研究業績

ソーラーハイブリッド燃料生産に関する研究

• H. Ono, M. Kawabe, H, Amano, M. Tsuji and Y. Tamaura, “Solar/chemical energy hybridization via Boudouard reaction for carbon utilization as a solar energy carrier”, Studies in Surf. Sci. and Cat., 114, 371-374, (1998)
• T. Sano, M. Tsuji and Y. Tamaura, “Photochemical effect on reduction of ultrafine (Ni, Zn)ferrite by CO at 300℃”, J. Chem. Soc. Faraday Trans. 94[9], 1243-1248, (1998).
• J. Matsunami, S. Yoshida, O. Yokota, M. Nezuka, M. Tsuji and Y. Tamaura, “Gasification of waste tire and plastic (PET) by solar thermochemical process for solar energy utilization”, Solar Energy, 65[1], 21-23, (1999)
  
• Y. Tamaura, M. Tsuji, S. Yshida, O. Yokota and T. Sano, “Solar Gasification of Coal using Carbonate Molten Salt Reactor” Solar Thermal Concentrating Technologies, Odeillo-Font-Romer, France, (1998).
• S. Yoshida, H. Amano, Y. Hosokawa, M. Tsuji and Y. Tamaura, “Gasification of Waste Tire with ZnO as an Oxidant for Solar Energy Utilization”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 425-426, (1998).
• H. Ono, M. Kawabe, M. Nezuka, M. Tsuji, and Y. Tamaura, “Kinetic Study on High-Temperature Solar Themochemical Energy Conversion Using Fe₃O₄/Carbon Redox or Boudouard Reaction Processes”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 425-426, (1998).
• M. Tsuji, M. Nezuka, S. Yosbida, H. Amano, Y. Tamaura and A. Steinfeld, “Thermochemical Solar/Fossil Energy Mixing using Metal Oxides”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 411-412, (1998).
• H. Ono, S. Yoshida, M. Nezuka, T. Sano, M. Tsuji and Y. Tamaura, “Kinetics and simulation on a high-temperature solar thermochemical energy conversion process on the Boudouard reaction”, Energy & Fuels, 13[3], 579-584, (1999).
• V. D. Thao, T. Sano, H. Amano, M. Tsuji and Y. Tamaura, “Ultra-Stabilization Process for Heavy Metal Sludges by Ferrite Coating”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 427-428, (1998).
• Yokota, Y. Oku, T. Sano, N. Hasegawa, J. Matsunami, M. Tsuji and Y. Tamaura, “Stoichiometric consideration of steam reforming of methane on Ni/Al₂O₃ catalyst at 650℃ by using a solar furnace”, Int. J. Hydrogen Energy, 25[1], 81-86, (2000).
• J. Matsunami, S. Yoshida, Y. Oku, O. Yokota, Y. Tamaura and M. Kitamura, “Coal gasification with CO₂ in molten salt for solar thermal/chemical energy conversion”, Energy, 25[1], 71-79, (2000)
• J. Matsunami, S. Yoshida, Y. Oku, O. Yokota, Y. Tamaura and M. Kitamura, “Coal gasification by CO₂ gas bubbling in molten salt for solar/fossil energy hybridization”, Solar Energy, 68[3], 257-261, (2000).
• Yokota, Y. Oku, M. Arakawa, N. Hasegawa, J. Matsunami, H. Kaneko, Y. Tamaura and M. Kitamura, “Steam reforming of methane using a solar simulator controlled by H₂O/CH₄ = 1/1”, Applied Organometallic Chem., 14[12], 867-870, (2000).
• N. Gokon, Y. Oku, H. Kaneko and Y. Tamaura, “Methane Reforming with CO₂ in Molten Salt using FeO Catalyst”, Solar Energy, 72[3], 243-250, (2002).
• 玉浦裕，“Solar Fuel Production by Conversion of Concentrated Solar-Heat to Chemical Energy（集光太陽エネルギー／化学エネルギー変換によるソーラー燃料生産）”，Eco-Engineering, 15[3], 109-119, (2003).
• N. Gokon, N. Hasegawa, H. Kaneko, H. Aoki, Y. Tamaura and M. Kitamura, “Photocatalytic effect of ZnO on carbon gasification with CO₂ for high temperature solar thermochemistry”, Solar Energy Mater. Solar Cells, 80[3], 335-341, (2003).
• Y. Katayama and Y. Tamaura, “Development of new green-fuel production technology by combination of fossil fuel and renewable energy”, Energy, 30[11-12], 2179-2185, (2005).

