TY - JOUR
T1 - Fe nanoparticle entrained in tubular carbon nanofiber as an effective electrode material for metal-air batteries
T2 - A fundamental reason
AU - Kim, Taegon
AU - Ohata, Yuzo
AU - Kim, Jandee
AU - Rhee, Choong Kyun
AU - Miyawaki, Jin
AU - Yoon, Seong Ho
N1 - Funding Information:
This work was supported by a grant from the ALCA project in Japan Science and Technology Agency (JST) and the Global Centre of Excellence (G-COE) of Novel Carbon Resource Sciences in Kyushu University. The authors thank JST and Kyushu University for financial assistance. CKR thanks Chungnam National University for a financial support (project number: 2014-0696-01).
Publisher Copyright:
© 2014 Elsevier Ltd. All rights reserved.
PY - 2014
Y1 - 2014
N2 - Fe nanoparticle entrained in tubular carbon nanofiber (TCNF) as an effective electrode material for metal-air batteries was successfully prepared. TEM and STM investigations revealed that during impregnation Fe precursor ions penetrated into TCNF tubes through factures between the structural units of TCNF, which were absent in commercial carbon nanotube (CCNT). Thus the location of Fe nanoparticles depended on carbon materials: they were in the TCNF tubes and on the surfaces of CCNT. During repeated voltammetric cycles, the Fe nanoparticles in the TCNF tubes evolved to elongated oxygen-lean Fe nanoparticles, while those on CCNT did to oxygen-rich Fe oxide dendrites. Voltammograms of the modified Fe nanoparticles revealed that a higher overpotential was needed for dendrite formation. On the other hand, impedance spectroscopy also disclosed that the mass transfer of soluble Fe species was much faster in the one-dimensional TCNF tubes than in the three-dimensional open spaces between individual CCNTs. Thus, a low overpotential of the redox process of the elongated Fe nanoparticles and the fast mass transfer of soluble Fe species in the TCNF tubes resulted in an increased amount of Fe involved in charging/ discharging process, which accounted for the higher efficiency of Fe nanoparticles on TCNF in Fe-air battery system.
AB - Fe nanoparticle entrained in tubular carbon nanofiber (TCNF) as an effective electrode material for metal-air batteries was successfully prepared. TEM and STM investigations revealed that during impregnation Fe precursor ions penetrated into TCNF tubes through factures between the structural units of TCNF, which were absent in commercial carbon nanotube (CCNT). Thus the location of Fe nanoparticles depended on carbon materials: they were in the TCNF tubes and on the surfaces of CCNT. During repeated voltammetric cycles, the Fe nanoparticles in the TCNF tubes evolved to elongated oxygen-lean Fe nanoparticles, while those on CCNT did to oxygen-rich Fe oxide dendrites. Voltammograms of the modified Fe nanoparticles revealed that a higher overpotential was needed for dendrite formation. On the other hand, impedance spectroscopy also disclosed that the mass transfer of soluble Fe species was much faster in the one-dimensional TCNF tubes than in the three-dimensional open spaces between individual CCNTs. Thus, a low overpotential of the redox process of the elongated Fe nanoparticles and the fast mass transfer of soluble Fe species in the TCNF tubes resulted in an increased amount of Fe involved in charging/ discharging process, which accounted for the higher efficiency of Fe nanoparticles on TCNF in Fe-air battery system.
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U2 - 10.1016/j.carbon.2014.09.014
DO - 10.1016/j.carbon.2014.09.014
M3 - Article
AN - SCOPUS:84920447012
SN - 0008-6223
VL - 80
SP - 698
EP - 707
JO - Carbon
JF - Carbon
IS - 1
ER -