Publication

  • Before 2017

    19. A. Abumazwed, W. Kubo, T. Tanaka, and A. G. Kirk ,”Improved self-referenced biosensing with emphasis on multiple-resonance nanorod sensors”,Optics Express, 25, 24803-24815, 2017.

    18. W. Kubo* “Effect of Au nanoparticles on PCPDTBT:PC71BM device performance with fair comparisons”, Physica Status Solidi A, 214, 1700110-n/a, 2017.

    17. A. Abumazwed, W. Kubo, C. Shen, T. Tanaka, and A. G. Kirk ,”Projection method for improving signal to noise ratio of localized surface plasmon resonance biosensors”, Biomedical Optics Express, 8, 1, 446-459, 2017.

    16. W. Kubo*, Y. Yokota, and T. Tanaka, “Au nanodot lattices with well-controlled in size and density for thin organic solar cells”, Physica Status Solidi-Rapid Research Letters, 9, 348-352, 2015.

    15. L. Olislager, W. Kubo, T. Tanaka, S. Ungureanu, R. A. L. Vallee, B. Kolaric, P. Emplit, and S. Massar, “Propagation and survival of frequency-bin entangled photons in metallic nanostructure”, Nanophotonics, 4, 324-331, 2015.

    14. X. Fang, S.Yaginuma, W. Kubo, T. Tanaka, “Resonance enhancement of difference-frequency generation through localized surface plasmon excitation”Applied Physics Letters, 102, 203101-203103, 2013.

    13. W. Kubo, S. Fujikawa, “Au double nanopillars with nanogap for plasmonic sensor”Nano Letters, 11, 8-15, 2011.[Link]

    12. W. Kubo, H. Hayakawa, K. Miyoshi, S. Fujikawa, “Size-controlled simple fabrication of free-standing, ultralong metal nanobelt array”, Journal of Nanoscience and Nanotechnology, 11, 131-137, 2011.

    11. F. Yang, W. Kubo, N. Sakai, T. Tatsuma, “Acceleration of photocatalytic remote oxidation by deposition of Pt nanoparticles onto TiO<sub>2</sub>Electrochemistry, 78, 161-164, 2010.

    10. W. Kubo, S. Fujikawa, “Manipulation of a One Dimensional Molecular Assembly of Helical Superstructures by Dielectrophoresis”, Applied Physics Letters, 95, 163110-1-3, 2009.

    9. W. Kubo, S. Fujikawa,“Embedding of a Gold Nanofin Array in a Polymer Film to Create Transparent, Flexible and Anisotropic Electrodes”, Journal of Materials Chemistry, 19, 2154-2158, 2009.

    8. T. Tatsuma, W. Kubo, “Photocatalytic lithography based on photocatalytic remote oxidation”, Journal of Photopolymer Science and Technology, 20, 83-86, 2007.

    7. W. Kubo, T. Tatsuma, “Mechanisms of Photocatalytic Remote Oxidation” Journal of the American Chemical Society, 128, 16034-16035, 2006.

    6. W. Kubo, T. Tatsuma, “Photocatalytic remote oxidation with various photocatalysts and enhancement of its activity” Journal of Materials Chemistry, 15, 3104-3108, 2005.

    5. H. Notsu, W. Kubo, S. Shitanda, T. Tatsuma, “Super-hydrophobic/super-hydrophilic patterning of gold surfaces by photocatalytic lithography”, Journal of Materials Chemistry, 15, 1523-1527, 2005.

    4. W. Kubo, T. Tatsuma, “Conversion of a solid surface from super-hydrophobic to super-hydrophilic by photocatalytic remote oxidation and photocatalytic lithography” Applied Surface Science, 243, 125-128, 2005.

    3. W. Kubo, T. Tatsuma, “Detection of H2O2 released from TiO2 photocatalyst to air” Analytical Sciences, 20, 591-593, 2004.

    2. W. Kubo, T. Tatsuma, A. Fujishima, H. Kobayashi, “Mechanisms and Resolution of Photocatalytic Lithography” The Journal of Physical Chemistry B, 108, 3005-3009, 2004.

    1. T. Tatsuma, W. Kubo, A. Fujishima, “Patterning of solid surfaces by photocatalytic lithography based on the remote oxidation effect of TiO<sub>2</sub>” Langmuir, 18, 9632-9634, 2002.