太陽熱化学反応に関する研究

• T. Sano, Y. Hosokawa, H. Amano, M. Tsuji and Y・Tamaura, “Stabilized Wustite Formed from Zn(II)- and Mn (II)-Wustite below 570℃”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 58-59, (1998).
  
• T. Sano and Y. Tamaura, “Synthesis of (Li, Mn) ferrites by reaction of ultrafine Fe2O3 with LiMn2O4 spinel at 650℃”, Mater. Res. Bull., 34[3], 389-401, (1999).
  
• T. Sano, M. Tsuji, N. Gokon, H. Kaneko and Y. Tamaura, “Oxygen uptake and release mechanism of lithium manganese ferrite in the low temperature range of 573K-773K”, J. Am. Ceram. Soc., 83[10], 2509-2514, (2000).
  
• 鈴木研夫，湯浅実，玉浦裕，“水平置きヘリオスタットを用いたビームダウン式タワー集光系の最適設計”，太陽エネルギー，29[5], 41-47, (2003).
  
• H. Kaneko, T. Kodama, N. Gokon, Y. Tamaura, K. Lovegrove and A. Luzzi, “Decomposition of Zn-ferrite for O2 generation by concentrated solar radiation”, Solar Energy, 76, 317-322 (2004).
  
• Y. Tamaura and H. Kaneko, “Oxygen-releasing step of ZnFe₂O₄/(ZnO+Fe₃O₄)-system in air using concentrated solar energy for solar hydrogen production”, Solar Energy, 78[5], 616-622, (2005).
  
• H. Kaneko, N. Gokon, N. Hasegawa and Y. Tamaura, “Solar thermochemical process for hydrogen production using ferrites”, Energy, 30[11-12], 2171-2178, (2005).

ソーラー水素生成反応に関する研究

• Y. Tamaura, Y. Ueda, J. Matsunami, N. Hasegawa, M. Nezuka, T. Sano and M. Tsuji, “Solar hydrogen production by using ferrites”, Solar Energy, 65[1], 55-57, (1999)
  
• Y. Tamaura, “Ferrites for Global Environmental Protection Technology”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 396-399, (1998).
  
• N. Hasegawa, Y. Ueda, T. Sano, M. Tsuji, Y. Tamaura and A. Steinfeld, “Non-Stoichiometric Ferrites for Solar Energy Conversion into H2 Energy”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 417-418, (1998).
  
• Y. Ueda, N. Hasegawa, Y. Ochiai, M. Tsuji and Y. Tamaura, “A New Themochemical Water Splitting Process Using Ferrite-CaCO₃ (or Na₂CO₃)-H₂O System”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 419-420, (1998).
  
• M. Kawabe, N. Hasegawa, H. Amano, M. Tsuji and Y. Tamaura, “Study on the 2nd Step (H₂ Production) in Fe₃O₄/Coal Redox Process for Solar/Fossil Energy Mixing”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 415-416, (1998).
  
• T. Sano, H. Ono, H. Amano, M. Tsuji and Y. Tamaura, “CO₂ Decomposition with Ferrites for Utilizing Carbon as Solar H2 Energy Carrier. -Reaction Mechanism of CO₂ Decomposition with Ferrites-”, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 423-424, (1998).
  
• H. Amano, Y. Ochiai, M. Tsuji and Y. Tamaura, “CO₂ decomposition with ferrites for utilizing carbon as solar H₂ energy carrier. -CO₂ decomposition reactivity with metal substituted ferrites-, J. Magnetics Soc. Jpn., 22 Supplement No.Sl, 421-422, (1998).
  
