20 Opening Ceremony of ICFMS 2014
09.20 – 10.00 Invited Speaker I (I. Watanabe)
10.00 – 10.40 Invited Speaker II (Y. Koike)
10.40 – 11.20 Invited Speaker III (Y. Furukawa)
11.20 – 13.00 Photo ICFMS 2014
Lunch Break
13.00 – 15.00 Second Parallel Session
Time Room A Room B Room C Room D
13.00 -13.30 Invited Speaker
IV (Ariando)
Invited
Speaker V (Y.
Nozue)
Invited
Speaker VI
(S. Sulaiman)
Invited
Speaker VII
(H. Taniguchi)
13.30 -14.00 Invited Speaker
VIII (Y. Kohori)
FMN-B-1 Invited
Speaker IX
(Rahmat H.)
Invited
Speaker X (N.
Kuwano) FMN-B-2
14.00 -14.15 FMN-A-1 FMN-B-3 FMN-C-1 FMN-D-1
14.15 -14.30 FMN-A-2 FMN-B-4 FMN-C-2 FMN-D-2
14.30 -14.45 FMN-A-3 FMN-B-5 FMN-C-3 FMN-D-3
14.45 -15.00 FMN-A-4 FMN-B-6 FMN-C-4 FMN-D-4
Time Agenda
15.00-16.30 Poster Session
E F G H I J K
FMN-E-1 FMN-F-1 FMN-G-1 FMN-H-1 FMN-I-1 FMN-J-1 FMN-K-1
FMN-E-2 FMN-F-2 FMN-G-2 FMN-H-2 FMN-I-2 FMN-J-2 FMN-K-2
FMN-E-3 FMN-F-3 FMN-G-3 FMN-H-3 FMN-I-3 FMN-J-3 FMN-K-3
FMN-E-4 FMN-F-4 FMN-G-4 FMN-H-4 FMN-I-4 FMN-J-4 FMN-K-4
FMN-E-5 FMN-F-5 FMN-G-5 FMN-H-5 FMN-I-5 FMN-J-5 FMN-K-5
FMN-E-6 FMN-F-6 FMN-G-6 FMN-H-6 FMN-I-6 FMN-J-6 FMN-K-6
FMN-E-7 FMN-F-7 FMN-G-7 FMN-H-7 FMN-I-7 FMN-J-7 FMN-K-7
FMN-E-8 FMN-F-8 FMN-G-8 FMN-H-8 FMN-I-8 FMN-J-8 FMN-K-8
FMN-E-9 FMN-F-9 FMN-G-9 FMN-H-9 FMN-I-9 FMN-J-9 FMN-K-9
FMN-E-10 FMN-F-10 FMN-G-10 FMN-H-10 FMN-I-10 FMN-J-10 FMN-K-10
16.30 – 17.10 Invited Speaker XI (T. Adachi)
17.10 – 17.50 Invited Speaker XII (A. Rusydi)
17.50 – 18.00 Closing
19.00 – 21.00 Dinner
2nd
day – 13 November 2014
08.00 - 08.15 Summary of ICFMS 2014 for Magnetic Materials (Y. Koike)
08.15 - 08.30 Summary of ICFMS 2014 for Functional Materials (Y. Furukawa)
08.30 - 08.45 Summary of ICFMS 2014 for Computation Materials (S. Sulaiman)
08.45 - 09.00 Summary of ICFMS 2014 for Research Collaboration (I. Watanabe)
09.00 - 09.15 Summary of ICFMS 2014 for Next ICFMS 2016 (Darminto)
09.15 - 09.30 Closing Ceremony
09.30 - 17.00 Lombok Field Trip (Optional)
