Nanostructural characterization and catalytic analysis of hybridized platinumphthalocyanine nanocomposites. Kaneko, K., Furuya, K., Hungria, B, A., Hernandez-Garrido, J.-., Midgley, A, P., Onodera, T., Kasai, H., Yaguchi, Y., Oikawa, H., Nomura, Y., Harada, H., Ishihara, T., & Baba, N. Journal of Electron Microscopy, 58(5):289--294, Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan, 2009.
Paper abstract bibtex Organic crystals, such as phthalocyanine nanocrystal, were successfully hybridized with Pt nanoparticles using a nanohybridization technique. The presence of highly dispersed Pt nanoparticles on the surface of phthalocyanine was confirmed by the combination of transmission electron microscopy and three-dimensional electron tomography. Catalytic activities of hybridized samples with different degrees of dispersions were also examined as oxygen reduction reactivity (ORR) with a linear potential sweep method. It was found that oxygen reduction activity increased with increasing Pt dispersion, and reasonably high ORR was observed on Pt-dispersed phthalocyanine nanocrystal even at 2 wt Pt loading.
@article{ Kaneko2009,
abstract = {Organic crystals, such as phthalocyanine nanocrystal, were successfully hybridized with Pt nanoparticles using a nanohybridization technique. The presence of highly dispersed Pt nanoparticles on the surface of phthalocyanine was confirmed by the combination of transmission electron microscopy and three-dimensional electron tomography. Catalytic activities of hybridized samples with different degrees of dispersions were also examined as oxygen reduction reactivity (ORR) with a linear potential sweep method. It was found that oxygen reduction activity increased with increasing Pt dispersion, and reasonably high ORR was observed on Pt-dispersed phthalocyanine nanocrystal even at 2 wt Pt loading.},
address = {Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan},
annote = {Cited By (since 1996): 2
Export Date: 15 January 2013
Source: Scopus
CODEN: JELJA
doi: 10.1093/jmicro/dfp027
Language of Original Document: English
Correspondence Address: Kaneko, K.; Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan; email: kaneko@zaiko.kyushu-u.ac.jp
References: Kubo, R., Electronic properties of metallic fine particles (1962) JPhys SocJpn, 17, pp. 975-986;
Yang, M., Qu, F., Lu, Y., He, Y., Shen, G., Yu, R., Platinum nanowire nanoelectrode array for the fabrication of biosensors (2006) Biomaterials, 27, pp. 5944-5950;
Liu, F., Lee, J.Y., Zhou, W.J., Template preparation of multisegment PtNi nanorods as methanol electro-oxidation catalysts with adjustable bimetallic pair sites (2004) JPhysChemB, 108, pp. 17959-17963;
Sung, W.J., Bae, Y.H., A glucose oxidase electrode based on electropolymerized conducting polymer with polyanion-enzyme conjugated dopant (2000) AnalChem, 72, pp. 2177-2181;
Niwa, O., Horiuchi, T., Morita, M., Huang, T., Kissinger, P.T., Determination of acetylcholine and choline with platinum-black ultramicroarray electrodes using liquid chromatography with a postcolumn enzyme reactor (1996) AnalChimActa, 318, pp. 167-173;
Travitsky, N., Ripenbein, T., Golodnitsky, D., Rosenberg, Y., Burshtein, L., Peled, E., Pt-, PtNi- and PtCo-supported catalysts for oxygen reduction in PEM fuel cells (2006) JPower Sources, 161, pp. 782-789;