  • Review Papers

    18. 久保若奈 “メタマテリアル熱電変換とその展開”, Optronics, 514 (10), 98-102, 2024.

    17. 久保若奈, “メタマテリアルによる熱電変換”, 応用物理 93 (9), 531, 2024.

    16. W. Kubo, “Metamaterial Thermoelectric Conversion”, Chapter 6, Thermal Plasmonics and Metamaterials for a Low-Carbon Society, 104-116, 2024.

    15. 久保若奈,田中拓男,”均一な熱輻射環境におけるメタマテリアル熱電発電”, レーザー研究, 第51巻2号, 2023.

    14. 久保若奈,田中拓男,”メタマテリアル熱電変換”, 機能材料, 2023年1月, 2023

    13. 久保若奈, “メタマテリアル熱電変換”,OPTRONICS 11月号.

    12. 久保若奈, “メタマテリアル光電変換素子”, メタマテリアル・メタサーフェスの設計・応用最新技術, 2020.8 (分担執筆)

    11. 久保若奈 “ナノコーティングリソグラフィー法”日本写真学会誌, 80, 289-291, 2017.

    10. 久保若奈, “金ナノドット格子構造と金ナノ粒子のプラズモン共鳴を利用した有機薄膜太陽電池“ 太陽光と光電変換機能,261-267, 2016 ,分担執筆

    9. 久保若奈,“プラズモニックナノ構造体を利用した太陽電池”応用物理学会有機分子・バイオエレクトロニクス分科会会誌,26(2), 73-76, 2015.

    8. 久保若奈”エネルギーデバイスに向けた光メタマテリアルの加工技術”月刊オプトロニクス,392, 50-54, 2014

    7. 久保若奈“ナノコーティングリソグラフィー法による金二重ナノピラー構造の作製と展開”Colloid & Interface Communication, 37, 28-29,2012.

    6. 久保若奈, 藤川茂紀, 田中拓男 “金ナノフィンによるフレキシブル透明導電膜”, ナノ学会会報, 10(2), 63-67,2012.

    5. 久保若奈, 藤川茂紀 “ナノコーティングリソグラフィによるナノギャップ型プラズモンセンサ素子の大面積作製” プラズモニクス光電子デバイス開発最前線 p.147-155, 2011.

    4. 久保若奈, 藤川茂紀 ”ナノコーティングリソグラフィーによる金二重ナノピラー配列の作製とプラズモンセンサーへの展開”  未来材料, 11(5), 60-63, 2011.

    3. 立間 徹, 久保若奈 “光触媒の非接触酸化反応と二重励起機構”産業と環境, 3, 34-36, 2005.

    2. 久保若奈, 立間 徹“光触媒リソグラフィー法” 応用セラミックス, 39(7), 548-551, 2004.

    1. 立間 徹, 久保若奈“非接触酸化反応と光触媒リソグラフィー法, 工業材料 50(7), 69-72 2002

  • Invited Talk

    48. W. Kubo, “Visualization of Thermal Absorption by a Metamaterial Absorber”, SPIE Optics & Photonics, San Diego, USA. 2025.8.3.

    47. W. Kubo, “Nonradiative Cooling”, META2025, Tremolinos, Spain, 2025.7.20.

    46. W. Kubo, “Visualization of Thermal Absorption by a Metamaterial Absorber”, A3 Metamaterial forum, Korea, 2025.7.3.

    45. W. Kubo, “Metamaterial thermoelectric conversion and nonradiative cooling”, 2025 Taiwan Physical Society Annual Meeting (TPS2025), Kaohsiung, Taiwan, 2025.1.15.

    44. W. Kubo, “Metamaterial Thermoelectric Conversion“, SPIE Photonics Asia, Nantong, Jiangsu, China, 2024.10.13

    43. W. Kubo, “Metamaterial Thermal Engineering”, University of Birmingham seminar, 2024.8.27

    42. W. Kubo, “Optical wireless power through metamaterial thermoelectric conversion“, SPIE Optics+Photonics, 2024, San Diego, USA, 2023. 8. 20.

    41. W. Kubo, “Non-radiative cooling”, META2024, Toyama, Japan, 2024. 7. 16.

    40. W. Kubo, “Metasurface thermoelectric power generation”, IUMRS, HongKong, China, 2024. 5.18.

    39. W. Kubo, “Metamaterial Energy Harvesting”, Meta-lens World Summit 2023, 2023, Hong Kong, China, 2023. 12. 20.

    38. W. Kubo, “Metamaterial thermal management -from power generation to non-radiative cooling-“, Optics & Photonics Japan 2023, OSJ-JSAP Joint Symposium, Hokkaido, Japan, 2023. 11. 28.

