Fullere
The Electrochemical Society
Contents
Author Index
Subject Index
Surface
Immobilization and Characterization of Cytochrome c on Fullerene
Modified Electrodes. F. D'Souza, L.M.
Rogers, E.S. O'Dell, A. Kochman, W. Kutner |
1 |
Formation and
Structure Control of Single-Walled Carbon Nanotubes Using
Plasma-Enhanced Chemical Vapor Deposition. T. Kato,
T. Hirata, G.-H. Jeong, R. Hatakeyama, K. Tohji |
10 |
Electrochemistry and
Photophysics of Fullerene-Porphyrin Dyads. Z. Ou, Z. Zhou, H.
Zhao, F.T. Tat, X.P. Zhang, S.R. Wilson, K.M. Kadish |
18 |
Electrochemical
Formation of Two-Component Electroactive Films of Palladium and
Fullerene. Covalently Attached to a Zinc Porphyrin Redox Probe. M. Plonska, K.
Winkler, S. Gadde, F. D'Souza, A.L. Balch |
30 |
Electrochemical
Transformations of C60 Fullerene Films in Solutions
Containing Water. Á. Szűcs, V.
Budavári, M. Novák, J.B. Nagy |
39 |
Self-Assembly via
'Two-Point' Binding of a Zinc Porphyrin Dimer to a bis Pyridine
Functionalized Fullerene: Singlet Emission Studies. F. D'Souza, S.
Gadde, M.E. Zandler, M. Itou, Y. Araki, O. Ito |
46 |
Supramolecular
Photovoltaic Cells Composed of Clusterized Fullerenes with Porphyrin
Dendrimers and Porphyrin-Alkanethiolate Protected-Gold Nanoparticles. T. Hasobe, Y.
Kashiwagi, M.A. Absalom, J. Sly, K. Hosomizu, M.J. Crossley, H.
Imahori, P.V. Kamat, S. Fukuzumi |
51 |
Gibbs Energy
Treatment of Ca@C74, C@C82, and La@C82.
Z.
Slanina, K. Kobayashi, S. Nagase |
71 |
Carbon Nanotube
Array in an Acidic Electrostatics by DLVO Theory. C. Lee, B. I.
Yakobson |
84 |
Computations of New Observations for C60F36
and C60H36. Z. Slanina, F.
Uhlík, O.V. Boltalina, K. Kobayashi, S. Nagase |
94 |
Production of
Endohedral N@C60 Using Novel Plasma Technology. R.
Hatakeyama, T. Hirata, K. Fujimoto, M. Miwa, Y. Kasama |
103 |
Bulk Synthesis and
Characterization of Carbon Nanocapsules Containing Lanthanum Carbide. K.
Yamamoto, T. Wakahara, T. Akasaka |
110 |
Thermal Effects in
Photoemission and Electron-Phonon Couplings of Fullerene. A. Bordoni, N. Manini |
118 |
Isolation and
Characterisation of C60F26, C60F28,
C60F30 and C60F22. |
126 |
Isolation and
Characterisation of C60F10O. |
134 |
Pyrolysis of
Fluorofullerenes. A.D. Darwish, A.K.
Abdul-Sada, N. Martsinovich, R. Taylor |
139 |
Novel Formation of a
Fluorinated Aziridino G.A. Burley, A.D.
Darwish, |
145 |
One Step Metal
Particle Deposition and Solubilization of Single Wall Carbon Nanotubes
for Fuel Call Applications. T. Nelson, K.
Vinodgopal, G.G. Kumar, P.V. Kamat |
152 |
Nanocarbon Formation
by Using ARC Discharge Plasmas in DNA Dispersed Organic Solvents. T. Okada,
T. Kaneko, R. Hatakeyama, K. Tohji |
160 |
Excited
Electronic States and Relative Stabilities of C80 Isomers. Z.
Slanina, F. Uhlík, L. Adamowicz, K. Kobayashi, S. Nagase |
168 |
Preparation of
Carbon Nanotubes for Biomedical Applications: Size-Separation and their
Biocompatibilities. K. Tohji, Y.
Akimoto, Y. Sato, B. Jeyadevan, K. Tamura, T. Akasaka, M. Uo, A.
Yokoyama, K.-I. Shibata, F. Watari |
178 |
Low Carrier Density
Organic Conductors: Unconventional Electron-Phonon Coupling and
Superconductivity. L. Pietronero, E.
Cappelluti |
184 |
Molecular Wires:
Long-Range Electron Tunneling and Hopping in Novel Donor-Acceptor
Ensembles. F.
Giacalone, J.L. Segura, N. Martín, D.M. Guldi |
197 |
Photoinduced
Electron Transfer in Porphyrin-Oligothiophene-Fullerene Linked Triads. T.
