北九州市立大学 エネルギー循環化学科 李研究室

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研究業績

最新の成果 (Recent achievements)

  • [Open Access] A Preliminary Study for Tunable Optical Assessment of Exhaled Breath Ammonia Based on Ultrathin Tetrakis(4-sulfophenyl)porphine Nanoassembled Films (IF:3.398)
    Sergiy Korposh and Seung-Woo Lee*
    Chemosensors 9(9), 269 (2021).


  • [Open Access] Fabrication of Humidity-Resistant Optical Fiber Sensor for Ammonia Sensing Using Diazo Resin-Photocrosslinked Films with a Porphyrin-Polystyrene Binary Mixture (IF:3.576)
    Soad Ahmed, Yeawon Park, Hirofumi Okuda, Shoichiro Ono, Sergiy Korposh, and Seung-Woo Lee*
    Sensors 21(18), 6176 (2021).


  • [Open Access] Label-Free Creatinine Optical Sensing Using Molecularly Imprinted Titanium Dioxide-Polycarboxylic Acid Hybrid Thin Films: A Preliminary Study for Urine Sample Analysis (IF:3.398)
    Seung-Woo Lee*, Soad Ahmed, Tao Wang, Yeawon Park, Sota Matsuzaki, Shinichi Tatsumi, Shigekiyo Matsumoto, Sergiy Korposh, and Steve James
    Chemosensors 9(7), 185 (2021).


  • [Open Access] Population structure and reproductive biology of the endangered crab Deiratonotus japonicus (Brachyura, Camptandriidae) surveyed for nine years in the Kita River, Japan (IF:2.033)
    Il-Kweun Oh and Seung-Woo Lee
    J. Marine Science and Engineering 8(11), 921 (2020).


  • Long-Period Grating Fiber-Optic Sensors Exploiting Molecularly Imprinted TiO2 Nanothin Films with Photocatalytic Self-Cleaning Ability (IF:6.232)
    T. Wang, S. Korposh, S. James, and S. W. Lee*
    Microchimica Acta 187, 663 (2020).


  • [Open Access] Multi-Parameter Optical Fiber Sensing of Gaseous Ammonia and Carbon Dioxide (IF:5.090)
    L. Liu, S. P. Morgan, R. Correia, S. W. Lee, and S. Korposh
    J. Lightwave Technology 38(7), 2037-2045 (2020).


  • Formation of Hollow Porous TiO2 Nanospheres via Encapsulation of CO2 Nanobubbles for High-Performance of Adsorption and Photocatalysis (IF:4.174)
    H. K. Lee and S. W. Lee*
    RSC Dalton Trans. 49, 8274-8281 (2020).


  • [Open Access] Template-sacrificial conversion of MnCO3microspheres to fabricate Mn-doped TiO2 visible light photocatalysts (IF:6.289)
    H. K. Lee and S. W. Lee*
    Materials & Design 189, 108497 (2020).


  • [Open Access: Review] Tapered optical fibre sensors: current trends and future perspectives (IF:3.275)
    S. Korposh, S. W. James, S.-W. Lee, and R. P. Tatam
    Sensors 19, 2294 (2019).

  • Identification of volatile metabolites in human saliva from patients with oral squamous cell carcinoma via zeolite-based thin-film microextraction coupled with GC-MS (IF:3.004)
    H. Shigeyama, T. Wang, M. Ichinose, T. Ansai, and S.-W. Lee*
    J. Chromatography B 1104, 49-58 (2019).


  • Highly sensitive label-free antibody detection using a long period fibre grating sensor (IF:7.001)
    L. Liu, L. Marques, R. Correia, S. P. Morgan, S.-W. Lee, P. Tighe, L. Fairclough, and S. Korposh
    Sensors & Actuators: B. Chemical 271, 24-32 (2018).


  • [Open Access] Fabrication of Visible-light Responsive N-doped TiO2 Nanothin Films via a Top-down Sol-gel Deposition Method Using NH4TiOF3 Single Crystals (IF:1.550)
    H.-K. Lee, T. Fujiwara, T. Okada, T. Fukushima, and S.-W. Lee*
    Chemistry Letters 47, 628-631 (2018).



  • [Invited] Porphyrin-nanoassembled fiber-optic gas sensor fabrication: Optimization of parameters for sensitive ammonia gas detection (IF:3.670)
    S. Korposh, S. Kodaira, R. Selyanchyn, F. H. Ledezma, S. W. James, and S.-W. Lee*
    Optics and Laser Technology 101, 1-10 (2018).



Go to Lee's ResearchGate!

研究論文等 (Publications)

<論文>

2021-

119. Sergiy Korposh and Seung-Woo Lee*, “A Preliminary Study for Tunable Optical Assessment of Exhaled Breath Ammonia Based on Ultrathin Tetrakis(4-sulfophenyl)porphine Nanoassembled Films (IF:3.398)”, Chemosensors 9(9), 269 (2021).

118. Soad Ahmed, Yeawon Park, Hirofumi Okuda, Shoichiro Ono, Sergiy Korposh, and Seung-Woo Lee*, “Fabrication of Humidity-Resistant Optical Fiber Sensor for Ammonia Sensing Using Diazo Resin-Photocrosslinked Films with a Porphyrin-Polystyrene Binary Mixture (IF:3.576)”, Sensors 21(18), 6176 (2021).

117. Seung-Woo Lee*, Soad Ahmed, Tao Wang, Yeawon Park, Sota Matsuzaki, Shinichi Tatsumi, Shigekiyo Matsumoto, Sergiy Korposh, and Steve James, “Label-Free Creatinine Optical Sensing Using Molecularly Imprinted Titanium Dioxide-Polycarboxylic Acid Hybrid Thin Films: A Preliminary Study for Urine Sample Analysis (IF:3.398)”, Chemosensors 9(7), 185 (2021).

2016-2020

116. Il-Kweun Oh and Seung-Woo Lee, “Population structure and reproductive biology of the endangered crab Deiratonotus japonicus (Brachyura, Camptandriidae) surveyed for nine years in the Kita River, Japan (IF:2.033)”, J. Marine Science and Engineering 8(11), 921 (2020).

115. T. Wang, S. Korposh, S. James, and S. W. Lee*, “Long-Period Grating Fiber-Optic Sensors Exploiting Molecularly Imprinted TiO2 Nanothin Films with Photocatalytic Self-Cleaning Ability (IF:6.232)”, Microchimica Acta 187, 663 (2020).

114. Il-Kweun Oh and Seung-Woo Lee, “Effects of Temperature on the Survival and LarvalDevelopmentof DeiratonotusJaponicus (Brachyura, Camptandriidae)as a Biological Indicator (IF:2.033)”, J. Marine Science and Engineering 8(3), 2138274-8281 (2020).