Invited Speakers
1. Isao Watanabe (RIKEN)
2. Yoji Koike (Tohoku University, Japan)
3. Yukio Furukawa (Waseda University, Japan)
4. Ariando (National University of Singapore, Singapore)
5. Yasuo Nozue (Osaka University, Japan)
6. Shukri Sulaiman (Universiti Sains Malaysia, Malaysia)
7. Hiromi Taniguchi (Saitama University, Japan)
8. Yoh Kohori (Chiba University,Japan)
9. Rahmat Hidayat (Bandung Institute of Technology)
10. Noriyuki Kuwano (Kyushu University)
11. Tadashi Adachi (Sophia University, Japan)
12. Andrivo Rusydi (National University of Singapore, Singapore)
List of Contributed Speakers
No. Name Title Code
1
Anne Zulfia,
Salahuddin J and
Ahmad Hafeizh E
Characterization of Al-Si-Mg/Al2O3Nano
Composite Produced by Stir Casting Method FMM-A-1
2 Aris Doyan and
Susilawati
Dielectric and Conductivity Properties of
Polyacrilamide Gels Material FMM-A-2
3
Norman Syakir,
Annisa Aprillia,
Fitrilawati and
Sagung Oka
Aditia
Tunning the Emission Color Coordinate of
Comersial White-Light LED Use the Poly-
TMSPMA Doped Dye DCM
FMM-A-3
4
R. Tasomara, T.
Kawamata, Y.
Matsuoka,
H.Sudo, K.
Naruse, M. Ohno,
H. Nagasawa, Y.
Hagiya, T. Sasaki,
Risdiana and Y.
Koike
Study of Thermal Conductivity due to Spins in
the One-Dimensional Spin System AFeX3
(A=Rb, Cs; X=Cl, Br)
FMM-A-4
5
G. Korotcenkov,
V. Brinzari, S.H.
Han, L.B. Gulina,
V.P. Tolstoy and
B.K. Cho
SnO2 Films Decorated by Au Clusters and Their
Gas Sensing Properties FMN-A-1
6
Kenji Takashima
and Yukio
Furukawa
Infrared Study on Electric Field Induced
Structural Changes in Ferroelectric Vinylidene
Fluoride/Trifluoroethylene Copolymer Thin
Films
FMN-A-2
7
A. Bahtiar, L.
Safriani, A.
Aprilia, Risdiana,
Harsojo,
Triwikantoro,
Darminto, A.
Agung Nugroho,
H. Guo, I.
Kawasaki and I.
Watanabe
Study of Charge CarrierDynamics of
P3HT:PCBM Blend for Active Material
SolarCell Using Muon Spin Relaxation
FMN-A-3
8 Alfred Albert and
Rosari Saleh
Synthesis of ZnO/TiO2 and ZnO/TiO2/CuO
Nanocomposite Using Sol-gel Method for The
Photocatalytic Degradation of Methylene Blue
Under UV and Visible Light Irradiation
FMN-A-4
9
Shofianina
Jalaludin, Sarah
Arifiyanti and
Rosari Saleh
Magnetic Hybrid Fe3O4 / CuO / TiO2Nano
Particles: Synthesize, Characterization and
Photocatalytic Activity
FMM-B-1
10
Yofentina Iriani,
Retno Maharsi and
Anif Jamaluddin
Characterization of BaxSr1-xTiO3 Applied as
Dielectric Material FMM-B-2
11
Iis Nurhasanah,
Aula Fitra Efendi,
Heri Sutanto and
Priyono
Structure and Growth of 5 mol % Zn-doped
CeO2Nanosphere Synthesized by Simple
Precipitation Process
FMM-B-3
12
Eni Sugiarti,
Kemas A. Zaini,
Yongming Wang,
Naoyuki
Hashimoto, Somei
Ohnuki and
Shigenari Hayashi
Effects of Oxidation Temperature on the Oxide
Scale Formation of NiCoCrAl Coatings on Low
Carbon Steel
FMM-B-4
13
Fahmi Astuti,
Malik Anjelh
Baqiya and
Darminto
Effect of Pb on Superconducting and Electrical
Properties of Bi2Sr2CaCu2O8+σNanopowders FMN-B-1
14
Asep Ridwan
Setiawan,Marsetio
Noorprajuda,
Aditianto Ramelan
and Rochim
Suratman
Preparation of Zn-ZrO2Nanocomposite Coating
by DC and Pulsed Current Electrodeposition
Technique with Low Current Density
FMN-B-2
15
Ariska Rinda
Adityarini, Eka
Yoga Ramadhan,
Endah Retno
Dyartanti and
Agus Purwanto
Effect of LiFePO4 Cathode Composite’s
Thickness on Lithium Battery Performance FMN-B-3
16
Annisa
Noorhidayati,
Raynaldi Philipus,
Nadia F. Djaja and
Rosari Saleh
Comparative Study of Photocatalytic Activity of
Ni-doped ZnO and Zeolite Supported Ni-doped
ZnO Prepared by Co-precipitation Method
FMN-B-4
17
Ahmad Taufiq,
Sunaryono, Edy
Giri Rachman
Putra, Suminar
Pratapa and
Darminto
Nano-structural studies on Fe3O4 particles
dispersing in a magnetic fluid using X-ray
diffractometry and small-angle neutron
scattering
FMN-B-5
18
Subagio A,
Priyono, Pardoyo,
Aswardi, Yudianti
R., Subhan A. and
Taer E
AC-MnO2-CNT Composites for Electrodes of
Electrochemical Supercapacitors FMN-B-6
19
Ananda Yogi
Nugraheni, M.