• H. Kaneko, Y. Hosokawa, N. Gokon, N. Kojima, N. Hasegawa, M. Kitamura and Y. Tamaura, “Enhancement of O₂-releasing step with Fe₂O₃ in the water splitting by MnFe₂O₄-Na₂CO₃ system“, J. Phys. Chem. Solids, 62[7] 1341-1347, (2001)
  
• Y. Tamaura, N. Kojima, N. Hasegawa, M. Inoue, R. Uehara, N. Gokon and H. Kaneko, “Stoichiometric studies of H2 generation reaction for H₂O/Zn/Fe₃O₄ system”, Int. J. Hydrogen Energy, 26[9], 917-922, (2001)
  
• H. Kaneko, Y. Hosokawa, N. Kojima, N. Gokon, N. Hasegawa, M. Kitamura and Y. Tamaura, “Studies on metal oxides suitable for enhancements of O₂-releasing step in the water splitting by MnFe₂O₄-Na₂CO₃ system”, Energy, 26[10], 919-929, (2001)
  
• H. Kaneko, Y. Ochiai, K. Shimizu, Y. Hosokawa, N. Gokon, and Y. Tamaura, “Thermodynamic study based on the phase diagram of Na₂O-MnO-Fe₂O₃ system for H2 production in three-step water splitting with Na₂CO₃/MnFe₂O₄/Fe₂O₃”, Solar Energy, 72[4], 377-383, (2002).
  
• H. Kaneko, N. Kojima, N. Hasegawa, M. Inoue, R. Uehara, N. Gokon, Y. Tamaura and T. Sano, “Reaction mechanism of H₂ generation for H₂O/Zn/Fe₃O₄ system”, Int. J. Hydrogen Energy, 27[10], 1023-1028, (2002).
  
• H. Kaneko, N. Gokon, N. Hasegawa, M. Inoue, R. Uehara and Y. Tamaura, “Water splitting by using a metal oxide for solar thermal/chemical energy conversion”, Eco-Engineering, 14[4], 3-9, (2002).
  
• M. Inoue, N. Hasegawa, R. Uehara, N. Gokon, H. Kaneko and Y. Tamaura, “Solar hydrogen generation with H₂O/ZnO/MnFe₂O₄ system“, Solar Energy, 76, 309-315 (2004).
  
• H. Kaneko, T. Yokoyama, A. Fuse, H. Ishihara, N. Hasegawa and Y. Tamaura, “Synthesis of New Ferrite, Al-Cu ferrite, and Its Oxygen Deficiency for Solar H₂ Generation from H₂O”, Int. J. Hydrogen Energy, 31, 15, 2256-2265, (2006).
  
• H. Kaneko, T. Miura, H. Ishihara, S. Taku, T. Yokoyama, H. Nakajima and Y. Tamaura “Reactive ceramics of CeO₂–MO_x (M=Mn, Fe, Ni, Cu) for H2 generation by two-step water splitting using concentrated solar thermal energy.”, Energy, 32, 5, 656-663, (2007)
  
• H. Kaneko, T. Miura, A. Fuse, H. Ishihara, S. Taku, H. Fukuzumi, Y. Naganuma, Y. Tamaura, “ Rotary-Type Solar Reactor for Solar Hydrogen Production with Two-step Water Splitting Process.” Energy & Fuel, 21, 2287-2293, (2007)
  
• S. Taku, H. Kaneko and Y. Tamaura, “Two-step water splitting reaction with　Ce-Zr oxide system for solar hydrogen production”, Eco-Engineering (2007),　19　(4), 255-262.
  
• H. Ishihara, H. Kaneko, N. Hasegawa, Y. Tamaura, “Two-step water splitting process with solid solution of YSZ and Ni-ferrite for solar hydrogen production”, Solar Energy Engineering, In Press.
  