113. H. K. Lee and S. W. Lee*, “Formation of Hollow Porous TiO2 Nanospheres via Encapsulation of CO2 Nanobubbles for High-Performance of Adsorption and Photocatalysis (IF:4.174)”, RSC Dalton Trans. 49, 8274-8281 (2020).

112. H. K. Lee and S. W. Lee*, “[Open Access] Template-sacrificial conversion of MnCO3microspheres to fabricateMn-doped TiO2visible light photocatalysts (IF:6.289)”, Materials & Design 189, 108497 (2020).

111. L. Liu, S. P. Morgan, R. Correia, S. W. Lee, and S. Korposh, “Multi-Parameter Optical Fiber Sensing of GaseousAmmonia and Carbon Dioxide (IF:5.090)”, J. Lightwave Technology 38(7), 2037-2045 (2020).

110. Korposh, S. W. James, S.-W. Lee, and R. P. Tatam, “[Review] Tapered optical fibre sensors: current trends and future perspectives (IF:3.275)”, Sensors 19, 2294 (2019).

109. H. Shigeyama, T. Wang, M. Ichinose, T. Ansai, and S.-W. Lee*, “Identification of volatile metabolites in human saliva from patients with oral squamous cell carcinoma via zeolite-based thin-film microextraction coupled with GC-MS (IF:3.004)”, J. Chromatography B 1104, 49-58 (2019).

108. L. Liu, L. Marques, R. Correia, S. P. Morgan, S.-W. Lee, P. Tighe, L. Fairclough, and S. Korposh, “Highly sensitive label-free antibody detection using a long period fibre grating sensor (IF:7.1)”, Sens. Actuators B 271, 24-32 (2018).

107. H.-K. Lee, T. Fujiwara, T. Okada, T. Fukushima, and S.-W. Lee*, “Fabrication of Visible-light Responsive N-doped TiO2 Nanothin Films via a Top-down Sol-gel Deposition Method Using NH4TiOF3 Single Crystals (IF:1.56)”, Chem. Lett. 47, 628-631 (2018).

106. S. Korposh, S. Kodaira, R. Selyanchyn, F. H. Ledezma, S. W. James, and S.-W. Lee*, “Porphyrin-nanoassembled fiber-optic gas sensor fabrication: Optimization of parameters for sensitive ammonia gas detection (IF:3.233)”, Optics and Laser Technology 101, 1-10 (2018).

105. R. Correia, S. James, S.-W. Lee, S. P. Morgan, and S. Korposh, “Review: Biomedical application of optical fibre sensors (IF:2.379)”, J. Optics 20, 073003 (2018).

104. S.-W. Lee*, R. Selyanchyn, S. Wakamatsu, and K. Hayashi, “Nanoassembled Thin-film-coated Quartz Crystal Microbalance Odor Sensors for Environmental and Human Breath Ammonchia Assessments (IF:0.560)”, Sensors and Materials 30(5), 1133-1144 (2018).

103. T. Wang, T. Ansai, and S.-W. Lee*, “Zeolite-loaded poly(dimethylsiloxane) hybrid films for highly efficient thin-film microextraction of organic volatiles in water (IF:3.004)”, J. Chromatography B 1041, 133-140 (2017).

102. D. Tiwari, K. Mullaney, S. Korposh, S. W. James, S.-W. Lee, and R. P. Tatam, “An ammonia sensor based on Lossy Mode Resonances on a tapered optical fibre coated with porphyrin-incorporated titanium dioxide (IF:7.1)”, Sens. Actuators B 242, 645-652 (2017).

101. H. Okuda, T. Wang, and S.-W. Lee*, “Selective Methanol Gas Detection Using a U-Bent Optical Fiber Modified with a Silica Nanoparticle Multilayer (IF:0.229)”, Electronics and Communications in Japan 100(2), 43-49 (2017).

100j. 李丞祐*, 高原直己, 王涛, “有機・無機複合薄膜を修飾した水晶振動子センサによるアンモニアおよびホルムアルデヒドの二成分ガス検知”, 電気学会論文誌E(センサ・マイクロマシン部門誌)137(7), 199-204 (2017).
100e. S.-W. Lee*, N. Takahara, and T. Wang, “Two-component Gas Sensing of Ammonia and Formaldehyde using Quartz Crystal Microbalance Sensors Modified with Organic/Inorganic Hybrid Nanothin Films (IF:0.260)”, IEEJ Transactions on Sensors and Micromachines 137(7), 199-204 (2017).

99. S. Korposh, S.-W. Lee, S. James, R. Tatam, and S. P. Morgan, “Biomedical application of optical fibre sensors”, Proc. SPIE 10111, Quantum Sensing and Nano Electronics and Photonics XIV, 101112Y (27 January 2017); doi: 10.1117/12.2243640.

98. J. Hromadka, S. Korposh, M. C. Partridge, S. James, F. Davis, D. Crump, S.-W. Lee, and R. P. Tatam, “Multi-parameter measurements using optical fibre long period gratings for indoor air quality monitoring”, Proc. SPIE 10323, 25th International Conference on Optical Fiber Sensors, 103233J (23 April 2017); doi: 10.1117/12.2265055.

97. F. U. Hernandez, T. Wang, S. Korposh, R. Correia, B. R. Hayes-Gill, J. Hromadka, N. N. Mohd Hazlan, A. Norris, D. Evans, S.-W. Lee, and S. P. Morgan, “Optical fibre sensing during critical care”, Proc. SPIE 10340, International Conference on Biophotonics V, 1034012 (29 April 2017); doi: 10.1117/12.2269993.

96. L. Liu, L. Marques, R. Correia, S. P. Morgan, S.-W. Lee, P. Tighe, L. C. Fairclough, and S. Korposh, “Human IgM detection using an optical fibre long period grating sensor”, Proc. 2017 IEEE SENSORS (29 Oct.-1 Nov. 2017); doi: 10.1109/ICSENS.2017.8234303.

95. T. Wang, W. Yasukochi, S. Korposh, S. W. James, R. P. Tatam, and S.-W. Lee*, “A long period grating optical fiber sensor with nano-assembled porphyrin layers for detecting ammonia gas (IF:7.1)”, Sens. Actuators B 228, 573-580 (2016).

94. T. Wang, T. Okada, K. Hayashi, S. W. James, and S.-W. Lee*, “Optical Gas Sensing Using Gold Nanoparticles/Polyelectrolyte Layer-by-Layer Films: A Case Study with Poly(acrylic acid) for Ammonia Detection (IF:0.560)”, Sensors and Materials 28(3), 181-190 (2016).

93j. 奥田浩史, 王涛, 李丞祐*, “シリカナノ粒子の多層薄膜を修飾したU字型光ファイバーを用いた選択的メタノールガス検知”, 電気学会論文誌E(センサ・マイクロマシン部門誌)136(5), 166-171 (2016).
93e. H. Okuda, T. Wang, and S.-W. Lee*, “Selective Methanol Gas Detection using a U-bent Optical Fiber Modified with a Silica Nanoparticle Multilayer (IF:0.260)”, IEEJ Transactions on Sensors and Micromachines 136(5), 166-171 (2016).