Nasrullah, Fandi
Angga Prasetya,
Fahmi Astuti and
Darminto
Study on Phase, Molecular Bonding, and
Bandgap of Reduced Graphene Oxide Prepared
by Heating Coconut Shell
FMM-C-1
20
Decky J. Indrani,
E. Budianto and B.
Soegijono
Compression Strength and Degradation Ability
of Hydroxyapatite/Alginate Composite
Scaffolds
FMM-C-2
21
Is Fatimah,
Dwiarso
Rubiyanto and
Thorikul Huda
Preparationand Characterizationof Ni/Zr-
Saponite as Catalyst in Catalytic Hydrogen
Transfer Reactionof Isopulegol
FMM-C-3
22
Eny Kusrini,
Gefin Yesya,
Nyoman
Suwartha, Cindy
Rianti Priadi, and
Nofrijon Sofyan
Characteristic of Equilibrium and Kinetic
Studies for Adsorption of Fluoride Ions
onChitosan-Praseodymium
FMM-C-4
23
A.F. Rozlan,
S.Sulaiman, M.I.
Mohamed-Ibrahim
and I. Watanabe
Electronic Structure of Muonated La2CuO4 FMN-C-1
24
Cukup Mulyana,
Adhitya Rusel
Syah and Nendi
Suhendi
Simulation Analysis of Damage Mechanism on
Material SA213-T22 Ferritic Type Caused of
Temperature, Stress and Loading Using Finite
Element Method Program
FMN-C-2
25
Melchor J.
Potestas, Arnold
C. Alguno,
Reynaldo M.
Vequizo, Bianca
Rae B. Sambo and
Majvell Kay G.
Odarve
Optical property enhancement of silica-modified
polyaniline grown on glass substrate via
incorporation of zinc sulfide into the polymer
matrix
FMN-C-3
26
Masruroh,
D.J.D.H Djoko,
Lalu A. Didik,
Eka Rachmawati,
Fadli Robiandi,
Masdiana Pagaga
and S.P Sakti
Effect of Solvents on Polystyrene Morphology
and the Deposited Zinc Phthalocyanine (ZnPc)
as Immobilisation Matrix for QCM Sensor
FMN-C-4
27
Abdul Halim
Daulay, Decky
Jusiana Indrani,
Muhammad Rifqi
Aufan, Aditianto
Ramelan,
Mardjono
Siswosuwarno and
Bambang
Sunendar
Purwasasmita
Bone Scaffold Based on Biopolymer/Carbonate
Apatite by Freeze Drying Method: Synthesis,
Characterization, and In Vitro Cytotoxicity
FMM-D-1
28
Mochamad
Chalid, Evana
Yuanita and
Juniko Pratama
Study of Alkalization to the Crystallinity and the
Thermal Behavior of Arenga Pinnata “Ijuk”
Fibers-based Poly(lactic acid) (PLA)
Biocomposite
FMM-D-2
29 E. Taer, R. Taslim
and M. Deraman
Preparations and Characterizations of Activated
Carbon Monolith from Rubber Wood and its
Affect on Supercapacitor Performances
FMM-D-3
30
Harsojo, Anna
Layla Salfarina
and Harini Sosiati
Fabricating Nano Fiber Polyvinylalcohol with
Evenly Distributed Nano Silver FMM-D-4
31 Rusinov P.О. and
Blednova Zh. M
The Structure and Phase Formation of the
Surface Layers Formed TiNiCu High Flame
Spraying
FMN-D-1
32
Nadia Febiana
Djaja and Rosari
Saleh
Comparative study on photocatalytic
performance of (Fe,La) and (Fe,Ce)-codoped
ZnO nanoparticles
FMN-D-2
33
Heri Sutanto, Iis
Nurhasanah and
Eko Hidayanto
Deposition of Ag 2~6 mol%-doped ZnO
Photocatalyst Thin Films By Thermal Spray
Coating Method for Degradation E. coli Bacteria
FMN-D-3
34
Bidhari Pidhatika
and Rupert
Konradi
Peptidomimetic ultrathin films for biomaterial
applications FMN-D-4
35 Agus Haryono and
Sri Budi Harmami
Synthesis of Iron Oxide Nanoparticles Coated
with Dextrin and Their Structure FMN-E-1
36
Rani Cahyani
Fajaryatun,
Therecia Wulan
Sukardi, Arif
Jumari and Agus
Purwanto
Enhancement of Lithium Battery Performance
by Thickness Anode Film Modification FMN-E-2
37
Tika Paramitha,
Tifa Paramitha
and Agus
Purwanto
Evaluation of Sintering and Soaking Methods on
the Dye-sensitized solar cell Performance FMN-E-3
38
Agus Sukarto
Wismogroho,
Wahyu Bambang
Widayatno, Toto
Sudiro and Didik
Aryanto
The Orientation Study of BaSr - Hexaferrite
Particles by Parallel Magnetic Field Press FMN-E-4
39
Aniek S
Handayani, Is
Sulistyati P and
M.Chalid
Synthesis of Amylopectin Macro-initiator for
Graft Copolymerization of Amylopectin-g-
Poly(Methyl Methacrylate) by ATRP (Atom
Transfer Radical Polymerization)
FMN-E-5
40
Annisa
Noorhidayati, Mia
P. Rahmawati and
Rosari Saleh
Photocatalytic Activity of Plain ZnO compared
to Zeolite Supported Transition Metal-(Co2+
and
Cr2+
) doped ZnO
FMN-E-6
41
Ardiansyah
Taufik, Iqriah
Kalim and Rosari
Saleh
Preparation, characterization and photocatalytic
activity of multifunctional Fe3O4/ ZnO / CuO
hybrid nanoparticles
FMN-E-7
42
Asep Ridwan
Setiawan, Hugo
Fathur Rahman
Erawan, Rochim
Suratman and M.
Nasir
Synthesis of Cobalt Oxide Layer Via
Electrospinning of PEO/Cobalt Acetate Solution
on AISI 430 Ferritic Steels Substrate
FMN-E-8
43
Aula Fitra Efendi
and Iis
Nurhasanah
Synthesis of Zn-doped CeO2 Nanopowders
Assisted by Ultrasound Irradiation FMN-E-9
44
I Made Joni, Dede
Nurjaeni,
Darmawan
Hidayat, Tuti
Aryati Demen,
Dwindra W.
