エネルギー材料統合研究センター

卓越型リサーチセンター

エネルギー材料統合研究センター

Research Center for Integrated Materials and Interfaces for Sustainable Energy

活動実績

論文

今西誠之(代表者)

欧文原著
  1. (1) Takagi K., Nonoyama T., Miyagawa R., Taminato S., Matsumoto M., Mori D., Imanishi N., Reversible lithium deposition/dissolution reaction with low polarization through a cross-linked polymer: Geometrical structure effects of the polymer protective layer on lithium metal anodes, Solid State Ionics, 386 (15) 116045 (2022).
  2. (2) Miyagawa R., Takeyoshi J., Kanamura K., Taminato S., Mori D., Imanishi N., Electrochemical Evaluation of Lithium Metal Batteries Using Separators with Different Pore Sizes, Electrochemistry, 90 (10) 107005 (2022).
  3. (3) Taminato S., Mori D., Takeda Y., Yamamoto O., Imanishi N., Composite Polymer Electrolytes for Lithium Batteries, ChemstrySelect, 7 (29) e202201667 (2022).
  4. (4) Mori D., Zhang T., Taminato S., Takeda Y., Yamamoto O., Imanishi N., Solid-State Lithium-Air Batteries, Solid State Batteries Volume 2: Materials and Advanced Devices, Chap. 11, pp. 249-265, Ed. R.K. Gupta, ACS Publications (2022).
  5. (5) Kamimoto K., Bai F., Mori D., Taminato S., Takeda Y., Yamamoto O., Izumi H., Minami H., Imanishi N., Water-stable high lithium-ion conducting Li1.4Al0.4Ge0.2Ti1.4(PO4)3-TiO2-LiCl•H2O-epoxy resin composite film with high mechanical strength as separator for Li-air batteries, Journal of Solid State Electrochemistry, 26 (3) 1349-1357 (2022).
  6. (6) Nakajima J., Ueda N., Taminato S., Mori D., Imanishi N., Higashimoto S., Matsuda Y., Synthesis and Proton Conductivity of the Mixed Cation Phosphate, KCo1-xH2x(PO3)3・yH2O with a One-dimensional Tunnel Structure, Journal of the Japan Society of Powder and Powder Metallurgy, 69 6603 (2022).
  7. (7) Ichida S., Mori D., Taminato S., Zhang T., Takeda Y., Yamamoto O., Imanishi N., A Rechargeable Aqueous Lithium-Air Battery with an Acetic Acid Catholyte Operated at High Pressure, Journal of Energy and Power Technology, 4 (3) doi:10.21926/jept.2201009 (2022).
  8. (8) Ye RJ., Ihrig M., Imanishi N., Finsterbusch M., Figgemeier E., A Review of Li+/H+ Exchange in Garnet Solid Electrolytes: From Instablity against Humidity to Sustainable Processing in Water, ChemSusChem, 14 4397-4407 (2021)
  9. (9) Ueda N., Nakajima J., Mori D., Taminato S., Imanishi N., Higashimoto S., Matsuda Y., High proton conductivity in NaMg1-xLixHx(PO3)3・yH2O with a three-dimensional open framework in the intermediate temperature range, Materials Advances, 2 6603 (2021)
  10. (10) Minami H., Izumi H., Hasegawa T., Bai F., Mori D., Taminato S., Takeda Y., Yamamoto O., Imanishi N., Aqueous Lithium--Air Batteries with High Power Density at Room Temperature under Air Atmosphere, Journal of Energy and Power Technology, 3 (3) 2103041 (2021)
  11. (11) Sun Z., Zhao X., Qiu W., Yang C., Yamamoto O., Imanishi N., Liu J., Zhang T., Partial Disproportionation Gallium-Oxygen Reaction Boosts Lithium-Oxygen Batteries, Energy Storage Materials, 41, 475-484 (2021)
  12. (12) Mizoguchi T., Sonoki H., Niwa E., Taminato S., Mori D., Takeda Y., Yamamoto O., Imanishi N., K2NiF4 type Ln2-xSrxNiO4+δ (Ln = La and Pr; x = 0-0.14) as an oxygen electrocatalyst for aqueous lithium-oxygen rechargeable batteries, Solid State Ionics, 369, 115708 (2021)