92. H.-K. Lee, T. Okada, T. Fujiwara, and S.-W. Lee*, “Top-Down Synthesis andDeposition of Highly Porous TiO2 Nanoparticles from NH4TiOF3 Single Crystals on Multi-Walled Carbon Nanotubes and Graphene Oxides (IF:6.289)”, Materials and Design 108, 269-276 (2016).

91. D. Tiwari, K. Mullaney, S. Korposh, S. W. James, S.-W. Lee, and R. P. Tatam, “Ammonia sensing using lossy mode resonances in a tapered optical fibre coated with porphyrin-incorporated titanium dioxide”, Proc. SPIE 9916, 6th European Workshop on Optical Fibre Sensors, 99161H (30 May 2016); doi: 10.1117/12.2236926.

90j. 王涛, 西松慶恒, 茂山博代, 安細敏弘, 李丞祐*, “唾液・尿中の揮発性有機代謝物の分子情報”, Aroma Research 17(3), 276-283 (2016).
90e. T. Wang, Y. Nishimatsu, H. Shigeyama, T. Ansai, and S.-W. Lee*, “Molecular information of volatile organic metabolites identified from human saliva and urine”, Aroma Research 17(3), 276-283 (2016).

2011-2015

89. R. Wong, S. Korposh, S.-W. Lee, S. W. James, and R. P. Tatam, “Photodecomposition of a target compound detected using an optical fibre long period grating coated with a molecularly imprinted titania thin film”, Proc. SPIE 9634, 24th International Conference on Optical Fibre Sensors, 96340Y (28 September 2015); doi: 10.1117/12.2192325.

88. R. Selyanchyn, S. Wakamatsu, K. Hayashi, and S.-W. Lee*, “A Nano-Thin Film-Based Prototype QCM Sensor Array for Monitoring Human Breath and Respiratory Patterns (IF:3.275)”, Sensors 15, 18834-18850 (2015).

87. Y. Ogimoto, R. Selyanchyn, N. Takahara, S. Wakamatsu, and S.-W. Lee*, “Detection of ammonia in human breath using quartz crystal microbalance sensors with functionalized mesoporous SiO2 nanoparticle film (IF:7.1)”, Sens. Actuators B 215, 428-436 (2015).

86. T. Nozoe, S. Goda, R. Selyanchyn, T. Wang, K. Nakazawa, T. Hirano, H. Matsui, and S.-W. Lee*, “In vitro detection of small molecule metabolites excreted from cancer cells using a Tenax TA thin-film microextraction device”, J. Chromatography B 991, 99-107 (2015).

85. H.-K. Lee and S.-W. Lee*, “Surfactant-free NH4TiOF3 Crystals: Self-assembly on Solid Surfaces and Room-temperature Hydrolysis for Hollow TiO2 Structures with High Photocatalytic Activity (IF:1.56)”, Chem. Lett. 44, 604-606 (2015).

84j. 李丞祐, “水晶発振子による呼気中アンモニア検査”, Aroma Research 16(4), 364-365 (2015).
84e. S.-W. Lee, “Quartz crystal microbalance based screening of ammonia in human breath”, Aroma Research 16(4), 364-365 (2015).

83. S.-W. Lee, “A New Concept for Development of Quartz Crystal Microbalance Fire Prevention Sensors Modified with Nano-Assembled Thin Film”, J. Disaster Research 10(4), 595-603 (2015).

82j. 王涛, 副田征幹, 李丞祐*, “クエン酸修飾金ナノ粒子を用いたポリアミンの高感度比色分析”, 高分子論文集 72(12), 752-759 (2015).
82e. T. Wang, M. Soeda, and S.-W. Lee*, “Sensitive Colorimetric Analysis of Polyamines Based on the Self-Assembly of Citric Acid-Modified Gold Nanoparticles (IF:0.27)”, Kobunshi Ronbunshu 72(12), 752-759 (2015).

81j. 李丞祐*, 荻本侑祐, 若松俊一, “呼気中アンモニアの即時検知を目指した水晶振動子ガスセンサシステムの開発”, 色材協会誌 88(6), 175-180 (2015).
81e. S.-W. Lee*, Y. Ogimoto, and S. Wakamatsu, “Development of a Quartz Crystal Microbalance Sensor System for Immediate Detection of Ammonia in Human Breath”, J. Jpn. Soc. Colour Mater. 88(6), 175-180 (2015).

80. S. Korposh, R. P. Tatam, S. W. James, and S.-W. Lee, “Chirality measurements using optical fibre long period gratings fabricated in high birefringent fibre”, Proc. SPIE 9655, 5th Asia-Pacific Optical Sensors Conference, 965533 (1 July 2015); doi: 10.1117/12.2184441.

79. S. Korposh, H. Okuda, T. Wang, S. W. James, and S.-W. Lee*, “U-shaped evanescent wave optical fibre sensor based on a porphyrin anchored nanoassembled thin film for high sensitivity ammonia detection”, Proc. SPIE 9655, 5th Asia-Pacific Optical Sensors Conference, 965518 (1 July 2015); doi: 10.1117/12.2184438.

78. S.-W. Lee*, T. Wang, R. Selyanchyn, S. Korposh, and S. W. James, “Optical fiber sensing of human skin emanations”, Proc. SPIE 9655, 5th Asia-Pacific Optical Sensors Conference, 96551K (1 July 2015); doi: 10.1117/12.2184411.

77. H. Okuda, T. Wang, and S.-W. Lee*, “Methanol selective fibre-optic gas sensor with a nanoporous thin film of organic-inorganic hybrid multilayers”, Proc. SPIE 9655, 5th Asia-Pacific Optical Sensors Conference, 96550Z (1 July 2015); doi: 10.1117/12.2183999.

76. D. Tiwari, S. W. James, R. P. Tatam, S. Korposh, and S.-W. Lee*, “A high-sensitivity chemical sensor based on titania coated optical-fiber long period grating for ammonia sensing in water”, Proc. SPIE 9655, 5th Asia-Pacific Optical Sensors Conference, 96552H (1 July 2015); doi: 10.1117/12.2184260.

75. S. Goda, R. Selyanchyn, T. Nozoe, H. Matsui, and S.-W. Lee*, “Development of a Thin-Film Microextraction Device based on ZSM-5/Tenax TA for VOC Detection in Liquid Samples”, J. Anal. Bioanal. Tech., S12 (2014).