Ralph, T.R., Hogarth, M.P., Catalysis for low temperature fuel cells (2002) Platinum Metals Rev, 46, pp. 117-135;
Kapoor, S., Belapurkar, A.D., Mittal, J.P., Mukherjee, T., Catalytic oxidation of carbon monoxide over radiolytically prepared Pt nanoparticles supported on glass (2005) MaterResBull, 40, pp. 1654-1661;
Inaba, M., Ando, M., Hatanaka, A., Nomoto, A., Matsuzawa, K., Tasaka, A., Kinumoto, T., Ogumi, Z., Controlled growth and shape formation of platinum nanoparticles and their electrochemical properties (2006) Electrochimica Acta, 52, pp. 1632-1638;
Bergamaski, K., Pinheiro, A.L.N., Teixeira-Neto, E., Nart, F.C., Nanoparticle size effects on methanol electrochemical oxidation on carbon supported platinum catalysts (2006) JPhysChemB, 110, pp. 19271-19279;
Wen, F., Simon, U., Low loading Pt cathode catalysts for direct methanol fuel cell derived from the particle size effect (2007) Chem. Mater, 19, pp. 3370-3372;
Ca, D.V., Sun, L., Cox, J.A., (2006) Optimization of the Dispersion of Gold and Platinum Nanoparticles on Indium Tin Oxide for the Electrocatalytic Oxidation of Cysteine and ArseniteElectrochimica Acta, 51, pp. 2188-2194;
Marie, J., Berthon-Fabry, S., Achard, P., Chatenet, M., Pradourat, A., Chainet, E., Highly dispersed platinum on carbon aerogels as supported catalysts for PEM fuel cell-electrodes: Comparison of two different synthesis paths (2004) JNon-CrystSol, 350, pp. 88-96;
Rodŕíguez-Reinoso, F., The role of carbon materials in heterogeneous catalysis (1998) Carbon, 36, pp. 159-175;
Kasai, H., Nalwa, H.S., Oikawa, H., Okada, S., Matsuda, H., Minami, N., Kakuta, A., Nakanishi, H., Novel preparation method of organic microcrystals (1992) JpnJApplPhys, 31, pp. L1132-L1134;
Rangel-Rojo, R., Matsuda, H., Kasai, H., Nakanishi, H., Irradiance dependence of the resonant nonlinearities in an organic material (2000) JOptSocAmB, 17, pp. 1376-1382;
Pennycook, S.J., Z-contrast stem for materials science (1989) Ultramicroscopy, 30, pp. 58-69;
Midgley, P.A., Weyland, M., 3D electron microscopy in the physical sciences: The development of Z-contrast and EFTEM tomography (2003) Ultramicroscopy, 96 (3-4), pp. 413-431. , DOI 10.1016/S0304-3991(03)00105-0;
Midgley, P.A., Weyland, M., Meurig Thomas, J., Johnson, B.F.G., Z-contrast tomography: A technique in three-dimensional nanostructural analysis based on Rutherford scattering (2001) Chemical Communications, (10), pp. 907-908;
Kaneko, K., Inoke, K., Sato, K., Kitawaki, K., Higashida, H., Arslan, I., Midgley, P.A., TEM characterization of Ge precipitates in an Al-1.6 at% Ge alloy (2008) Ultramicroscopy, 108, pp. 210-220;
Kaneko, K., Inoke, K., Freitag, B., Hungria, A.B., Midgley, P.A., Hansen, T.W., Zhang, J., Adschiri, T., Structural and morphological characterization of cerium oxide nanocrystals prepared by hydrothermal synthesis (2007) Nano Lett, 7, pp. 421-425;
Ishihara, T., Hata, Y., Nomura, Y., Kaneko, K., Matsumoto, H., (2007)Pd-Au bimetal supported on rutile-TiO2 for selective synthesis of hydrogen peroxide by oxidation of H2 with O2 under atmospheric pressure ChemLett, 36, pp. 878-879;
Lu, Y., Reddy, R.G., (2007) The Electrochemical Behavior of Cobalt Phthalocyanine/platinum As Methanol-resistant Oxygen-reduction Electrocatalysts for DMFCElectrochimica Acta, 52, pp. 2562-2569},