Maulana and
Camellia
Panatarani
Development of Beads Mill with High
Separation Efficiency Performance FMN-E-10
45 Aventi
Comparison Between Fire Resistance
Lightweight Brick And Fire Resistance Red
Brick
FMN-F-1
46
A. Bahtiar, Siti
Halimah
Tusaddiah, Wendy
Paramandhita S,
Mustikasari, Lusi
Safriani, Mariah
Kartawidjaja, Kei
Kanazawa, Ippei
Enokida, Yukio
Furukawa and Isao
Watanabe
Optical, Structural and Morphological Properties
of Ternary Thin Film Blend of
P3HT:PCBM:ZnO Nanoparticles
FMN-F-2
47
Cukup Mulyana,
Aswad Hi Saad,
Otong Nurhilal
and Mariah K
Failure Analysis on Disimilar Metal Weld
(DMW) of Ferritic SA-213 T22 and Austenitic
SA-213 TP 304H
FMN-F-3
48
Cukup Mulyana,
Sri Suryaningsih
and Mariah K
Disimilar Metal Weld Joint Power Plant FMN-F-4
49
D.J.Djoko
H.Santjojo,
Masruroh and
Fadli Robiandi
Functionality of ZnPc thin film deposited on
polystyrene interlayer for immobilization of
Biomolecules in QCM based biosensor
FMN-F-5
50
D. Dahlan, N.
Sartika, Astuti and
E. Taer
Effect of TiO2 on Duck Eggshell Membrane as
Separators in Supercapacitor Applications FMN-F-6
51
Bambang
Prihandoko, Tia
Rahmiati and
Anne Zulfia
Characteristic of Ceramic Composite Li4Ti5O12
under Influence of Li2O FMN-F-7
52
Indri Badria
Adilina, Silvester
Tursiloadi, and
Shogo Shimazu
Development of Bentonite Clay
Nanocomposites as Selective Catalysts for the
Synthesis of Vanillin from Clove Oil
Derivatives
FMN-F-8
53 Susilawati and
Aris Doyan
Synthesis and Characterization of Solid
Composite Polymer FMN-F-9
54
Iwantono, Akrajas
A. Umar, Erman
Taer, Rika Taslim
and Winda
Nurwidya
Zink-oxide (ZnO) Nanorods Prepared by Seed-
Mediated Growth Method as Active Materials
Photoelectrochemical Solar Cell
FMN-F-10
55
Eko Pujiyanto,
Pringgo Widyo
Laksono and
Sagiran
Synthesis and Sintering of Hydroxyapatite-
Zirconia Composites FMN-G-1
56
E. Taer, R.
Taslim, Satri,
Iwantono, B.N.M.
Dolah and M.
Deraman
The Investigations of a Composite Electrodes of
Biomass Based Activated Carbon Mixtured with
Carbon Nanotube Sand Polyaneline for
Supercapacitor Applications
FMN-G-2
57
Fandi Angga
Prasetya, M.
Nasrullah,
Ananda Yogi
Nugraheni, Salim
Mustofa and
Darminto
Analysis of Graphene Phase on Result of Heat
Treatment on Coconut FMN-G-3
58
Fitrilawati,
Norman Syakir,
Annisa Aprilia,
Zhouyang Liu,
Xinliang Feng, K.
Muellen and
Christoph Bubeck