• H. Kaneko,H. Ishihara, S. Taku, Y. Naganuma. N. Hasegawa, Y. Tamaura, “Cerium ion redox system in CeO₂-xFe₂O₃ solid solution at high temperatures (1,273-1,673K) in the two-step water splitting reaction for solar H₂ generation.” Journal of Materials. Science, In Press.

ビームダウン式集光太陽装置に関する研究

• Hiroshi Hasuike, Yoshio Yoshizawa, Akio Suzuki and Yutaka Tamaura, ” Study on design of molten salt solar receivers for beam-down solar concentrator”, Solar Energy, 80 (10), 1255-1262, (2006).

生態工学に関する研究

• M. Nishio, Y. Tamaura, K. Omasa, S. Muramatsu, K. Horaguchi, A. Masuda, K. Maruyama, H. Morooka, and K. Nitta, “Proposal for Eco-Engineering System Designed for Aomori Prefecture Environment-Industry Special Zone”, Eco-Engineering, 16(1), 21-26 (2004).
  
• Y. Tamaura, H. Aoki, M. Nishio, K. Omasa, S. Muramatsu, N. Hasegawa, K. Nitta, and S. Nishizaki, “Eco-Engineering and Community Special Zone for Sustainable Society”, Eco-Engineering, 16(1), 27-32 (2004).

環境保全技術に関する研究

• S. Yoshida, J. Matsunami, Y. Hosokawa, O. Yokota, Y. Tamaura and M. Kitamura, “Coal/CO₂ gasification system using molten carbonate salt for solar/fossil energy hybridization”, Energy & Fuels, 13[5], 961-964, (1999).
  
• M. Tsuji, J. Matsunami and Y. Tamaura, “Selective removal of selenium in wastewater by hydrotalcite with higher layer charge”, Trans. Mater. Res. Soc. Jpn., 24[3], 357-360, (1999).
  
• Y. Tanaka，M. Tsuji and Y. Tamaura, “ESCA and thermodynamic studies of alkali metal ion exchange reactions on an α-MnO₂ phase with the tunnel structure“, Phys. Chem. Chem. Phys., 2, 1473-1479, (2000).
  
• M. Tsuji and Y. Tamaura, “Thermodynamic study of M⁺/H⁺ exchanges on a cryptomelane-type manganic acid“, Solvent Extr. Ion Exch., 18[1], 187-202, (2000.)
  
• N. Gokon, A. Shimada, H. Kaneko, Y. Tamaura, K. Ito and T. Ohara, “Magnetic Coagulation and Reaction Rate for the Aqueous Ferrite Formation Reaction“, Journal of Magnetism and Magnetic Materials, 238[1], 47-55, (2002)
  
• N. Gokon, A. Shimada, N. Hasegawa, H. Kaneko, Y. Tamaura, K. Ito and T. Ohara, “The magnetic coagulation reaction between paramagnetic particles and iron ions coprecipitates“, J. Magn. Magn. Mater., 246[1-2], 275-282, (2002).
  
• N. Gokon, A. Shimada, N. Hasegawa, H. Kaneko, M. Kitamura and Y. Tamaura, “Ferrimagnetic coagulation process for phosphate ion removal using high gradient magnetic separation“, Sep. Sci. Tech., 37[16], 3781-3791, (2003).
  
• N. Gokon, N. Hasegawa, H. Kaneko, T. Ohara and Y. Tamaura, “A high magnetic field effect on the M(II)-substituted magnetite formation (M = Ni, Mn, Co) in the wet process“, J. Magn. Magn. Mater., 256[1-3], 293-300, (2003).
  
• 郷右近展之、島田綾乃、松岡孝仁、金子宏、玉浦裕、小原健司、“フェリ磁性体を用いた環境水中のリン及び重金属イオンの磁気分離”水環境学会誌，25[1]，33-38，(2002)
  
• 郷右近展之，長谷川紀子，金子宏，玉浦裕，小原健司，“強磁場におけるFe²⁺/Fe³⁺懸濁溶液を用いた湿式フェライト生成反応”，粉体および粉末冶金，49[8], 710-716, (2002).