author = {Kaneko, K and Furuya, K and Hungria, A B and Hernandez-Garrido, J.-C. and Midgley, P A and Onodera, T and Kasai, H and Yaguchi, Y and Oikawa, H and Nomura, Y and Harada, H and Ishihara, T and Baba, N},
issn = {00220744 (ISSN)},
journal = {Journal of Electron Microscopy},
keywords = {Electron tomography,Nanocomposite,Organic crystal},
number = {5},
pages = {289--294},
title = {{Nanostructural characterization and catalytic analysis of hybridized platinumphthalocyanine nanocomposites}},
url = {https://www.scopus.com/inward/record.url?eid=2-s2.0-70349473158&partnerID=40&md5=4f1c70802d18bc575c5086acc66dc8d6},
volume = {58},
year = {2009}
}
Downloads: 0
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The presence of highly dispersed Pt nanoparticles on the surface of phthalocyanine was confirmed by the combination of transmission electron microscopy and three-dimensional electron tomography. Catalytic activities of hybridized samples with different degrees of dispersions were also examined as oxygen reduction reactivity (ORR) with a linear potential sweep method. It was found that oxygen reduction activity increased with increasing Pt dispersion, and reasonably high ORR was observed on Pt-dispersed phthalocyanine nanocrystal even at 2 wt Pt loading.},\n address = {Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan},\n annote = {Cited By (since 1996): 2\n\n \nExport Date: 15 January 2013\n\n \nSource: Scopus\n\n \nCODEN: JELJA\n\n \ndoi: 10.1093/jmicro/dfp027\n\n \nLanguage of Original Document: English\n\n \nCorrespondence Address: Kaneko, K.; Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan; email: kaneko@zaiko.kyushu-u.ac.jp\n\n \nReferences: Kubo, R., Electronic properties of metallic fine particles (1962) JPhys SocJpn, 17, pp. 975-986; \nYang, M., Qu, F., Lu, Y., He, Y., Shen, G., Yu, R., Platinum nanowire nanoelectrode array for the fabrication of biosensors (2006) Biomaterials, 27, pp. 5944-5950; \nLiu, F., Lee, J.Y., Zhou, W.J., Template preparation of multisegment PtNi nanorods as methanol electro-oxidation catalysts with adjustable bimetallic pair sites (2004) JPhysChemB, 108, pp. 17959-17963; \nSung, W.J., Bae, Y.H., A glucose oxidase electrode based on electropolymerized conducting polymer with polyanion-enzyme conjugated dopant (2000) AnalChem, 72, pp. 2177-2181; \nNiwa, O., Horiuchi, T., Morita, M., Huang, T., Kissinger, P.T., Determination of acetylcholine and choline with platinum-black ultramicroarray electrodes using liquid chromatography with a postcolumn enzyme reactor (1996) AnalChimActa, 318, pp. 167-173; \nTravitsky, N., Ripenbein, T., Golodnitsky, D., Rosenberg, Y., Burshtein, L., Peled, E., Pt-, PtNi- and PtCo-supported catalysts for oxygen reduction in PEM fuel cells (2006) JPower Sources, 161, pp. 782-789; \nRalph, T.R., Hogarth, M.P., Catalysis for low temperature fuel cells (2002) Platinum Metals Rev, 46, pp. 117-135; \nKapoor, S., Belapurkar, A.D., Mittal, J.P., Mukherjee, T., Catalytic oxidation of carbon monoxide over radiolytically prepared Pt nanoparticles supported on glass (2005) MaterResBull, 40, pp. 1654-1661; \nInaba, M., Ando, M., Hatanaka, A., Nomoto, A., Matsuzawa, K., Tasaka, A., Kinumoto, T., Ogumi, Z., Controlled growth and shape formation of platinum nanoparticles and their electrochemical properties (2006) Electrochimica Acta, 52, pp. 