Reduction Kinetic and Stability of Thermally
Reduced Graphene Oxide Thin Films FMN-G-4
59
Fitri Yuli Zulkifli,
Nugroho Adi
Saputro, Basari
and Eko Tjipto
Rahardjo
Left Handed Metamaterial Structure on
Microstrip Antenna FMN-G-5
60
Ghiska
Ramahdita,
Mochammad
Chalid and Lisman
Suryanegara
Potential Effects of Alkali Treatments on
Chemical and Thermal Properties of Various
Natural Cellulosic Fibers
FMN-G-6
61
H. S. Nusa, W.
Astuti, A. S.
Kartasasmita, R.
Virgana, N.
Syakir, A. Bahtiar,
L. Safriani and
Risdiana
Characterization of Optical and Structure
Properties of Polydimethylsiloxanes FMN-G-7
62
H. Sosiati, M.
Muhaimin,
Purwanto, D.A.
Wijayanti,
Harsojo,
Soekrisno and K.
Triyana
Microscopic characterization of cellulose
nanocrystal isolated from sisal fibers FMN-G-8
63
Harsojo, Anita
F.W., and Harini
Sosiati
A Simple Way of Fabricating Nano Fiber PVA
Loaded with Superparamagnetic Fe3O4 FMN-G-9
64
H. Setiadi, A.
Prasetyo, V.
Suendo and A. A.
Nugroho
Phonon Properties of Co:TiO2 single crystal FMN-G-10
65
L. Safriani, T.
Susilawati, S.
Hidayat and I.
Sopian
Fabrication of Photonic Crystal Based on
Colloidal Polystyrene Particles on Flexible
Substrate
FMN-H-1
66 Jul Endawati Durability of Wood Shavel Composites With
Environmental Friendly Based Binder FMN-H-2
67
Lusi Safriani,
Risdiana, Ayi
Bahtiar, Annisa
Aprilia, I.
Kawasaki and Isao
Watanabe
μSR study of charge carrier motion in active
layer P3HT:ZnO:PCBM hybrid solar cells FMN-H-3
68
Mastuki, Darminto
and Malik Anjelh
Baqiya
Explorative synthesis of calcium ferrite Ca-Fe-O
by mixing precipitated CaCO3 from limestone
and iron sand extracted – Fe2O3.H2O
FMN-H-4
69
Mochamad
Chalid, Evana
Yuanita and Dio
Arifin
Study on Mechanical Properties of Recycle
Polypropylene (rPP) -Calcium Carbonate
(CaCO3) Composite
FMN-H-5
70 Nur Afifah and
Rosari Saleh
Photocatalytic Activity of Fe- Doped
ZnO/Montmorillonite Nanocomposite for
Degradation of Malachite Green
FMN-H-6
71 Tjahjanti P.H and
Setyawan E.H
Use Powder of Wood Ulin (Eusideroxylon
Zwageri) for Mixed Materials Builders Head
Bushing
FMN-H-7
72
Ahmad Said, Is
Fatimah, Aprisilia
Risky Wijaya and
Uun Ayyil
Hasanah
Preparation of Rice Straw-based Silica Gel:
Effect of pH on Its Physicochemical Character
and Catalytic Activity
FMN-H-8
73
Risdiana,
D. Suhendar, S.
Pratiwi, T. Saragi,
W. A. Somantri,
S. Harimurty, F.
K. Muharom, S. F.
Winda, R. R.