74. H.-K. Lee, D. Sakemi, R. Selyanchyn, C.-G. Lee, and S.-W. Lee*, “Titania Nanocoating on MnCO3 Microspheres via Liquid-Phase Deposition for Fabrication of Template-Assisted Core-Shell- and Hollow-Structured Composites”, ACS Appl. Mater. Interfaces 6, 57-64 (2014).

73. S. Korposh, R. Selyanchyn, S. James, R. Tatam, and S.-W. Lee*, “Identification and quality assessment of beverages using a long period grating fibre-optic sensor modified with a mesoporous thin film”, Sensing and Bio-Sensing Research 1, 26-33 (2014).

72. S. W. James, S. Korposh, S.-W. Lee, and R. P. Tatam, “A long period grating-based chemical sensor insensitive to the influence of interfering parameters (IF:3.950)”, Optics Express 22(7), 8012-8023 (2014).

71. S. Korposh, S. W. James, S.-W. Lee, and R. P. Tatam, “Temperature and surrounding refractive index insensitive cascaded long period grating chemical sensor”, Proc. SPIE 9157, 23rd International Conference on Optical Fibre Sensors, 91574J (2 June 2014); doi: 10.1117/12.2059031.

70. T. Wang, S. Korposh, S. James, R. Tatam, and S.-W. Lee*, “Optical fiber long period grating sensor with a polyelectrolyte alternate thin film for gas sensing of amine odors (IF:7.1)”, Sens. Actuators B 185, 117-124 (2013).

69. S. Korposh, F. Davis, S. W. James, T. Wang, S.-W. Lee, S. Higson, and R. P. Tatam, “Detection of volatile organic compounds (VOCs) using an optical fibre long period grating with a calixarene anchored mesoporous thin film”, Proc. SPIE 8794, 5th European Workshop on Optical Fibre Sensors, 87941I (20 May 2013); doi: 10.1117/12.2026270.

68. R. Selyanchyn, T. Nozoe, H. Matsui, T. Kadosawa, and S.-W. Lee*, “TD-GC-MS Investigation of the VOCs Released from Blood Plasma of Dogs with Cancer”, Diagnostics 3, 68-83 (2013).

67. R. Selyanchyn and S.-W. Lee*, “Molecularly imprinted polystyrene?titania hybrids with both ionic and π?π interactions: a case study with pyrenebutyric acid (IF:6.232)”, Microchim Acta 180, 1443-1452 (2013).

66. D. Sakemi, H. Lee, R. Selyanchyn, and S.-W. Lee*, “One-pot Anatase TiO2 Nanocoating on Multiwalled Carbon Nanotubes via Liquid-phase Deposition Process (IF:1.56)”, Chem. Lett. 42(6), 595-597 (2013).

65. K. Araki, D.-H. Yang, T. Wang, R. Selyanchyn, S.-W. Lee*, and T. Kunitake, “Self-assembly and imprinting of macrocyclic molecules in layer-by-layered TiO2 ultrathin films (IF:6.237)”, Anal. Chim. Acta 779, 72-81 (2013).

64. T. Wang, S. Korposh, S. James, R. Tatam, and S.-W. Lee*, “Polyelectrolyte multilayer nanothin film coated long period grating fiber optic sensors for ammonia gas sensing”, Proc. 13th IEEE Conference Nanotechnology (IEEE-NANO 2013) (5-8 Aug. 2013); doi: 10.1109/NANO.2013.6720931.

63. W. Yasukochi, T. Wang, S. Kodaira, S. Korposh, R. Selyanchyn, and S.-W. Lee*, “Ammonia Gas Detection Using an Optically Sensitive Hybrid Organic/Inorganic Multilayer Nanoporous Film (IF:0.20)”, Adv. Sci. Lett. 19(2), 415-419 (2013).

62. T. Nozoe, R. Selyanchyn, H. Matsui, and S.-W. Lee*, “Pyrolysis Gas Chromatography Mass Spectrometry Assessment of Low-Concentration Sarcosine in Water Based Samples (IF:0.20)”, Adv. Sci. Lett. 19(1), 233-237 (2013).

61j. 酒見大輔, 二神渉, 工藤義高, 尾上慎弥, 李丞祐*, 国武豊喜, “チタン-n-ブトキシドを用いたカーボンナノチューブの可溶化および酸化チタンナノコーティング”, 高分子論文集 70(6), 253-261 (2013).
61e. D. Sakemi, W. Futagami, Y. Kudo, S. Onoue, S.-W. Lee*, and T. Kunitake, “Solubilization and Titania Nano-Coating of Carbon Nanotubes Using Titanium (IV) Tetrabutoxide (IF:0.27)”, Kobunshi Ronbunshu 70(6), 253-261 (2013).

60j. 高原直己, 王涛, 李丞祐*, “シクロデキストリンを配合した酸化チタンナノハイブリッド薄膜の分子選択性”, 高分子論文集 70(5), 214-220 (2013).
60e. N. Takahara, T. Wang, and S.-W. Lee*, “Selective Adsorption of Molecules by Imprinted Titania Nanohybrid Thin Films with Anchored Cyclodextrin Host Molecules (IF:0.27)”, Kobunshi Ronbunshu 70(5), 214-220 (2013).

59. T. Wang, S. Korposh, R. Wong, S. James, R. Tatam, and S.-W. Lee*, “A Novel Ammonia Gas Sensor Using a Nanoassembled Polyelectrolyte Thin Film on Fiber-optic Long-period Gratings (IF:1.56)”, Chem. Lett. 41(10), 1297-1299 (2012).

58. N. Mizutani, S. Korposh, R. Selyanchyn, D.-H. Yang, C.-S. Lee, S.-W. Lee*, and T. Kunitake, “One-step Fabrication of Polystyrene-TiO2 Nanosandwich Film by Phase Separation (IF:1.56)”, Chem. Lett. 41(5), 552-554 (2012).

57. N. Mizutani, S. Korposh, R. Selyanchyn, S. Wakamatsu, and S.-W. Lee*, “Application of a Quartz Crystal Microbalance (QCM) Twin Sensor for Selective Label-free Immunoassay to Simultaneous Antigen-antibody Reactions”, Sens. & Trans. 137(2), 1-9 (2012).

56. S. Korposh, T. Wang, S. James, R. Tatam, and S.-W. Lee*, “Pronounced aromatic carboxylic acid detection using a layer-by-layer mesoporous coating on optical fibre long period grating (IF:7.1)”, Sens. Actuators B 173, 300-309 (2012).

55. S. Korposh, R. Selyanchyn, W. Yasukochi, S.-W. Lee*, S. W. James, and R. P. Tatam, “Optical fibre long period grating with a nanoporous coating formed from silica nanoparticles for ammonia sensing in water (IF:3.408)”, Materials Chemistry and Physics 133, 784-792 (2012).

54. R. Jarzebinska, S. Korposh, S. James, W. Batty, R. Tatam, and S.-W. Lee*, “Optical Gas Sensor Fabrication Based on Porphyrin-Anchored Electrostatic Self-Assembly onto Tapered Optical Fibers”, Analytical Letters 45, 1297-1309 (2012).