Nakamura, M. Fujitsuka, Y. Araki, O. Ito, J. Ikemoto, K. Takimiya, Y.
Aso, T. Otsubo |
210 |
Synthesis and Cation
Complexation Induced Electrochemical Behavior of bis-Functionalized
Fullerene-Dibenzo- F. D'Souza, A.L.
McCarty, P.M. Smith |
232 |
Integrating Single
Wall Carbon Nanotubes into Donod-Acceptor Nanohybrids. D.M. Guldi, A.
Raman, J. Ramey, N. Jux, V. Georgakilas, N. Tagmatarchis, M. Prato |
237 |
Preparation and
Biocompatibility of Sintered Carbon Nanotube Disk. M. Ohtsubo, Y. Sato,
B. Jeyadevan, K. Tohji, R. Hatakeyama, G. Yamamoto, M. Ohmori, T.
Hashida, K. Tamura, T. Akasaka, M. Uo, A. Yokoyama, F. Watari |
243 |
Unique
Cycloadditions Accompanying Methylation and Metal Fluoride
Fluorination: Formation of New Fullerene Dimers. A.G. Avent, A.K.
Abdul-Sada, R. Taylor |
249 |
The First Pauson-Khand
Reaction with C60: A New Tool in Fullerene Chemistry. N. Martín,
Á Martín-Domenech, S. Filippone, M. Altable |
256 |
Synthesis and
Properties of Open-Cage Fullerene C70 Derivatives. Y. Murata,
S. Maeda, M. Murata, K. Komatsu |
267 |
Organic
Functionalization of C60 Toward the Synthesis of Endohedral
Fullerene Complexes. K.
Komatsu, Y. Murata, M. Murata, H. Sawa |
275 |
Recent Advances in
Phthalocyanine-Fullerene Molecular Systems. G.
Bottari, D. González-Rodríguez, T. Torres |
282 |
Nanostructured
Carbon Electrodes Based on Fullerenes and Carbon Nanotubes for Methanol
Oxidation Reaction. G. Kumar,
D. Meisel, P.V. Kamat, K. Vinodgopal |
298 |
Investigation of the
Impact of Stress on Aluminum-Induced Crystallization of Amorphous
Silicon. L. Cai, H. Abu-Safe,
M. Zou, M. Barghouti, M. Hossain, H. Naseem, W. Brown |
307 |
Effect of Stress on
Aluminum Induced Crystallization of Magnetron Sputtered Amorphous
Silican Thin Film. M. Hossain, H.
Abu-Safe, L. Cai, H. Naseem, W.D. Brown |
313 |
Evidence for Singlet
Oxygen Generation from Irradiated Hydrophilic Micelle-like
Hexa(sulfobutyl)fullerene (FC4S). C. Yu, T.
Canteenwala, L.Y. Chiang, K. Pritzker, B.C. |
321 |
Dynamic Light
Scattering and Relaxometric Studies of Water-Soluble Gd@C60
Derivatives as pH-Responsive MRI Contrast Agents. B. Sitharaman, L.J.
Wilson, R.D. Bolskar, G. González, É. Tóth, L.
Helm, A.E. Merbach |
330 |
Toward Targeted
Fullerene Cancer Therapy: Design and Synthesis of a Paclitaxel-C60-Antibody
Conjugate. T. Zakharian, J.
Ashcroft, A. Mirakyan, D. Tsyboulski, N. Benedict, B. Weisman, L.J.
Wilson, J.W. Marks, M.R. Rosenblum |
338 |
Synthesis of
Amphiphilic Fullerodendrimers and their Incorporation in Langmuir and
Langmuir-Blodgett Films. S. Zhang,
Y. Rio, F. Cardinali, C. Bourgogne, J.-L. Gallani, J.-F. Nierengarten |
349 |
Photophysics and
Photovoltaic Devices of a p-Extended Tetrathiafulvalene-Fullerene Dyad. C. Winder,
H. Neugebauer, N.S. Sariciftci, F. Giacalone, J.L. Segura, N.
Martín |
365 |
Nanodimensional
Paper Sensor for Fighting Bioterrorism. I. Cawthray, M.