Sihombing, M. R.
Ramadhan and R.
Tasomara
The Effects of Fe Impurities to the Magnetic
Properties in Electron-doped Superconducting
Cuprates
FMN-H-9
74
Gilang Gumilar,
Brian Yuliarto and
Nugraha
Preparation of SnO2 thin films with surfactants-
assisted via low temperature chemical bath
deposition method and its performance as CO
gas sensor
FMN-H-10
75
Sahrul Hidayat,
Orina Amelia,
Iman Rahayu, and
Fitrilawati
Conduction Properties of PTMSPMA-PEO and
Its Application as Polymer Electrolyte in
LiFePO4 Batteries
FMN-I-1
76 Shirley Savetlana
and Gusri Akhyar
The Effect of Grafit and NBR on the Hardness
of Fly-ash/Phenolic Composite for Brake Lining
Application
FMN-I-2
77
Dieni Mansur, Sri
Fahmiati, Yulianti
Sampora and Agus
Haryono
Synthesis and Characterization of Polystyrene-
Co-Maleic Acid-Cu as Biocide in Marine
Biofouling
FMN-I-3
78
Sunaryono,
Ahmad Taufiq,
Suminar Pratapa,
Zainuri,
Triwikantoro and
Darminto
Magnetic properties of Fe3O4 nanoparticles
synthesized from natural magnetites by
coprecipitation method at room temperature with
various stirring rate
FMN-I-4
79
Togar Saragi, Siti
Nurjannah, Ricca
Novia, Norman
Syakir, Edward
Simanjuntak, Lusi
Safriani, Risdiana
and Ayi Bahtiar
Particle Synthesis of Cobalt Ferrite by utilize
Sol-Gel Method FMN-I-5
80
Toto Sudiro,
Kemas Ahmad
Zaini Thosin,
Didik Aryanto,
Agus Sukarto
Wismogroho and
Kazuya Kurokawa
Fe-Si-Al Alloys Prepared by a Spark Plasma
Sintering Technique FMN-I-6
81
Sarah A. Arifin,
Shofianina
Jalaludin, Nadia F.
Djaja and Rosari
Saleh
The Preparation of Fe3O4/TiO2 and
Fe3O4/TiO2/CuO nanohybrids for
photoreduction of Cr(VI)
FMN-I-7
82
Tuti Susilawati,
Dwika Andjani,
Sri Suryaningsih,
Norman Syakir,
and Fitrilawati
Corrosion Protection of Carbon Steel Pipe Using
Polymer Hybrid with Inhibitor Cerium FMN-I-8
83
Wiendartun,
Risdiana,
Fitrilawati, R. E.
Siregar and Y.
Koike
Influence of Nb2O5 addition on the electrical
properties of Fe2TiO5 ceramics-based NTC
thermistor
FMN-I-9
84 Lydia Anggraini
and Kei Ameyama
Development of Hybrid Ceramics Composite
through Microstructure Refinement FMN-I-10
85
Wijang Wisnu R,
Heru Sukanto, and
Miftahul Anwar
Effect of soaking time in Alkali solution on the
Interfacial Shear Strength
of Cantala Fiber /Recycle HDPE Composites
FMN-J-1
86
Witta Kartika
Restu, Yulianti
Sampora, Yenny
Meliana and Agus
Haryono
Effect of Accelerated Stability Test on
Characteristics of Emulsion
Systems with Chitosan as a Stabilizer
FMN-J-2
87
Wiwik Pudjiastuti,
Arie Listyarini and
Arief Riyanto
Smart Cold System using Phase Change
Materials (PCM’s) to Preserve
The Freshness of Seafood Products
FMN-J-3
88
Yayah Yuliah, Ayi
Bahtiar, Sahrul
Hidayat, Rustam E
Siregar and
Fitrilawati
Fluorescence Spectroscopy Study of PVP-
capped ZnO Nano-particles
as the Electron Acceptor of Organic Solar Cell
Materials Poly(3-
Hexylthiophene-2,5-diyl) (P3HT)
FMN-J-4
89
Decky J Indrani,
Bambang S.