53j. 野添太久磨, セリャンチン・ロマン, 松井英享, 李丞祐*, “熱分解法によるサルコシンの臭気化定量分析とその応用”, Aroma Research 13(3), 256-261 (2012).
53e. T. Nozoe, R. Selyanchyn, H. Matsui, and S.-W. Lee*, “Pyrolysis-based quantitative analysis of sarcosine and its application to urine samples”, Aroma Research 13(3), 256-261 (2012).

52j. 梁道鉉, 二神渉, 水谷直貴, 李丞祐*, “金属酸化物/フラーレン多層ナノコンポジット薄膜の作製”, 高分子論文集 69(4), 171-178 (2012).
52e. D.-H. Yang, W. Futagami, N. Mizutani, and S.-W. Lee*, “Fabrication of Metal Oxide and Fullerene Layer-by-Layered Nanocomposite Films (IF:0.27)”, Kobunshi Ronbunshu 69(4), 171-178 (2012).

51. R. Selyanchyn, S. Korposh, S. Wakamatsu, and S.-W. Lee*, “Respiratory Monitoring by Porphyrin Modified Quartz Crystal Microbalance Sensors (IF:3.275)”, Sensors 11(1), 1177-1191 (2011).

50. R. Selyanchyn, S. Korposh, S. Wakamatsu, and S.-W. Lee*, “Simultaneous Monitoring of Humidity and Chemical Changes Using Quartz Crystal Microbalance Sensors Modified with Nano-thin Films (IF:1.580)”, Anal. Sci. 27(3), 253-258 (2011).

49. N. Mizutani, D.-H. Yang, R. Selyanchyn, S. Korposh, S.-W. Lee*, and T. Kunitake, “Remarkable Enantioselectivity of Molecularly Imprinted TiO2 Nano-thin Films (IF:6.237)”, Anal. Chim. Acta 694(1-2), 142-50 (2011).

48. S.-W. Lee*, S. Korposh, T. Onodera, and K. Toko, “Electrochemical detection of the explosive taggant 2,3-dimethyldinitrobutane using a single-walled carbon nanotube employed TiO2 composite film (IF:0.78)”, Nanoscience and Nanotechnology - Asia 1(1), 47-52 (2011).

47. S.-W. Lee*, S. Korposh, T. Onodera, and K. Toko, “Fast and Sensitive Detection of 2,3-Dimethyldinitrobutane (DMNB) as Explosive Taggant Using Corundum Based Integrated Electrochemical Chips (IF:0.60)”, Sensor Letters 9(1), 266-271 (2011).

46. S. Korposh, S.-W. Lee*, S. W. James, and R. P. Tatam, “Refractive index sensitivity of fibre-optic long period gratings coated with SiO2 nanoparticle mesoporous thin films (IF:1.857)”, Measurement Science and Technology 22(7), 075208 (2011).

45. S. Korposh, S.-W. Lee*, S. W. James, and R. P. Tatam, “Refractive index sensitivity of fibre optic long period gratings with SiO2 nanoparticle based mesoporous coatings”, Proceedings of SPIE - The International Society for Optical Engineering 7753 (2011).

44. R. Selyanchyn, S. Korposh, W. Yasukochi, and S.-W. Lee*, “A Preliminary Test for Skin Gas Assessment Using a Porphyrin Based Evanescent Wave Optical Fiber Sensor”, Sens. & Trans. 125(2), 54-67 (2011).

43. S.-W. Lee*, N. Takahara, S. Korposh, D.-H. Yang, and T. Kunitake, “A Novel Mass-Sensitive Sensor Based on β-Cyclodextrin-Anchored Bisphenol A-Imprinted TiO2 Ultrathin Layers (IF:0.560)”, Sens. Mater. 23(4), 229-236 (2011).

2006-2010

42. S. Korposh, S. W. James, S.-W. Lee*, S. Topliss, S. C. Cheung, W. J. Batty, and R. P. Tatam, “Fiber optic long period grating sensors with a nanoassembled mesoporous film of SiO2 nanoparticles (IF:3.950)”, Optics Express 18(12), 13227-13238 (2010).

41. S. Korposh, W. Batty, S. Kodaira, S.-W. Lee*, S. W. James, S. M. Topliss, and R. P. Tatam, “Ammonia sensing using a fibre optic long period grating with a porous nanostructured coating formed from silica nanospheres”, Proc. SPIE 7653, Fourth European Workshop on Optical Fibre Sensors, 76531D (8 September 2010); doi: 10.1117/12.866326.

40. S. Korposh, R. Selyanchyn, and S.-W. Lee*, “Nano-assembled thin film gas sensors. IV. Mass-sensitive monitoring of humidity using quartz crystal microbalance (QCM) electrodes (IF:7.1)”, Sens. Actuators B 147(2), 599-606 (2010).

39j. 水谷直貴, 二神渉, 李 丞祐*, 国武豊喜, “ポリマーを鋳型とした酸化チタンナノ薄膜の多孔性評価:C60フラーレンおよびシトクロム c の選択的吸着”, 高分子論文集 67(5), 304-311 (2010).
39e. N. Mizutani, W. Futagami, S.-W. Lee*, and T. Kunitake, “Evaluation of porosity of polymer-templated TiO2 nano-thin films: Selective adsorption of C60 fullerene and cytochrome c (IF:0.27)”, Kobunshi Ronbunshu 67(5), 304-311 (2010).

38. R. Selyanchyn, S. Korposh, T. Matsui, H. Matsui, and S.-W. Lee*, "Purge and trap coupled to Curie point thermal desorption for the detection of parts per trillion 2,4,6-trichloroanisole (TCA) in water solutions (IF:1,500)", Chromatographia 71, 317-321 (2010).

37. S.-W. Lee*, N. Takahara, S. Korposh, D.-H. Yang, K. Toko, and T. Kunitake, “Nano-assembled thin film gas sensor. III. Sensitive detection of amine odors using TiO2/polyacrylic acid ultrathin film QCM sensors (IF:6.370)”, Anal. Chem. 82, 2228-2236 (2010).

36. S. Korposh, S. Kodaira, W. Batty, S. W. James, and S.-W. Lee*, “Nano-assembled thin film gas sensor. II. An intrinsic highly sensitive fibre optic sensor for ammonia detection (IF:0.560)”, Sens. Mater. 21, 179-189 (2009).

35. D.-H. Yang, C. S. Park. J. H. Min, M. H. Oh, Y. S. Yoon, S.-W. Lee*, and J. S. Shin, “Fullerene nanohybrid metal oxide ultrathin films (IF:2.281)”, Current Applied Physics 9, e132-e135 (2009).