1632-1638; \nBergamaski, K., Pinheiro, A.L.N., Teixeira-Neto, E., Nart, F.C., Nanoparticle size effects on methanol electrochemical oxidation on carbon supported platinum catalysts (2006) JPhysChemB, 110, pp. 19271-19279; \nWen, F., Simon, U., Low loading Pt cathode catalysts for direct methanol fuel cell derived from the particle size effect (2007) Chem. Mater, 19, pp. 3370-3372; \nCa, D.V., Sun, L., Cox, J.A., (2006) Optimization of the Dispersion of Gold and Platinum Nanoparticles on Indium Tin Oxide for the Electrocatalytic Oxidation of Cysteine and ArseniteElectrochimica Acta, 51, pp. 2188-2194; \nMarie, J., Berthon-Fabry, S., Achard, P., Chatenet, M., Pradourat, A., Chainet, E., Highly dispersed platinum on carbon aerogels as supported catalysts for PEM fuel cell-electrodes: Comparison of two different synthesis paths (2004) JNon-CrystSol, 350, pp. 88-96; \nRodŕíguez-Reinoso, F., The role of carbon materials in heterogeneous catalysis (1998) Carbon, 36, pp. 159-175; \nKasai, H., Nalwa, H.S., Oikawa, H., Okada, S., Matsuda, H., Minami, N., Kakuta, A., Nakanishi, H., Novel preparation method of organic microcrystals (1992) JpnJApplPhys, 31, pp. L1132-L1134; \nRangel-Rojo, R., Matsuda, H., Kasai, H., Nakanishi, H., Irradiance dependence of the resonant nonlinearities in an organic material (2000) JOptSocAmB, 17, pp. 1376-1382; \nPennycook, S.J., Z-contrast stem for materials science (1989) Ultramicroscopy, 30, pp. 58-69; \nMidgley, P.A., Weyland, M., 3D electron microscopy in the physical sciences: The development of Z-contrast and EFTEM tomography (2003) Ultramicroscopy, 96 (3-4), pp. 413-431. , DOI 10.1016/S0304-3991(03)00105-0; \nMidgley, P.A., Weyland, M., Meurig Thomas, J., Johnson, B.F.G., Z-contrast tomography: A technique in three-dimensional nanostructural analysis based on Rutherford scattering (2001) Chemical Communications, (10), pp. 907-908; \nKaneko, K., Inoke, K., Sato, K., Kitawaki, K., Higashida, H., Arslan, I., Midgley, P.A., TEM characterization of Ge precipitates in an Al-1.6 at% Ge alloy (2008) Ultramicroscopy, 108, pp. 210-220; \nKaneko, K., Inoke, K., Freitag, B., Hungria, A.B., Midgley, P.A., Hansen, T.W., Zhang, J., Adschiri, T., Structural and morphological characterization of cerium oxide nanocrystals prepared by hydrothermal synthesis (2007) Nano Lett, 7, pp. 421-425; \nIshihara, T., Hata, Y., Nomura, Y., Kaneko, K., Matsumoto, H., (2007)Pd-Au bimetal supported on rutile-TiO2 for selective synthesis of hydrogen peroxide by oxidation of H2 with O2 under atmospheric pressure ChemLett, 36, pp. 878-879; \nLu, Y., Reddy, R.G., (2007) The Electrochemical Behavior of Cobalt Phthalocyanine/platinum As Methanol-resistant Oxygen-reduction Electrocatalysts for DMFCElectrochimica Acta, 52, pp. 2562-2569},\n author = {Kaneko, K and Furuya, K and Hungria, A B and Hernandez-Garrido, J.-C. and Midgley, P A and Onodera, T and Kasai, H and Yaguchi, Y and Oikawa, H and Nomura, Y and Harada, H and Ishihara, T and Baba, N},\n issn = {00220744 (ISSN)},\n journal = {Journal of Electron Microscopy},\n keywords = {Electron tomography,Nanocomposite,Organic crystal},\n number = {5},\n pages = {289--294},\n title = {{Nanostructural characterization and catalytic analysis of hybridized platinumphthalocyanine nanocomposites}},\n url = {https://www.scopus.com/inward/record.url?eid=2-s2.0-70349473158&partnerID=40&md5=4f1c70802d18bc575c5086acc66dc8d6},\n volume = {58},\n year = {2009}\n}","author_short":["Kaneko, K.","Furuya, K.","Hungria","B, A.","Hernandez-Garrido, J.