Purwasasmita and
Jojor Simanjuntak
Magnetic Nanoparticles and
Carbonate Apatite/Chitosan/Alginate Composite
Scaffolds
FMN-J-5
90
Yenny Meliana,
Sri Budi
Harmami, Witta
Kartika Restu and
Agus Haryono
Morphology and Structure of Nanoencapsulation
of Centella asiatica and
Zingiber officinale Exctract as The Oral Dosage
of Anticellulite Treatment
FMN-J-6
91
Joko Triwibowo,
Irvan Alamsyah
and Jan Setiawan
Synthesis And Characterization Of Carbon-
coated LiFePO4 With
Various Carbon Sources As Cathode Material
For Lithium Ion Batteries
Through A Solid-state Process
FMN-J-7
92
Joko Triwibowo,
Jan Setiawan,
Raden Ibrahim
Purawiardi and
Bambang
Prihandoko
Study on Carbon-coated LiMn0.7Fe0.3-xNixPO4
(0 < x < 0.15) as Cathode
Material for Lithium Ion Batteries
FMN-J-8
93
Kiagus Dahlan,
Akhiruddin
Maddu, Setia
Utami Dewi, Nur
Aisyah
Nuzulia, Sugandi,
Fitri Afriani and
Jayanti Dwi
Hamdila
Synthesis of Porous Calcium
Phosphate/Alginate Composites Using
Chicken Eggshells as the Calcium Sources for
Bone Tissue Scaffolds
FMN-J-9
94
W. A. Somantri,
S. Pratiwi, D.
Suhendar, M. R.
Ramadhan, N.
Sehendi, T.
Saragi, and
Risdiana
The Study of electron mobility in Electron-
doped Superconductor
Eu1.85+yCe0.15-yCu1-yFeyO4+a-d
FMN-J-10
95
T. P. Negara, L.
Yuliawati, A. D.
Garnadi, S.
Nurdiati and H.
Alatas
Effect of Filling-Factor on Transmittance of a
Dielectric Slab Waveguide with Metallic
Grating
FMN-K-1
96
Sidik Permana,
Novitrian, Zaki
Suud, Ismail and
Mitsutoshi Suzuki
Plutonium Production Evaluation of
Transuranium loading in Fast Breeder Reactor
(FBR)
FMN-K-2
97
Sidik Permana,
Novitrian, Zaki
Suud, Ismail and
Mitsutoshi Suzuki
Heavy Nuclide Production Analysis For
Different Burnup and
Cooling Time of Light Water Reactor (LWR)
FMN-K-3
98
Moh. Toifur,
Kusendratno,
Rahmadhani and
Riswanto
Performance of Several Wire Configuration
Bridge (Wcb) Transducers
to Handle The Low Temperature Sensor
FMN-K-4
99
Riesca Ayu
Kusuma
Wardhani, Lia
Asri, Muhamad
Nasir, Ida Suhadi
and Bambang
Sunendar
Electrospun Chitosan-Polyethylene Oxide
Nanofiber Containing
Botanical Collagen for Wound Dressing
Application
FMN-K-5
100
Ferli S. Irwansyah,
Dani G. Syarif,
Atiek R.
Noviyanti and
Sahrul Hidayat
Synthesis and Characterization
Composite La9,33Si6O26 (LSO) - Zr0.85Y0.15O1.925
(YSZ)