Croston, K.S.V. Santhanam |
374 |
Abdul-Sada, A.K. |
126, 139, 249 |
Absalom, M.A. |
51 |
Abu-Safe, H. |
307, 313 |
Adamowicz, L. |
168 |
Akasaka, T. |
110, 178, 243 |
Akimoto, Y. |
178 |
Altable, M. |
256 |
Araki, Y. |
46, 210 |
Ashcroft, J. |
338 |
Aso, Y. |
210 |
Avent, A.G. |
249 |
Balch, A.L. |
30 |
Barghouti, M. |
307 |
Benedict, N. |
338 |
Bolskar, R.D. |
330 |
Boltalina, O.V. |
94 |
Bordoni, A. |
118 |
Bottari, G. |
282 |
|
349 |
Brown, W.D. |
307, 313 |
Budavári, V. |
39 |
Burley, G.A. |
145 |
Cai, L. |
307, 313 |
Canteenwala, T. |
321 |
Cappelluti, E. |
184 |
Cardinali, F. |
349 |
Cawthray, I. |
374 |
Chiang, L.Y. |
321 |
Crossley, M.J. |
51 |
Croston, M. |
374 |
D'Souza, F. |
1, 30, 46, 232 |
Darwish, A.D. |
134, 139, 145 |
Filippone, S. |
256 |
Fujimoto, K. |
103 |
Fujitsuka, M. |
210 |
Fukuzumi, S. |
51 |
Gadde, S. |
30, 46 |
Gallani, J.-L. |
349 |
Georgakilas, V. |
237 |
Giacalone, F. |
197, 365 |
González, G. |
330 |
González-Rodriguez,
D. |
282 |
Guldi, D.M. |
197, 237 |
Hashida, T. |
243 |
Hasobe, T. |
51 |
Hatakeyama, R. |
10, 103, 160, 243 |
Helm, L. |
330 |
Hirata, T. |
10, 103 |
Hosomizu, K. |
51 |
Hossain, M. |
307, 313 |
Ikemoto, J. |
210 |
Imahori, H. |
51 |
Ito, O. |
46, 210 |
Itou, M. |
46 |
Jeong, G.-H. |
10 |
Jeyadevan, B. |
178, 243 |
Jux, N. |
237 |
Kadish, K.M. |
18 |
Kamat, P.V. |
51, 152, 298 |
Kaneko, T. |
160 |
Kasama, Y. |
103 |
Kashiwagi, Y. |
51 |
Kato, T. |
10 |
Kobayashi, K. |
71, 94, 168 |
Kochman, A. |
1 |
Komatsu, K. |
267, 275 |
Kumar, G. |
152, 298 |
Kutner, W. |
1 |
Lee, C. |
84 |
Maeda, S. |
267 |
Manini, N. |
118 |
Marks, J.W. |
338 |
Martín, N. |
197, 256, 365 |
Martín-Domenech,
Á |
256 |
Martsinovich, N. |
139 |
McCarty, A.L. |
232 |
Meisel, D. |
298 |
Merbach, A.E. |
330 |
Mirakyan, A. |
338 |
Miwa, M. |
103 |
Murata, M. |
267, 275 |
Murata, Y. |
267, 275 |
Nagase, S. |
71, 94, 168 |
Nagy, J.B. |
39 |
Nakamura, T. |
210 |
Naseem, H. |
307, 313 |
Nelson, T. |
152 |
Neugebauer, H. |
365 |
Nierengarten, J.-F. |
349 |
Novák, M. |
39 |
O'Dell, E.S. |
1 |
Ohmori, M. |
243 |
Ohtsubo, M. |
243 |
Okada, T. |
160 |
Otsubo, T. |
210 |
Ou, Z |
18 |
Pietronero, L. |
184 |
Plonska, M. |
30 |
|
237 |
Pritzker, K. |
321 |
Raman, A. |
237 |
Ramey, J. |
237 |
|
349 |
|
1 |
Rosenblum, M.R. |
338 |
Santhanam, K.S.V. |
374 |
|
365 |
Sato, Y. |
178, 243 |
Sawa, H. |
275 |
|
197, 365 |
Shibata, K.-I. |
178 |
Sitharaman, B. |
330 |
Slanina, Z. |
71, 94, 168 |
Sly, J. |
51 |
Smith, P.M. |
232 |
Street, J.M. |
126, 134, 145 |
Szücs, Á |
39 |
Tagmatarchis, N. |
237 |
Takimiya, K. |
210 |
Tamura, K. |
178, 243 |
Tat, F.T. |
18 |
Taylor, R. |
126, 134, 139, 145, 249 |
Tohji, K. |
10, 160, 178, 243 |
Torres, T. |
282 |
Tóth, É. |
330 |
Tsyboulski, D. |
338 |
Uhlík, F. |
94, 168 |
Uo, M. |
178, 243 |
Vinodgopal, K. |
152, 298 |
Wakahara, T. |
110 |
Watari, F. |
178, 243 |
Weisman, B. |
338 |
|
321 |
|
330, 338 |
Wilson, S.R. |
18 |
Winder, C. |
365 |
Wnkler, K. |
30 |
Yamamoto, G. |
243 |
Yamamoto, K. |
110 |
Yakobson, B.I. |
84 |
Yokoyama, A. |
178, 243 |
Yu, C. |
321 |
Zakharian, T. |
338 |
|
46 |
Zhang, S. |
349 |
Zhang, X.P. |
18 |
Zhao, H. |
18 |
Zhou, Z. |
18 |
Zou, M. |
307 |
amorphous silicon |
307 |
applications |
321 |
aqueous |
39 |
arc discharge plasma |
160 |
axial ligation |
46 |
azirifinofullerene |
145 |
band-gap |
313 |
biocompatibility |