    37. W. Kubo, “Metamaterial Thermal Management”, SPIE Optics+Photonics, 2023, San Diego, USA., 2023. 8. 23

    36. W. Kubo, “Metamaterial Thermoelectric Conversion”, META2023, Paris, France, 2023. 7. 19.

    35. W. Kubo, “Metamaterial thermal engineering technique”, Thermal Polaritonics Workshop, The Univ. of Tokyo, 2023. 4. 7.

    34. W. Kubo, “Metamaterial Thermoelectric Conversion”, ACP/IPOC2022, Shenzhen, China, 2022. 11. 8 (online)
    33. W. Kubo, “Metamaterial Energy Harvesting”, SPIE Optics+Photonics, 2022, San Diego, USA., 2022. 8. 21
    32. W. Kubo, “Plasmonic Energy Harvesting”, APNFO, 2022, Sapporo, Japan, 2022. 7. 29
    31. W. Kubo, “Plasmonic Energy Harvesting”, META2022, 2022, Spain, 2022. 7. 20
    30. W. Kubo, “Metamaterial Thermoelectric Conversion”, A3 Metamaterial, 2022, Seoul, 2022. 6. 28
    29. W. Kubo, “Metamaterial Energy Harvesting”, SPIE Europe, 2022, online, 2022. 4. 7

    28. W. Kubo, “Metamaterial Thermoelectric Conversion”, GNP, Osaka, 2022.3.15.

    27. W. Kubo, “Plasmonic Energy Convresion (tentative)”, OPJ Joint symposia on Optics, 2021, online, 2021. 10. 29
    26. W. Kubo, “ Metamaterial thermoelectric Convresion”, KJF-ICOMEP 2021, online, 2021. 8. 29
    25. W. Kubo, “ Metamaterial thermoelectric Convresion”, SPIE Nanoscience and Nanotechnology, online, 2021. 8. 1
    24. W. Kubo, “Plasmonic Photo-thermoelectric Convresion (tentative)”, Meta2021, online, 2021. 7. 20
    23. W. Kubo, “Metamaterial thermoelectric convresion”, ALPS, online, 2021. 4. 20
    22. W. Kubo, “Photoelectric Conversion via Local Heating”, SYMPOSIUM: The Casimir Effect: Where Chemistry and Biology meet Quantum Technology, online, 2020. 10. 29Web page
    21. W. Kubo, “Metamaterial perfect absorber for increasing thermal gradient across thermoelectric device”, SPIE Optics+Photonics Nanoscience Engineering, online, 2020. 8. 26
    20. W. Kubo, “Photoelectric Conversion via Plasmonic Local Heat”, GNR, Taipei, Taiwan, 2019. 12. 10
    19. W. Kubo, “Plasmonic Energy Conversion”, OptoX-Nano, Okayama, Japan, 2019. 12. 4
    18. W. Kubo, “Plasmonic local heat as a resource for energy conversion”, iSPN, Kobe, Japan, 2019. 11. 14
    17. W. Kubo, “Plasmonic Photodetector driven by Plasmonic Local Heat”, Metamaterials2019, Roma, Italy, 2019. 9. 16
    16. W. Kubo“Photoelectric conversion via plasmonic nanohole arrays” SPIE, San Diego, USA, 2019.8. 11
    15. W. Kubo”Correlation between Light Absorption and External Quantum Efficiency of Metamaterial Perfect Absorber Solar Cell”, META 2019, Lisbon, Portugal, 2019. 7. 23.
    14. W. Kubo, “Plasmonic Photodetector vis Local Heat”, OSA-OSK-OPJ joint symposium, Busan, Korea, 2019. 7. 16.
    13. W. Kubo, “Metamaterial Perfect Absorber Solar Cell” SPIE,San Diego, USA, 2018. 8.19.
    12. W. Kubo”Local Heat in Plasmonic Metmaterials” A3 Metamaterial symposium, Korea, 2018. 8. 13
    11. W. Kubo and M. Kondo “Thermoelectric Conversion Triggered by Plasmon” PIERS in Toyama, Toyama, Japan, 2018. 8. 3
    10. W. Kubo”Switching Triggered by Plasmonic Nanoheater” OSA-JSAP Joint Symposium, Fukuoka, Japan, 2017.9.5.
    9. W. Kubo “Designing Material Properties by using Plasmons” Southampton ECS Nano seminar, Southampton, UK, 2017.7.4.
    8. W. Kubo“Manipulation of VO2 Phase Transition Tmeperature by Plasmon Resonance of Au Nanorods” Energy Material Nanotechnology Metamaterials, Dubrovnik, Croatia, 2016.5.10
    7. W. Kubo,“Light Management by Plasmonic Metamaterials for Organic Solar Cells”Energy Materials Nanotechnology 2015 fall meeting, Las Vegas, USA, 2015.11.17
    6. W. Kubo”Fabrication of Metamaterials and its Application toward Energy Devices” ICCES’15, International Conference on Computational & Experimental Engineering and Sciences, Reno, USA, 2015.7.22
    5. W. Kubo,“Metal Nanostructures for Energy Materials” SJTU-RIKEN Workshop, Shanghai, China, 2013.10.26
    4. W. Kubo. “Large-scale Fabrication of Nanostructures with Metals and Metal Oxides.”The 7th International Conference on the Science and Technology for Advanced Ceramics(STAC-7), Yokohama, Japan, 2013.6.19
    3. W. Kubo”Large-scale Fabrication of Plasmonic Nanostructures toward Practical Device”The 7th International Conference on Nanophotonics (ICNP)/ The 4th Conference on Advances in Optoelectronics and Micro/Nano Optics (AOM), HongKong, China, 2013.5.20
    2. W. Kubo,”Plasmonic Nanostructures Fabricated by Nanocoating Lithography” The 2nd Korea-Japan Metamaterials Forum, Tsukuba, Japan, 2012.6.28
    1. W. Kubo,”Fabrication of Double Nanopillars with Gap and its Application for Plasmonic Sensor”KORE-JAPAN International Seminar, Jeju, Korea, 2011.11.3