34. D.-H. Yang, M.-J. Ju, A. Maeda, and S.-W. Lee*, “Enhanced sensor capability of juxtaposed β-cyclodextrin rings in TiO2 ultrathin matrix as determined by cyclic surface-polarization impedance measurement (IF:0.560)”, Sens. Mater. 20(5), 191-200 (2008).

33. S. O. Korposh, Y. P. Sharkan, M. Y. Sichka, D.-H. Yang, S.-W. Lee*, and J. J. Ramsden*, “Matrix influence on the optical response of composite bacteriorhodopsin films to ammonia (IF:7.1)”, Sens. Actuators B 133, 281-290 (2008).

32. D.-H. Yang, N. Takahara, S.-W. Lee*, and T. Kunitake, “Fabrication of glucose-sensitive TiO2 ultrathin films by molecular imprinting and selective detection of monosaccharides (IF:7.1)”, Sens. Actuators B 130, 379-385 (2008).

31. S. Kodaira, S.-W. Lee*, and T. Kunitake, “Photoinduced Micropatterning of Silver Nanoparticles in a Titanium Dioxide/Poly(acrylic acid) Alternate Thin Film (IF:1.56)”, Chem. Lett. 37, 168-169 (2008).

30. S. Korposh, S. Kodaira, S.-W. Lee*, W. J. Batty, S. W. James, and R. P. Tatam, “Fabrication of sensitive fibre-optic gas sensors based on nano-assembled thin films”, Proc. 2008 IEEE SENSORS (26-29 Oct. 2008), 1285-1288; doi: 10.1109/ICSENS.2008.4716679.

29. S. Kodaira, S. Korposh, S.-W. Lee*, W. J. Batty, S. W. James, and R. P. Tatam, “Fabrication of Highly Efficient Fibre-Optic Gas Sensors Using SiO2/Polymer Nanoporous Thin Films”, Proc. 3rd International Conference on Sensing Technology, 481-485 (2008); doi: 10.1109/ICSENST.2008.4757152.

28. S. Korposh, S. Kodaira, S.-W. Lee*, W. J. Batty, S. W. James, and R. P. Tatam, “Deposition of SiO2/Polymer Nanoporous Thin Films on Long-Period Grating (LPG) Optical Fibres and Dramatic Enhancement of the Resonance Bands”, Proc. 3rd International Conference on Sensing Technology, 666-669 (2008); doi: 10.1109/ICSENST.2008.4757189.

27. M.-J. Ju, D.-H. Yang, N. Takahara, K. Hayashi, K. Toko, S.-W. Lee*, and T. Kunitake, “Landmine detection: Improved binding of 2,4-dinitrotoluene in a γ-CD/metal oxide matrix and its sensitive detection via a cyclic surface polarization impedance (cSPI) method”, Chem. Comm. 6, 2630-2632 (2007).

26. M.-J. Ju, D.-H. Yang, S.-W. Lee*, T. Kunitake, K. Hayashi, and K. Toko, “Fabrication of TiO2/γ-CD films for nitro aromatic compounds and its sensing application via cyclic surface-polarization impedance (cSPI) spectroscopy (IF:7.1)”, Sens. Actuators B 123, 359-367 (2007).

25. S. Korposh, N. Takahara, S.-W. Lee*, and T. Kunitake, “Fabrication of Optical Gas Sensors Using Porphyrin-based Nano-assembled Thin Films: a Comparison with Bulk Materials”, Proc. 7th IEEE Conference Nanotechnology (IEEE-NANO 2007) 7, 1037-1040 (2007); doi: 10.1109/NANO.2007.4601360.

24. D.-H. Yang, N. Takahara, N. Mizutani, S.-W. Lee*, and T. Kunitake, “Fabrication of TiO2 and Cytochrome c Alternate Ultrathin Films via a Gas-phase Surface Sol-Gel Process (IF:1.56)”, Chem. Lett. 35, 990-991 (2006).

23. N. Takahara, D.-H. Yang, M.-J. Ju, K. Hayashi, K. Toko, S.-W. Lee*, and T. Kunitake, “Anchoring of Cyclodextrin Units on TiO2 Thin Layer for Effective Detection of Nitro-aromatics: A Novel Electrochemical Approach for Landmine Detection (IF:1.56)”, Chem. Lett. 35, 1340-1341 (2006).

22. S. Korposh, N. Takahara, J. J. Ramsden, S.-W. Lee*, and T. Kunitake, “Nano-assembled thin film gas sensors. I. Ammonia detection by a porphyrin-based multilayer film”, J. Biolog. Phys. Chem. 6, 125-132 (2006).

21. D.-H. Yang, M.-J. Ju, A. Maeda, K. Hayashi, K. Toko, S.-W. Lee*, and T. Kunitake, “Design of highly efficient receptor sites by combination of cyclodextrin units and molecular cavity in TiO2 ultrathin layer”, Biosens. Bioelectron. 22, 388-392 (2006).

20. K. Nakazawa, S.-W. Lee, J. Fukuda, D.-H. Yang, and T. Kunitake, “Hepatocyte Spheroid Formation on a Titanium Dioxid Gel Surface and Hepatocyte Long-term Culture”, J. Materials Science: Materials in Medecine 17(4), 359-364 (2006).

19. N. Mizutani, D.-H. Yang, N. Mitsushita, S.-W. Lee*, and T. Kunitake, “Fabrication and Application of Enantioselective TiO2 Nanofilms by Molecular Imprinting”, Proc. 2006 IEEE SENSORS (22-25 Oct. 2006), 1249-1252; doi: 10.1109/ICSENS.2007.355856.

2001-2005

18. 李丞祐, 国武豊喜, “分子キャビティをもつセラミックナノ薄膜の作製”, 未来材料 5(2), 26-32 (2005).

17. D.-H. Yang, S.-W. Lee*, and T. Kunitake, “Facile Fabrication of Molecularly Imprinted Cavities in Spin-Coated TiO2 Nanofilms (IF:1.56)”, Chem. Lett. 34, 1686-1687 (2005).

16. Y.-J. Ji, H.-Y. Kim, Y.-S. Yoon, S.-W. Lee, and J.-S. Shin, “Hard Coatings on Polycarbonate Plate by Sol-Gel Process”, J. Adhesion and Interface 6, 10-18 (2005).

15. D.-H. Yang, A.-H. Bae, K. Koumoto, S.-W. Lee*, K. Sakurai, and S. Shinkai, “In situ monitoring of polysaccharide-polynucleotide interaction using a schizophyllan-immobilized QCM device (IF:7.1)”, Sens. Actuators B 105, 490-494 (2005).

14. S.-W. Lee*, D.-H. Yang, and T. Kunitake, “Regioselective imprinting of anthracenecarboxylic acids onto TiO2 gel ultrathin films: an approach to thin film sensor (IF:7.1)”, Sens. Actuators B 104, 35-42 (2005).