  13. (13) Imanishi N., Zhang T., Mori D., Taminato S., Takeda Y., Yamamoto O., Lithium Metal Anode for High-Power and High-Capacity Rechargeable Batteries, Journal of Energy and Power Technology, 3 (2) 2102019 (2021)
  14. (14) Li Y.N., Jiang F.L., Sun Z., Yamamoto O., Imanishi N., Zhang T., Bifunctional 1‐Boc-3-Iodoazetidine Enhancing Lithium Anode Stability and Rechargeability of Lithium-Oxygen Batteries, ACS Applied Materials & Interfaces, 13, 16437 (2021)
  15. (15) Shimonishi Y., Mori D., Maeda Y., Taminato S., Imanishi N., Yoshida S., Investigation of the Difference in Charge/Discharge Resistance for Cathode Materials after Cycle Test Combined with STEM-EELS and XAFS Analysis, Journal of The Electrochemical Society, 168, 040533 (2021)
  16. (16) Takagi H., Kakimoto K., Mori D., Taminato S., Takeda Y., Yamamoto O., Imanishi N., High Energy Density Rechargeable Aqueous Lithium Batteries with an Aqueous Hydroquinone Sulfonic Acid and Benzoquinone Sulfonic Acid Redox Couple Cathode, Journal of Energy and Power Technology, 3 (1) 2101010 (2021)
  17. (17) Bai F., Kakimoto K., Shang X.F., Mori D., Taminato S., Matsumoto M., Takeda Y., Yamamoto O., Izumi H., Minami H., Imanishi N., Water-Stable High Lithium-Ion Conducting Solid Electrolyte of Li1.4Al0.4Ge0.2Ti1.4(PO4)3-LiCl for Aqueous Lithium-Air Batteries, frontiers in Energy Research, 8, 187(1-9) (2020)
  18. (18) Kanamori S., Matsumoto M., Taminato S., Mori D., Takeda Y., Hah H.J., Takeuchi T., Imanishi N., Lithium metal deposition/dissolution under uniaxial pressure with high-rigidity layered polyethylene separator, RSC Advances, 10, 17805-17815 (2020)
  19. (19) Soga S., Bai F., Zhang T., Kakimoto K., Mori D., Taminato S., Takeda Y., Yamamoto O., Imanishi N., Ambient Air Operation Rechargeable Lithium-Air Battery with Acetic Acid Catholyte, Journal of The Electrochemical Society, 167, 090522 (2020)
  20. (20) Zhang Y.P., Li Y.Q., Cui Z.H., Wang J.C., Yamamoto O., Imanishi N., Zhang T., A porous framework infiltrating Li-O2 battery: a low-resistance and high-safety system, Sustainable Energy Fuels, 4, 1600-1606 (2020)
  21. (21) Bai F., Kakimoto K., Shang X.F., Mori D., Taminato S., Matsumoto M., Takeda Y., Yamamoto O., Minami H., Izumi H., Imanishi N., Synthesis of NASICON-type Li1.4Al0.4Ge0.2Ti1.4(PO4)3 solid electrolyte by rheological phase method, Journal of Asian Ceramic Societies, 8, (2020)
  22. (22) Matsuda Y., Funakoshi K., Sebe R., Kobayashi G., Yonemura M., Imanishi N., Mori D., Higashimoto S., Arrangement of water molecules and high proton coductivity of tunnel strcture phosphates, KMg1-xH2x(PO4)3・yH2O, RSC Advances, 10, 7803-7811 (2020)
  23. (23) Bai F., Mori D., Taminato S., Takeda Y., Yamamoto O., Nemori H., Nomura M., Imanishi N., Electrical and mechanical properties of water stable NASICON-type Li1+xAlxGe0.2Ti1.8-x(PO4)3, Solid State Ionics, 345, 115151 (2020)
  24. (24) Fujimoto S., Uemura S., Imanishi N., Hirai S., Oxygen Concentration Measurement in the Porous Cathode of a Lithium-Air Battery using a Fine Optical Fiber Sensor, Mechanical Engineering Letter, 5, 19-00095 (2019)