178, 243 |
biological application |
330, 338 |
biomedical |
321 |
biomedical application |
330, 338 |
bulk synthesis |
110 |
C60 anion |
118 |
C60 isomers |
168 |
C60-antibody
conjugate |
338 |
carbon nanocapsules |
110 |
carbon nanotubes |
84, 152 |
cation complexation |
232 |
cation recognition |
232 |
charge separation |
46, 237 |
chemical detection |
374 |
chemically modified electrode
|
1 |
CNT films |
298 |
CNT's |
160 |
computations |
71, 94 |
crystallization |
307 |
cyclic voltammetry |
232, 275 |
cyclization |
349 |
cycloaddition |
232, 249 |
cytochrome c |
1 |
dendrimers |
349 |
DFT calculations |
168, 267 |
differential pulse voltammetry |
267 |
DNA encapsulated nanocarbons |
160 |
donor-bridge-acceptor |
197, 210 |
double layer interaction |
84 |
drug delivery |
338 |
DVVO theory |
84 |
dyads |
18, 30 |
electrochemistry |
39 |
electron transfer |
197, 210, 237 |
electron-phonon coupling |
184 |
electron-photocoupling |
118 |
electrophoretic deposition |
298 |
electrostatic effect |
84 |
endohedral fullerene |
275, 330 |
energy transfer |
321 |
excited state |
168 |
fibrous connective tissue |
243 |
fluorinated fullerenes |
249 |
fluorination |
126 |
fluorofullerenes |
126, 134, 139, 145 |
FTIR |
313 |
fuel cell application |
152, 298 |
fullerene clusters |
51 |
fullerene dyad |
365 |
fullerene films |
30, 39 |
fullerene modified electrode |
1 |
fullereneoxides |
134 |
fullerenes |
282 |
fulleropyrrolidines |
256 |
functionalized fullerene |
46, 232, 256 |
functionalized nanotubes |
374 |
gadofullerene |
330 |
gate dielectric |
313 |
gold nanoparticle |
51 |
gold particles |
152 |
HPLC separation |
134 |
hydrodynamic diameter |
330 |
hydrogenation |
39 |
inflammatory response |
243 |
lanhanum carbide |
110 |
L-B films |
349 |
light energy conversions |
51 |
low temperature formation |
10 |
lymphocyte |
243 |
metallofullerene |
71, 94, 103 |
methanol oxidation |
152, 298 |
methylation |
249 |
molecular wires |
197 |
multi-walled carbon nanotubes |
243 |
MWCNT |
178 |
N@C60 |
103 |
nanotubes |
282 |
neutrohils activity |
178 |
nonadiabatic effects |
184 |
oligo-PPVs |
197 |
open cage fullerene |
145, 267, 275 |
optoelectronic application |
18 |
organic conductors |
184 |
organic solar cells |
365 |
organic solvent |
160 |
oxygen reduction |
152 |
Pauson-Khand reaction |
256 |
PECVD |
313 |
photochemistry |
18, 210 |
photocurrent |
51, 237 |
photoelectrochemistry |
39 |
photoemission |
118 |
photoinduced charge transfer |
365 |
photoinduced electron transfer |
282 |
photovoltaic solar cells |
282 |
photovoltaics |
51 |
phthalcyanines |
282 |
piezoelectric microgravimetry |
1 |
plasma generation |
103 |
plasma-enhanced chemical
vapor deposition |
10 |
porphyrin |
51 |
porphyrin dimer |
46 |
porphyrins |
18, 30, 210 |
pyridinofullerene |
18 |
pyrolysis |
139 |
quartz crystal microbalance |
1 |
redox probe |
30 |
sensor |
374 |
silicon nitride |
313 |
single wall carbon nanotubes |
10, 298 |
singlet oxgen |
321, |
size-separation |
178 |
solubilization of CNT |
152 |
spark plasma system |
243 |
structure-energetics |
71 |
subphthalocyanines |
282 |
super conductivity |
184 |
surface immobilization |
1 |
SWNT |
237 |
tetrathiafulvalene |
197, 365 |
thermal effects |
118 |
thin film transistor |
313 |
triad |
210 |
triplet excited state |
338 |
Zeolite |
10 |