13. S. Korposh, M. Y. Sichka, I. I. Trikur, Y. P. Sharkan, D.-H. Yang, S.-W. Lee, and J. J. Ramsden, “Films based on bacteriorhodopsin in sol-gel matrices”, Proc. SPIE 5956, Integrated Optics: Theory and Applications, 595616 (30 September 2005); doi: 10.1117/12.622631.

12. M.-J. Ju, K. Hayashi, K. Toko, D.-H. Yang, S.-W. Lee*, and T. Kunitake, “A New Electrochemical Sensor for Heavy-Metal Ions by the Surface-Polarization Controlling Method”, Proc. 2005 IEEE TRANSDUCERS (5-9 June 2005)2, 1876-1879; doi: 10.1109/SENSOR.2005.1497462.

11. A.-H. Bae, S.-W. Lee, M. Ikeda, M. Sano, S. Shinkai, and K. Sakurai, “Rod-like architecture and helicity of the poly(C)/schizophyllan complex observed by AFM and SEM (IF:2.01)”, Carbohydr. Res. 339, 251-258 (2004).

10. K. Hayashi, K. Hayama, K. Masunaga, W. Futagami, S.-W. Lee, and K. Toko, “Analysis of adsorbing molecules on Pt surface using electrochemical impedance spectroscopy (IF:0.599)”, IEICE Trans. Electron. E87-C(12), 2087-2092 (2004).

9. T. Kunitake and S.-W. Lee, “Molecular imprinting in ultrathin titania gel films via surface sol-gel process (IF:6.237)”, Anal. Chim. Acta 504, 1-6 (2004).

8. S.-W. Lee, I. Ichinose, and T. Kunitake, “Enantioselective Binding of Amino Acid Derivatives onto Imprinted TiO2 Ultrathin Films (IF:1.56)”, Chem. Lett. 31, 678-679 (2002).

7. I. Ichinose, T. Kikuchi, S.-W. Lee, and T. Kunitake, “Imprinting and Selective binding of Di- and Tri-Peptides in Ultrathin TiO2-Gel Films in Aqueous Solutions (IF:1.56)”, Chem. Lett. 31, 104-105 (2002).

6. S.-W. Lee and T. Kunitake, “Adsorption of TiO2 nanoparticles imprinted with D-glucose on a gold surface (IF:0.55)”, Mol. Cryst. and Liq. Cryst. 371, 111-114 (2001).

Untill 2000

5. S.-W. Lee, I. Ichinose, and T. Kunitake, “Molecular imprinting of protected amino acids in ultrathin multilayers of TiO2 gel (IF:1.56)”, Chem. Lett. 27, 1193-1194 (1998).

4. S.-W. Lee, I. Ichinose, and T. Kunitake, “Molecular Imprinting of Azobenzene Carboxylic Acid on a TiO2 Ultrathin Film by the Surface Sol-Gel Process (IF:3.75)”, Langmuir 14, 2857-2863 (1998).

3. C. H. Lee, N. H. Jeong, S. W. Lee, and T. Kitamura, “Novel Synthesis of Liquid-Crystalline 1,3-Butadiynes Using Coupling Reaction of Alkynyliodonium Salts with Organocopper Reagents (IF:5.278)”, J. Ind. & Eng. Chem. 3(2), 155-159 (1997).

2. B. C. Lee, Y. K. Shin, S. W. Lee, I. Lee, and W. H. Lee, “Nucleophilic Substitution Reactions of Benzoic Anhydrides Aniline in Methanol-Acetonitrile Mixture (IF:0.13)”, J. Kor. Chem. Soc. 41(2), 69-76 (1997).

1. B. C. Lee, S. W. Lee, and I. Lee, “Kinetics and Mechanism of Nucleophilic Substitution Reaction of Benzyl Chlorodes”, Bull. Nat. Sci. Chungbuk Natl. Univ. Kor. 5(1), 143-158 (1991).

<著書:外書>

11. S. Korposh, S.-W. Lee, and S. James, “Long Period Grating Based Fibre Optic Chemical Sensors”, in Fiber Optic Sensors”, Springer International Publishing, Switzerland (2017), Chap. 12, pp. 241-267.


詳細は、こちら

10. S. Korposh, S. James, R. Tatam , and S.-W. Lee*, “Optical Fibre Long-Period Gratings Functionalised with Nano-Assembled Thin Films: Approaches to Chemical Sensing”, in: Current Trends in Short- and Long-period Fiber Gratings, INTECH (2013), Chap. 4, pp. 63-86.


ダウンロードは、こちら

9. S. Korposh, S. James, R. Tatam , and S.-W. Lee*, “Fibre-Optic Chemical Sensor Approaches Based on Nanoassembled Thin Films: A Challenge to Future Sensor Technology”, in: Current Developments in Optical Fiber Technology, INTECH (2013), Chap. 9, pp. 237-264.


ダウンロードは、こちら

8. S.-W. Lee, “Nano-Assembled Thin-Film-Based Gas Sensors”, in Biochemical Sensors: Mimicking Gustatory and Olfactory Senses”, Pan Stanford Publishing Pte. Ltd. (2013), Chap. 24, pp. 435-456.


7. S.-W. Lee and T. Kunitake (2012). “Handbook of Molecular Imprinting: Advanced Sensor Applications”, Pan Stanford Publishing Pte. Ltd.; ISBN: 978-981-4316-65-1 (Hardcover), 978-981-4364-32-4 (eBook).


詳細は、こちら

6. S.-W. Lee, “Trace Detection Based on Cyclodextrin Anchored Molecularly Imprinted TiO2 Thin Films”, in: Handbook of Molecular Imprinting: Advanced Sensor Applications”, Pan Stanford Publishing Pte Ltd (2012), Chap. 12, pp. 421-451.


5. S.-W. Lee*, S. Korposh, R. Selyanchyn, and T. Kunitake, “Fundamentals and Perspectives of Molecular Imprinting in Sensor Applications”, in: Handbook of Molecular Imprinting: Advanced Sensor Applications”, Pan Stanford Publishing Pte Ltd (2012), Chap. 1, pp. 3-64.


4. S. Korposh, R. Selyanchyn, and S.-W. Lee*, “Environmental and bio-medical applications using quartz crystal microbalance (QCM) humidity sensors modified with nano-assembled thin films”, in: Humidity Sensors: Types, Nanomaterials and Environmental Monitoring, Nova Science Publishers, NY (2011), Chap. 2, pp. 93-116.


3. S. Korposh and S.-W. Lee*, “Fabrication of sensitive fibre-optic gas sensors based on nano-assembled thin films”, in: Optical Fibre, New Developments, IN-TECH, Vienna (2009), Chap. 1, pp. 1-16.