  25. (25) Imanishi N., Yamamoto O., Perspective and challenges of rechargeable lithium-air batteries, Materials Today Advances, 4, 100031 (2019)
  26. (26) Sonoki H., Matsui M., Imanishi N., Effect of Anion Species in Early Stage of SEI Formation Process, Journal of The Electrochemical Society, 166, A3593-A3598 (2019)
  27. (27) Sonoki H., Mori D., Taminato S., Takeda Y., Yamamoto O., Imanishi N., A hydrated strontium cobalt oxyhydroxide Ruddlesden-Popper phase as an oxygen electrocatalyst for aqueous lithium-oxygen rechargeable batteries, Chemical Communications, 55, 7454-7457 (2019)
  28. (28) Bai F., Shang X., Mori D., Taminato S., Matsumoto M., Watanabe S., Takeda Y., Yamamoto O., Nemori H., Nomura M., Imanishi N., High lithium-ion conducting solid electrolyte thin film of Li1.4Al0.4Ge0.2Ti1.4(PO4)3-TiO2 for aqueous lithium secondary batteries, Solid State Ionics, 338, 127-133 (2019)
  29. (29) Koizumi Y., Mori D., Taminato S., Yamamoto O., Takeda Y., Imanishi N., Lithium-stable NASICON-type lithium-ion conducting solid electrolyte film coated with a polymer electrolyte, Solid State Ionics, 337, 101-106 (2019)
  30. (30) Watanabe S., Mori D., Taminato S., Matsuda Y., Yamamoto O., Takeda Y., Imanishi N., Aqueous Lithium Rechargeable Battery with a Tin(II) Chloride Aqueous Cathode and a Water-Stable Lithium-Ion Conducting Solid Electrolyte, Journal of The Electrochemical Society, 166, A539-A545 (2019)
  31. (31) Eijima S., Sonoki H., Matsumoto M., Taminato S., Mori D., Imanishi N., Solid Electrolyte Interphase Film on Lithium Metal Anode in Mixed-Salt System, Journal of The Electrochemical Society, 166, A5421-A5429 (2019)
  32. (32) Matsui M., Kuwata H., Mori D., Imanishi N., Mizuhata M., Destabilized Passivation Layer on Magnesium-Based Intermetallics as Potential Anode Active Materials for Magnesium Ion Batteries, frontiers in Chemistry, 7, 7 (2019)
  33. (33) Mori D., Sugimoto K., Matsuda Y., Ohmori K., Katsumata T., Taminato S., Takeda Y., Yamamoto O., Imanishi N., Synthesis, structure and ionic conductivity of garnet like lithium ion conductor Li6.25+xGa0.25La3-xSrxZr3O12, Journal of The Electrochemical Society, 166, A5168-A5173 (2019)
  34. (34) Sakakibara T., Kitamura M., Honma T., Kohno H., Uno T., Kubo M., Imanishi N., Takeda Y., Itoh T., Cross-linked polymer electrolyte and its application to lithium polymer battery, Electrochimica Acta, 296, 1018-1026 (2019)
  35. (35) Bai, F. Shang X., Nemori H., Nomura M., Mori D., Matsumoto M., Kyono N., Takeda Y., Yamamoto O., Imanishi N., Lithium-ion conduction of Li1.4Al0.4Ti1.6(PO4)3-GeO2 composite solid electrolyte, Solid State Ionics, 329, 40-45 (2019)
  36. (36) Wang X., Zhang P., Wang T., Yamamoto O., Imanishi N., Wang M., Facile synthesis of mesoporous NiCo2O4 nanoneedle arrays on three dimensional graphene thin film grown on Ni foam for a high-performance binder-free lithium-ion battery anode, Journal of Electroanalytical Chemistry, 823, 545-552 (2018)
  37. (37) Kyono N., Bai F., Nemori H., Minami H., Mori D., Takeda Y., Yamamoto O., Imanishi N., Lithium-ion conducting solid electrolytes of Li1.4Al0.4Ge0.2Ti1.4(PO4)3 and MOx (M = Al, Ti, and Zr) composites, Solid State Ionics, 324, 114-127 (2018)