材料に関する研究

• H. Nakajima, H. Ishihara, Q. Shen, T. Toyoda, K. Itoh, H. Kaneko and Y. Tamaura，“Effect of Fe doping on photoluminescence of yttria-stabilized zirconia”，Journal of Alloys and Compounds，441(1-2), 255-258, (2007).
  
• H. Nakajima, K. Itoh, H. Kaneko and Y. Tamaura, ” Effects of Fe doping on crystalline and optical properties of yttria-stabilized zirconia”, Journal of Physics and Chemistry of Solids, 68 (10), 1946-1950, (2007)

その他

• Youkoh Kaizu, Yutaka Tamaura, Shuichiro Hirai, Kunio Yoshikawa and Noam Lior, “Editorial Introduction”, Energy, 30 (11-12), 2023-2024, (2005)

• 環境安全科学入門，玉浦裕 他，講談社サイエンティフィク，(1999)
  
• 集光太陽熱利用が拓く新エネルギー，玉浦裕 他，日本高温ソーラ熱利用協会，(1999)
  
• CO2削減に向けた次世代エネルギー技術ハンドブック，玉浦裕 他，リアライズ社，(2001)
  
• 水素利用技術集成，岩崎和市他監修，エヌ・ティー・エス，“集光太陽熱による水素製造技術”，玉浦裕，203-226, (2003)
  
• 赤外線加熱工学ハンドブック,小岩昌宏監修，アグネ技術センター，“フェライトによるソーラ水素生産技術開発研究”，玉浦裕，336-343, (2003)
  
• 理工系基礎化学,　玉浦裕　他,　講談社,　(2006)
  
• 炭素の辞典,　玉浦裕　他,　朝倉書店, (2007)
  
• エネルギーの地平を切り拓く50人, 玉浦裕　他,　環境新聞社, (2007)
  

• 玉浦裕、“太陽エネルギーと化石燃料とのハイブリッド利用”、エネルギー・資源、 20[5]、418-425、（1999）
  
• 玉浦裕、“ソーラハイブリッド燃料”、化学工学、63[3]、142-143、（1999）
  
• 玉浦裕、“ソーラ熱化学法によるソーラハイブリッド燃料生産”、粉体と工業、31[10]、47-58、（1999）
  
• 玉浦裕、“環境汚染物質の微量分析”、材料科学、36[3]、125-129、（1999）
  
• 玉浦裕、“高温ソーラーケミストリー”、太陽エネルギー、25[3]、19-28、（1999）
  
• 玉浦裕、“21世紀の太陽エネルギー　-ソーラー熱化学法によるソーラーハイブリッド燃料生産への道”、環境管理、36[1]、14-22、（2000）
  
• 玉浦裕、金子宏、“ソーラハイブリッド水素生産とサンベルト国際太陽エネルギービジネス－水素エネルギー時代へのソフトランディングシナリオ－”、日本機械学会誌、103[983]、 677-680、（2000）
  
• 玉浦裕、“化学系廃棄物の安全管理”、化学工業、51[10]、764-769、（2000）
  
• 玉浦裕、“次世代エネルギーとしての水素（第1回）水素エネルギー時代を開くソーラーハイブリッド燃料による実現シナリオ”、PETROTECH、25[1]、34-39、(2002)
  
• 玉浦裕、“東京工業大学における化学物質の安全科学教育”、化学と工業、54[12]、1401-1403、(2001)
  
• 玉浦裕, “フェライトによる集光太陽熱の水素変換”, 日本応用磁気学会誌, 26[11], 1114-1120 (2002)
  
• 玉浦裕, “CO₂削減技術と持続可能型社会”， 生物の化学　遺伝，別冊17，156-163，(2003)
• 玉浦裕, “安衛法をめぐる大学の安全教育のあり方”, 化学, 60[5], 40-43, (2005).
• 金子宏, 玉浦裕, “PRTR（化学物質排出移動量届出制度）”, 臨床病理レビュー特集　新改訂　医療廃棄物の適正処理マニュアル―感染性廃棄物を中心に―, 133, 174-176, (2005).