-.","Midgley","A, P.","Onodera, T.","Kasai, H.","Yaguchi, Y.","Oikawa, H.","Nomura, Y.","Harada, H.","Ishihara, T.","Baba, N."],"author":["Kaneko, K","Furuya, K","Hungria","B, A","Hernandez-Garrido, J.-C.","Midgley","A, P","Onodera, T","Kasai, H","Yaguchi, Y","Oikawa, H","Nomura, Y","Harada, H","Ishihara, T","Baba, N"],"annote":"Cited By (since 1996): 2 Export Date: 15 January 2013 Source: Scopus CODEN: JELJA doi: 10.1093/jmicro/dfp027 Language of Original Document: English Correspondence Address: Kaneko, K.; Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan; email: kaneko@zaiko.kyushu-u.ac.jp References: Kubo, R., Electronic properties of metallic fine particles (1962) JPhys SocJpn, 17, pp. 975-986; Yang, M., Qu, F., Lu, Y., He, Y., Shen, G., Yu, R., Platinum nanowire nanoelectrode array for the fabrication of biosensors (2006) Biomaterials, 27, pp. 5944-5950; Liu, F., Lee, J.Y., Zhou, W.J., Template preparation of multisegment PtNi nanorods as methanol electro-oxidation catalysts with adjustable bimetallic pair sites (2004) JPhysChemB, 108, pp. 17959-17963; Sung, W.J., Bae, Y.H., A glucose oxidase electrode based on electropolymerized conducting polymer with polyanion-enzyme conjugated dopant (2000) AnalChem, 72, pp. 2177-2181; Niwa, O., Horiuchi, T., Morita, M., Huang, T., Kissinger, P.T., Determination of acetylcholine and choline with platinum-black ultramicroarray electrodes using liquid chromatography with a postcolumn enzyme reactor (1996) AnalChimActa, 318, pp. 167-173; Travitsky, N., Ripenbein, T., Golodnitsky, D., Rosenberg, Y., Burshtein, L., Peled, E., Pt-, PtNi- and PtCo-supported catalysts for oxygen reduction in PEM fuel cells (2006) JPower Sources, 161, pp. 782-789; Ralph, T.R., Hogarth, M.P., Catalysis for low temperature fuel cells (2002) Platinum Metals Rev, 46, pp. 117-135; Kapoor, S., Belapurkar, A.D., Mittal, J.P., Mukherjee, T., Catalytic oxidation of carbon monoxide over radiolytically prepared Pt nanoparticles supported on glass (2005) MaterResBull, 40, pp. 1654-1661; Inaba, M., Ando, M., Hatanaka, A., Nomoto, A., Matsuzawa, K., Tasaka, A., Kinumoto, T., Ogumi, Z., Controlled growth and shape formation of platinum nanoparticles and their electrochemical properties (2006) Electrochimica Acta, 52, pp. 1632-1638; Bergamaski, K., Pinheiro, A.L.N., Teixeira-Neto, E., Nart, F.C., Nanoparticle size effects on methanol electrochemical oxidation on carbon supported platinum catalysts (2006) JPhysChemB, 110, pp. 19271-19279; Wen, F., Simon, U., Low loading Pt cathode catalysts for direct methanol fuel cell derived from the particle size effect (2007) Chem. Mater, 19, pp. 3370-3372; Ca, D.V., Sun, L., Cox, J.A., (2006) Optimization of the Dispersion of Gold and Platinum Nanoparticles on Indium Tin Oxide for the Electrocatalytic Oxidation of Cysteine and ArseniteElectrochimica Acta, 51, pp. 2188-2194; Marie, J., Berthon-Fabry, S., Achard, P., Chatenet, M., Pradourat, A., Chainet, E., Highly dispersed platinum on carbon aerogels as supported catalysts for PEM fuel cell-electrodes: Comparison of two different synthesis paths (2004) JNon-CrystSol, 350, pp. 