ダウンロードは、こちら

2. S.-W. Lee and T. Kunitake, “Molecular Imprinting by the Surface Sol-Gel Process-Templated Nanoporous Metal Oxide Thin Films for Molecular Recognition”, in: Self-Organized Nanoscale Materials, edited by D. J. Lockwood and M. Adachi, Kluwer/Plenum series on Nanostructure Science and Technolgy (2006), Chap. 5, pp. 186-220.


1. I. Ichinose, S.-W. Lee, and T. Kunitake, “Nanofabrication by the Surface Sol-Gel Process and Molecular Imprinting”, in: Supramolecular Organization and Materials Design, Cambridge University Press (2002), Chap. 6, pp. 172-213.


詳細は、こちら

<著書:和書・解説>

5. 李 丞祐, “匂いのセンシング・定量評価技術−呼気中アンモニアの検出と病気診断応用”, (株)シーエミシー出版(2020), 第3編4章.

詳細は、こちら

4. 李 丞祐, “現代界面コロイド科学の事典−環境をはかるコロイド界面科学と技術(巨大ナノ薄膜と環境センサー”, 丸善(株)(2010), 第5章 第7項 p. 136-137.

3. 李 丞祐, “自己組織化ハンドブック−分子鋳型法を利用した高感度金属イオンセンサー”, 新日本編集企画(2009), 第9章 第2.3項 p. 776-778.

2. 李 丞祐, “MEMSデバイス総論−バイオセンサー”, サイエンス&テクノロジー株式会社(2009), 第5章 第2項 p. 104-119.

1. 李 丞祐 他1人, “分子がつくるナノの不思議(クバプロ)(韓国語翻訳書)”, 電波科学社(2002), ソウル.

特許関連 (Patents)

<分類>発明者:技術または特許名(出願番号/公開番号/登録番号)の順になります。
これまで18件の特許出願、その内、9件の特許を取得しています。

当研究室の技術・特許に興味のある方または企業へ

特許の詳細またはライセンス契約を希望される場合はご連絡ください。
北九州市立大学 国際環境工学部エネルギー循環化学科 教授 李 丞祐
電話 093-695-3293
Eメール leesw[at]kitakyu-u.ac.jp
([at]を@に置き換えてください)


技術・特許情報の詳細は、こちらを!

11. <特許>平川清、李丞祐:液種別判別センサ(特許第6868928号)
10. <特許>李丞祐, 李学根:多孔質酸化チタン微粒子の製造方法及び多孔質酸化チタン微粒子(特許第6850469号)
9. <特許>井上孝, 磯部良彦, 李丞祐:ガスセンサ(特許第5817108号)
8. <特許>李丞祐, 水谷直貴:芳香族ニトロ化合物検知センサーの製造方法、芳香族ニトロ化合物検知センサーおよびそれを用いた芳香族ニトロ化合物の検知方法(特許第5812419号)
7. <特許>李丞祐, セリャンチンロマン:呼気分析の方法(特許第5652847号)
6. <特許>李丞祐 、セルギーオーコルポシュ:複合薄膜及びそれを備えた雰囲気センサ並びに光導波路センサ(特許第5388309号)
5. <特許>国武豊喜, 李丞祐, 二神渉:カーボンナノチューブ組成物およびこれを用いた製造方法(特許第5382756号)
4. <特許>李丞祐, セルギー・オー・コルポシュ:雰囲気センサ及びその製造方法(特許第5219033号)
3. <特許>李丞祐, セルギー・オー・コルポシュ:湿度センサ(特許第4952334号)
2. <特許>李丞祐, 国武豊喜, 林健司, 都甲潔:金属イオン検知用電極及びその製造方法(特許第4817371号)
1. <特許>李丞祐, 高原直己, 国武豊喜:ガス検知素子及びその製造方法(特許第4565092号)

20. <特許出願>Seung-Woo Lee et al.:Optical Sensor(UK Patent Application No. 2113037.2)
19. <特許出願>李丞祐、平川清、奥田浩史:光学式検知チップおよび光学式検知システム(特願2021-131390)
19. <特許出願>平川清、李丞祐:液種別判別センサ(特願2020-214874)
18. <技術>李丞祐, 安細敏弘:癌の診断を補助する方法、および癌を診断するシステム(特願2018-205844)
17. <技術>李丞祐, 李学根:多孔質酸化チタン微粒子の製造方法及び多孔質酸化チタン微粒子(韓国AP20170017)
16. <技術>李丞祐, 李学根:多孔質酸化チタン微粒子の製造方法及び多孔質酸化チタン微粒子(特願2016-201643)
15. <技術>李丞祐 、セルギーオーコルポシュ:複合薄膜及びそれを備えた雰囲気センサ並びに光導波路センサ(特願2010-505829)
14. <技術>井上孝, 磯部良彦, 李丞祐:ガスセンサ(特願2010-272905)
13. <技術>李丞祐, セリャンチンロマン:呼気分析の方法及び呼気分析装置(特願2009-257537)
12. <技術>李丞祐, 高原直己, 国武豊喜:ガス検知素子及びその製造方法(特願2008-508577)
11. <技術>李丞祐, セルギー・オー・コルポシュ:雰囲気センサ(特願2008-086429)
10. <技術>李丞祐, セルギー・オー・コルポシュ:湿度センサ(特願2007-091555)
9. <技術>李丞祐, 水谷直貴:高感度雰囲気センサーの製造方法、高感度雰囲気センサーおよびそれを用いた物質の検知方法(特願2006-248816)
8. <技術>李丞祐, 国武豊喜, 林健司, 都甲潔:金属イオン検知用電極及びその製造方法(特願2006-083283)
7. <技術>李丞祐, 梁道鉉, 高原直己, 国武豊喜:化学物質識別膜の製造方法(特願2005-252104)
6. <技術>国武豊喜, 李ユアン志, 李丞祐, 梁道鉉:金属酸化物薄膜の製造方法、微粒子層の固定化方法および有機/金属酸化物複合薄膜の製造方法(特願2005-184382)
5. <技術>国武豊喜, 李丞祐, 二神渉:可溶化剤、可溶化方法、カーボンナノチューブ組成物およびこれを用いた製造方法(特願2005-064898)
4. <技術>李丞祐, 周明鍾, 国武豊喜, 林健司, 都甲潔:溶液分析方法及び溶液分析装置(特願2004-329437)
3. <技術>李丞祐, 国武豊喜, 都甲潔, 林健司:化学物質分離膜及びその製造方法、並びに化学物質の検出方法及び化学物質検出装置(特願2003-095914)
2. <技術>中澤浩二, 李丞祐, 国武豊喜:培養床、培養床コーティング剤、培養床製造方法並びにこれらを用いた細胞培養方法及び培養細胞(特願2003-073555)
1. <技術>国武豊喜, 李丞祐:光異性体の分離・検出能をもつ金属酸化物薄膜(特願1999-064540)

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