  • Patents

    13. 出願番号2023-134713, 久保若奈, 川村直也, 東京農工大学

    12. 出願番号2022-198598, 久保若奈, 東京農工大学

    11. 出願番号2022-138077, 久保若奈, 上村 彬, 東京農工大学

    10. 出願番号2022-132221, 久保若奈, 東京農工大学

    9. 出願番号2019-193493, 久保若奈, 三輪魁斗, 東京農工大学

    8. 出願番号2018-080180, 久保若奈, 近藤柾樹, 東京農工大学,

    7. 特願 2019-034731, 久保若奈, 近藤柾樹, 東京農工大学,熱電変換素子、光検出器、画像素子及び光熱電変換素子

    6. 出願番号2012-199796, 特許公開2014-56892, 久保若奈, 田中拓男「光起電力素子およびその製造方法」独立行政法人理化学研究所

    5. 特許番号2008155400, 藤川茂紀, 久保若奈, 早川晴美, 国武豊喜, 羽田英夫, 古谷早苗「ナノ構造帯含有フィルムの作製方法およびナノ構造帯含有フィルム」独立行政法人理化学研究所, 東京応化工業株式会社

    4. 特許番号2008156745, 三好賢太郎, 久保若奈, 藤川茂紀, 国武豊喜, 羽田英夫, 松丸省吾, 古谷早苗 「構造体およびその製造方法」独立行政法人理化学研究所, 東京応化工業株式会社

    3. 特許番号2009057518, 特願, 2007-227934,久保若奈, 藤川茂紀, 国武豊喜, 羽田英夫, 古谷早苗 「異方性フィルムおよび異方性フィルムの製造方法」 独立行政法人理化学研究所, 東京応化工業株式会社

    2. 特許番号20090061170,Kubo; Wakana, Fujikawa; Shigenori, Kunitake; Toyoki, Hada; Hideo, Furuya; Sanae,「ANISOTROPIC FILM AND METHOD OF MANUFACTURING ANISTROPIC FILM」 Tokyo Ohka Kogyo Co., Ltd., Riken, 出願日2008-08-27

    1. 特願2002-043711,立間 徹, 藤嶋 昭, 久保若奈「光触媒リソグラフィー法」財団法人生産技術研究所奨励会, 大日本印刷株式会社