  38. (38) Furusawa H., Konishi R., Mori D., Horino H., Horiba T., Takeda Y., Takada J., Yamamoto O., Imanishi N., Biogenous iron oxide (L-BIOX) as a high capacity anode material for lithium ion batteries, Electrochimica Acta, 281, 227-236 (2018)
  39. (39) Kuwata H., Matsui M., Sonoki H., Manabe Y., Imanishi N., Mizuhata M., Improved cycling performance of intermetallic anode by minimized SEI layer formation, Journal of The Electrochemical Society, 165, A1486-A1491 (2018).
  40. (40) Morita Y., Watanabe S., Mori D., Takeda Y., Yamamoto O., Imanishi N., High-energy-density rechargeable lithium-nickel chloride aqueous solution batteries, ACS Omega, 3, 5558-5562 (2018)
  41. (41) Zhang P., Yang X., Wang T., Imanishi N., Yamamoto O., Wang M., A novel hybrid positive electrode with liquid-solid redox couples having high-capacity for lithium battery, Journal of Power Sources, 390, 54-60 (2018)
  42. (42) Nemori H., Shang X., Minami H., Mitsuoka S., Nomura M., Sonoki H., Morita Y., Mori D., Takeda Y., Yamamoto O., Imanishi N., Aqueos lithium-air batteries with a lithium-ion conducting solid electrolyte Li1.3Al0.5Nb0.2Ti1.3(PO4)3, Solid State Ionics, 317, 136-141 (2018)
  43. (43) Zhang P., Zhu J., Wang M., Imanishi N., Yamamoto O., Lithium dendrite suppression and cycling efficiency of lithium anode, Electrochemistry Communications, 87, 27-30 (2018)
  44. (44) Mori D., Yahia H.B., Shikano M., Imanishi N., Inaguma Y., Belharouak I., Low temperature synthesis, structure and magnetic properties of Mn2[VO4]F, Journal of Asian Ceramic Societies, 5, 460-465 (2017)
  45. (45) Kuwata H., Matsui M., Imanishi N., Passivation Layer Formation of Magnesium Metal Negative Electrodes for Rechargeable Magnesium Batteries, Journal of The Electrochemical Society, 164, A3229-A3236 (2017)
  46. (46) Si Q., Mori D., Takeda Y., Yamamoto O., Imanishi N., Silicon-Carbon Composite Electrode Materials Prepared by Pyrolysis of a Mixture of Manila Hemp, Silicon Powder, and Flake Artificial Graphite for Lithium Batteries, Energies, 10, 1803 (2017)
  47. (47) Matuda Y., Sakaida A., Sugimoto K., Mori D., Takeda Y., Yamamoto O., Imanishi N., Sintering behavior and electrochemical properties of garnet-like lithium conductor Li6.25M0.25La3Zr2O12 (M: Al3+ and Ga3+), Solid State Ionics, 311, 69-74 (2017)
  48. (48) Morita Y., Watanabe S., Zhnag P., Wang H., Mori D., Matsuda Y., Yamamoto O., Takeda Y., Imanishi N., High Specific Energy Density Aqueous lithium-Metal Choloride Rechargeable Batteries, Journal of The Electrochemical Society, 164, A1958-A1964 (2017)
  49. (49) Wang H., Matsui M., Kuwata H., Sonoki H., Matsuda Y., Shang X.F., Takeda Y., Yamamoto O., Imanishi N., A reversible dendrite-free high-areal-capacity lithium metal electrodes, Nature communications, 8, 15106 (2017)
欧文原著
  1. (1) 武田 保雄, 松田 泰明, 森 大輔, 今西 誠之, ガーネット型リチウムイオン導電体 - 酸化物系全固体電池の電解質として, "全固体電池の基礎理論と開発最前線", 第4章, 42-56ページ, 菅野 了次 編, CMC リサーチ (2018)
  2. (2) 久保山 正志, 古澤 誉, 森 大輔, 武田 保雄, 山本 治, 旭野 欣也, 上谷 謙二, 今西 誠之, 超残光性蛍光体SrAl2O4:Eu3+, Dy3+の特性に及ぼすアルミナ原料の影響, 粉体および粉末冶金, 65, 176-182 (2018)