as Electrolyte Solid Oxide Fuel Cell
FMN-K-6
101
M. A. Saleh, H.
Kuhn, D. Onggo,
A. A. Nugroho,
and P.H.M. Van
Loosdrecht
UV/Vis Spectroscopy of
(C6H5CH2CH2NH3)2MnCl4 single crystal FMN-K-7
102
Kuwat Triyana,
Elly Indahwati,
Harsojo, Chotimah
and Kamsul
Abraha
Electrospun Gelatin Nanofibers Doped with
Lithium Carbonate and Its
Compatibility as Electrolyte Polymer in Lithium
Ion Battery
FMN-K-8
103
Chotimah, Kuwat
Triyana and
Indriana Kartini
Effect of Annealing Temperature on
Morphology and Composition of
Electrospun PEDOT:PSS Nanofibers
FMN-K-9
ISSN: 1662-9752
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University Politehnica of Bucharest, Faculty of Materials Science and Engineering; 313 Splaiul Independentei,Bucharest, 060042, Romania;
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Lund University, Department of Solid State Physics; Box 118, Lund, 221 00, Sweden;
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Volume 827doi: https://doi.org/10.4028/www.scienti�c.net/MSF.827
Search
Paper Title
Functional Properties of Modern Materials
Papers
Book
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AC-MnO -CNT Composites for Electrodes of ElectrochemicalSupercapacitorsAuthors: Agus Subagio, Priyono, Pardoyo, Aswardi, R. Yudianti, A.Subhan, E. TaerAbstract: Electrodes for electrochemical supercapacitors were fabricatedby doctor blade method of composite of activated carbon (AC), MnO and...more
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Optical, Structural and Morphological Properties of TernaryThin Film Blend of P3HT:PCBM:ZnO Nanoparticles
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Authors: Ayi Bahtiar, Siti Halimah Tusaddiah, Wendy Paramandhita S.Mustikasari, Lusi Safriani, Mariah Kartawidjaja, Kei Kanazawa, IppeiEnokida, Yukio Furukawa, Isao WatanabeAbstract: Ternary blend �lm of conjugated polymer, fullerene andinorganic nanoparticles has intensively studied as active material for high...more
Conduction Properties of PTMSPMA-PEO and its Application asPolymer Electrolyte in LiFePO BatteriesAuthors: Sahrul Hidayat, Orina Amelia, Iman Rahayu, FitrilawatiAbstract: The conduction properties of polymer composite PTMSPMA-PEOas electrolyte in lithium-ion batteries has been investigated. The gel...more
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125
μSR Study of Charge Carrier Motion in Active LayerP3HT:ZnO:PCBM Hybrid Solar CellsAuthors: Lusi Safriani, Risdiana, Ayi Bahtiar, Annisa Aprilia, I. Kawasaki,Isao WatanabeAbstract: The so-called hybrid (organic-inorganic) solar cell has beendeveloped due to the combining advantage between organic material...more
131
The E�ect of Sintering and Soaking Temperature on the Dye-Sensitized Solar Cell PerformanceAuthors: Tika Paramitha, Tifa Paramitha, Agus PurwantoAbstract: Dye-sensitized solar cell (DSSC) is a photoelectrochemical solarcell that is able to convert solar energy into electrical energy. Sintering of...more
135
Study on Carbon-Coated LiMn Fe Ni PO (0 ≤ x ≤ 0.15) asCathode Material for Lithium Ion BatteriesAuthors: Joko Triwibowo, Jan Setiawan, Raden Ibrahim Purawiardi,Bambang PrihandokoAbstract: Phosphate-based cathode material, LMP, with olivine crystalstructure is generally known as cathode material with low electronic...more
0.7 0.3-x x 4 140
E�ect of LiFePO Cathode Thickness on Lithium BatteryPerformanceAuthors: Ariska Rinda Adityarini, Eka Yoga Ramadhan, Endah RetnoDyartanti, Agus Purwanto
4 146
Showing 21 to 30 of 67 Paper Titles
Abstract: Lithium ion battery is composed of three main parts, i.e.cathode, anode and electrolyte. In this work, we investigated the e�ect of...more
E�ect of TiO on Duck Eggshell Membrane as Separators inSupercapacitor ApplicationsAuthors: D. Dahlan, N. Sartika, Astuti, E.L. Namigo, E. TaerAbstract: A study concerning the e�ect of TiO on duck eggshellmembrane as separator in supercapacitor applications. Concentration of...more
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151
Enhancement of Lithium Battery Performance by ThicknessAnode Film Modi�cationAuthors: Rani Cahyani Fajaryatun, Therecia Wulan Sukardi, Arif Jumari,Agus PurwantoAbstract: A lithium battery was composed of anode, cathode, andseparator. The performance of lithium battery was in�uenced by the...more
156
Study of Interfacial Charge Transfer Loss in Hybrid Solar Cellsby Impedance SpectroscopyAuthors: Rahmat Hidayat, Yolla Sukma Handayani, Priastuti WulandariAbstract: Organic solar cells have been much studied because of thesimplicity in their fabrication process in comparison to solar cells based on...more
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< 1 2 4 5 … > >>
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