88-96; Rodŕíguez-Reinoso, F., The role of carbon materials in heterogeneous catalysis (1998) Carbon, 36, pp. 159-175; Kasai, H., Nalwa, H.S., Oikawa, H., Okada, S., Matsuda, H., Minami, N., Kakuta, A., Nakanishi, H., Novel preparation method of organic microcrystals (1992) JpnJApplPhys, 31, pp. L1132-L1134; Rangel-Rojo, R., Matsuda, H., Kasai, H., Nakanishi, H., Irradiance dependence of the resonant nonlinearities in an organic material (2000) JOptSocAmB, 17, pp. 1376-1382; Pennycook, S.J., Z-contrast stem for materials science (1989) Ultramicroscopy, 30, pp. 58-69; Midgley, P.A., Weyland, M., 3D electron microscopy in the physical sciences: The development of Z-contrast and EFTEM tomography (2003) Ultramicroscopy, 96 (3-4), pp. 413-431. , DOI 10.1016/S0304-3991(03)00105-0; Midgley, P.A., Weyland, M., Meurig Thomas, J., Johnson, B.F.G., Z-contrast tomography: A technique in three-dimensional nanostructural analysis based on Rutherford scattering (2001) Chemical Communications, (10), pp. 907-908; Kaneko, K., Inoke, K., Sato, K., Kitawaki, K., Higashida, H., Arslan, I., Midgley, P.A., TEM characterization of Ge precipitates in an Al-1.6 at% Ge alloy (2008) Ultramicroscopy, 108, pp. 210-220; Kaneko, K., Inoke, K., Freitag, B., Hungria, A.B., Midgley, P.A., Hansen, T.W., Zhang, J., Adschiri, T., Structural and morphological characterization of cerium oxide nanocrystals prepared by hydrothermal synthesis (2007) Nano Lett, 7, pp. 421-425; Ishihara, T., Hata, Y., Nomura, Y., Kaneko, K., Matsumoto, H., (2007)Pd-Au bimetal supported on rutile-TiO2 for selective synthesis of hydrogen peroxide by oxidation of H2 with O2 under atmospheric pressure ChemLett, 36, pp. 878-879; Lu, Y., Reddy, R.G., (2007) The Electrochemical Behavior of Cobalt Phthalocyanine/platinum As Methanol-resistant Oxygen-reduction Electrocatalysts for DMFCElectrochimica Acta, 52, pp. 2562-2569","address":"Department of Materials Science and Engineering, Kyushu University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan","abstract":"Organic crystals, such as phthalocyanine nanocrystal, were successfully hybridized with Pt nanoparticles using a nanohybridization technique. The presence of highly dispersed Pt nanoparticles on the surface of phthalocyanine was confirmed by the combination of transmission electron microscopy and three-dimensional electron tomography. Catalytic activities of hybridized samples with different degrees of dispersions were also examined as oxygen reduction reactivity (ORR) with a linear potential sweep method. It was found that oxygen reduction activity increased with increasing Pt dispersion, and reasonably high ORR was observed on Pt-dispersed phthalocyanine nanocrystal even at 2 wt Pt loading."},"bibtype":"article","biburl":"http://www2.uca.es/dept/cmat_qinor/nanomat/people/Hungria.bib","downloads":0,"keywords":["electron tomography","nanocomposite","organic crystal"],"search_terms":["nanostructural","characterization","catalytic","analysis","hybridized","platinumphthalocyanine","nanocomposites","kaneko","furuya","hungria","b","hernandez-garrido","midgley","a","onodera","kasai","yaguchi","oikawa","nomura","harada","ishihara","baba"],"title":"Nanostructural characterization and catalytic analysis of hybridized platinumphthalocyanine nanocomposites","year":2009,"dataSources":["tkoLgiggidjAYidGW"]}