久保雅敬(代表的教員)

欧文原著
  1. (1) Ifraan D, Kubo M, Yusuf N N A N, Hakim A, Manisah R, Abdullah N, Solubilization of Reduced Graphene Oxide by Grafting-on Poly(2-methyl-2-oxazoline). Journal of Physics: Conference Series 12067 (2021)
  2. (2) Abdullah N, Ifraan D, Yahya N A M, Hashim N, Abdullah S, Mohamed R M, Kubo M, Covalent Functionalization of Reduced Graphene Oxide Using Azido-Terminated Poly(2-isopropyl-2-oxazoline). Journal of Physics: Conference Series 1532 (2020)
  3. (3) Watanabe R, Noba M, Uno T, Itoh T, Kubo M, Preparation of Polypseudorotaxane Composed of Linear and Cyclic Polyethylene Oxides and Its Application to Solid Polymer Electrolyte. Journal of Polymer Science: Part A: Polymer Chemistry, 58, (2020)
  4. (4) Itoh T, Yamamura M, Fukushima T, Washio Y, Uno T, Kubo M, Tohnai N, Miyata M, Bundle Assemblies Formation of Alternating Copolymer: Alternating Copolymerization of Symmetrical Substituted p-Quinodimethanes with Asymmetrical N,7,7-tricyanoquinone Methide Imine in Solid State. European Polymer Journal, 125, 109539 (2020)
  5. (5) Ando D, Ijichi J, Uno T, Itoh T, Kubo M, Preparation of Donor-Acceptor Polyfluorenes with Pendant Carboxyl or Amine Functionalities and Their Photoluminescence Properties. Polymer Bulletin, 76, 6137 (2019)
  6. (6) Sakakibara T, Kitamura M, Honma T, Kohno H, Uno T, Kubo M, Imanishi N, Takeda Y, Itoh T, Cross-Linked Polymer Electrolyte and Its Application to Lithium Polymer Battery. Electrochimica Acta, 296, 1018 (2019)
  7. (7) Itoh T, Nakamura K, Uno T, Kubo M, Thermal and Electrochemical Properties of Poly(2,2-dimethoxypropylene carbonate)-Based Solid Polymer Electrolyte for Polymer Battery. Solid State Ionics, 317, 69 (2018)
  8. (8) Itoh T, Niihara S, Uno T, Kubo M, Thermal and Electrochemical Properties of Poly(butylene sulfite)-Based Polymer Electrolyte. Ionics, 24, 2287 (2018)
  9. (9) Itoh T, Kondo F, Uno T, Kubo M, Tohnai N, Miyata M, Exclusive Formation of Bridge-Substituted [2.2]Paracyclophane by Topochemical Photocycloaddition Reaction of Unsymmetrical Substituted p-Quinodimethane. Crystal Growth & Design, 17, 3606 (2017)
  10. (10) Uno T, Yamamoto S, Yamane A, Kubo M, Itoh T, Asymmetric Anionic Polymerizations of 7-(o-Substituted phenyl)-2,6-dimethyl-1,4-benzoquinone Methides: Electrostatic Interaction and Steric, Inductive, and Resonance Effects of the ortho-Substituent on the Optical Activity, Journal of Polymer Science :Part A: Polymer Chemistry, 55, 1048 (2017)
  11. (11) Uryu Y, Uno T, Itoh T, Kubo M, A Ternary Composite Based on Polystyrene Sulphonic Acid, Organic Dye and Hygroscopic Inorganic Salt for Cobalt-Free Humidity Indicating Agent. Materials Research Innovations 21, 331 (2017)
  12. (12) Itoh T, Fujita K, Uno T, Kubo M, Polymer Electrolytes Based on Vinyl Ethers with Various EO Chain Length and Their Polymer Electrolytes Cross-Linked by Electron Beam Irradiation. Ionics, 23, 257 (2017)
欧文原著
  1. (1) 久保雅敬, ラジカル重合を中心としたポリマー・微粒子・コーティング剤の合成、応用、トラブル対策. 技術情報協会 (2020)
  2. 久保雅敬, 環状高分子の合成と機能発現. シーエムシー出版 (2018)

鳥飼直也(代表的教員)

欧文原著
  1. (1) Yamaoka, K., Yamada, N. L., Hori, K., Fujii, Y., Torikai, N. Interfacial Selective Study on the Gelation Behavior of Aqueous Methylcellulose Solution via a Quartz Crystal Microbalance. Langmuir 38 (15), 4494-4502 (2022)
  2. (2) Yamaoka, K., Fujii, Y., Torikai, N. Investigating Localized Gelation Behavior of an Aqueous Methylcellulose Solution using a Quartz Crystal Microbalance. Mater. Trans. 62 (5) 647-654 (2021)
  3. (3) Iguchi, M., Fujii, Y., Hori, K., Nemoto, F., Torikai, N. Thermal Stability and Interfacial Segregation for Polymer Thin Films Blended with a Homologue Having Different Tacticity. JPS Conf. Proc., 33, 011081 (2021)
  4. (4) Honda, T., Nishikawa, G., Fujii, Y., Inada, S., Iwase, H., Torikai. N. Adsorbed Polymer Effects on Particle Dispersion in Polymeric Matrix Examined by SANS. JPS Conf. Proc., 33, 011082 (2021)
  5. (5) Pruksawan, S., Samitsu, S., Fujii, Y., Torikai, N., Naito, M. Toughening Effect of Rodlike Cellulose Nanocrystals in Epoxy Adhesive. ACS Appl. Polym. Mater., 2 (3), 1234-1243 (2020)
  6. (6) Miyazaki, M., Miyata, N., Yoshida, T., Arima, H., Tsumura, Y., Torikai, N., Aoki, H., Yamamoto, K., Kanaya, T., Kawaguchi, D., Tanaka K. Detailed Structural Study on the Poly(vinyl alcohol) Adsorption Layers on a Si Substrate with Solvent Vapor-Induced Swelling. Langmuir 36 (13), 3415-3424 (2020)
  7. (7) Fukunaga, Y., Fujii, Y., Inada, S., Tsumura, Y., Asada, M., Naito, M., Torikai, N. Dispersion State of Carbon Black in Polystyrene Produced by Different Dispersion Media and Its Effects on the Composite Rheological Properties. Polym. J., 51, 275-281 (2019)
  8. (8) Kumada, T., Akutsu, K., Ohishi, K., Morikawa, T., Kawamura, Y., Sahara, M., Suzuki, J., Torikai, N. Development of spin-contrast-variation neutron reflectometry for the structural analysis of multilayer films. J. Appl. Cryst., 52, 1054-1060 (2019)
  9. (9) Miyazaki, T., Miyata, N., Asada, M., Tsumura, Y., Torikai, N., Aoki, H., Yamamoto, K., Kanaya, T., Kawaguchi, D., Tanaka K. Elucidation of Heterogeneous Layered Structure in the Thickness Direction of Poly(vinyl alcohol) Films with Solvent Vapor-Induced Swelling. Langmuir, 35 (34), 11099-11107 (2019)
  10. (10) Kumada, T., Akutsu, K., Ohishi, K., Morikawa, T., Kawamura, Y., Sahara, M., Suzuki, J., Torikai, N. Development of Dynamic Nuclear Polarization System for Spin-Contrast-Variation Neutron Reflectometer. JPS Conf. Proc., 22, 011015 (2018)
  11. (11) Kumada, T., Akutsu, K., Ohishi, K., Kawamura, Y., Morikawa, T., Sahara, M., Suzuki, J., Torikai, N. Development of closed-cycle dynamic nuclear polarization system for small-angle neutron scattering and neutron reflectometry. Proc. Sci., 009 (2018)
  12. (12) Nakajima, K., Kawakita, Y., Itoh, S., Abe, J., Aizawa, K., Aoki, H., Endo, H., Fujita, M., Funakoshi, K., Gong, W., Harada, M., Harjo, S., Hattori, T., Hino, M., Honda, T., Hoshikawa, A., Ikeda, K., Ino, T., Ishigaki, T., Ishikawa, Y., Kai, T., Kajimoto, R., Kamiyama, T., Kaneko, N., Kawana, D., Ohira-Kawamura, S., Kawasaki, T., Kimura, A., Kiyanagi, R., Kojima, K., Kusaka, K., Lee, S., Machida, S., Masuda, T., Mishima, K., Mitamura, K., Nakamura, M., Nakamura, S., Nakao, A., Oda, T., Ohhara, T., Ohshita, H., 6104-866-1, K., Otomo, T., Sano-Furukawa, A., Shibata, K., Shinohara, T., Soyama, K., Suzuki, J., Suzuya, K., Takahara, A., Takata, S., Takeda, M., Toh, Y., Torii, S., Torikai, N., Yamada, N. L., Yamada, T., Yamazaki, D., Yokoo, T., Yonemura, M., Yoshizawa, H. Materials and Life Science Experimental Facility (MLF) at J-PARC. II - Neutron Scattering Instruments-. Quantum Beam Sci., 1 (3), 9-1-59 (2017)
欧文原著
  1. (1) 鳥飼直也. 4. 分析・試験法編 E. 表面・界面物性「4-39 表面構造」,pp. 470-471. 高分子材料の事典. 朝倉書店. ISBN: 978-4-254-25272-9 (2022)
  2. (2) 鳥飼直也. 第1章第1節 高分子/フィラーの分散・凝集状態とその評価,pp. 3-10. 樹脂/フィラー複合材料の界面制御と評価. 技術情報協会. ISBN: 978-4-86104-822-1 (2022)
  3. (3) 鳥飼直也. 第2章第13節 動的粘弾性測定による高分子コンポジットの構造,物性評価,pp. 200-207. 動的粘弾性測定とそのデータ解釈・事例集. 技術情報協会. ISBN: 978-4-86104-866-1 (2021)
  4. (4) 鳥飼直也. 第3章 ブロック共重合体の界面・薄膜構造, pp. 30-45. ブロック共重合体の構造設計と応用展開. シーエムシー出版. ISBN: 978-4-7813-1351-1 (2018)

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