Shuhei Inoue

Last Updated :2021/04/06

Affiliations, Positions
Graduate School of Advanced Science and Engineering, Associate Professor
E-mail
shu18hiroshima-u.ac.jp

Basic Information

Educational Backgrounds

  • The University of Tokyo, Graduate School, Division of Engineering, Japan, 2000/04, 2003/03
  • The University of Tokyo, Graduate School, Division of Engineering, Japan, 1998/04, 2000/03
  • Keio University, Faculty of Science and Engineering, Japan, 1993/04, 1998/03

Academic Degrees

  • Doctor of Engineering, The University of Tokyo
  • Master of Engineering, The University of Tokyo

Research Fields

  • Engineering;Mechanical engineering;Thermal engineering

Research Keywords

  • nano particle
  • carbon nanotube

Educational Activity

Course in Charge

  1. 2021, Liberal Arts Education Program1, 1Term, Introduction to Information and Data Sciences
  2. 2021, Undergraduate Education, 4Term, Thermodynamics II
  3. 2021, Undergraduate Education, 1Term, Heat Transfer II
  4. 2021, Undergraduate Education, Second Semester, Experiments in Mechanical Engineering II
  5. 2021, Graduate Education (Doctoral Program) , Year, Mechanical Science Research V
  6. 2021, Graduate Education (Master's Program) , 1Term, Special Exercises on Mechanical Engineering A
  7. 2021, Graduate Education (Master's Program) , 2Term, Special Exercises on Mechanical Engineering A
  8. 2021, Graduate Education (Master's Program) , 3Term, Special Exercises on Mechanical Engineering B
  9. 2021, Graduate Education (Master's Program) , 4Term, Special Exercises on Mechanical Engineering B
  10. 2021, Graduate Education (Master's Program) , Academic Year, Special Study on Mechanical Engineering
  11. 2021, Graduate Education (Master's Program) , 3Term, Advanced Thermal Engineering
  12. 2021, Graduate Education (Doctoral Program) , Academic Year, Special Study on Mechanical Engineering

Research Activities

Academic Papers

  1. Understanding the mechanism of photochromism in double-layer metal oxide using X-ray photoelectron spectroscopy, CHEMICAL PHYSICS LETTERS, 739, 202001
  2. Light and flexible gas sensors made of free-standing carbon nanotube paper, CHEMICAL PHYSICS LETTERS, 747, 20200516
  3. Synthesis of broad yellow phosphors by co-doping and realization of high quality of white light, CHEMICAL PHYSICS LETTERS, 717, 11-15, 20190216
  4. VHF Plasma CVD Synthesis of Photochromic ZnO Nanoparticle, MRS ADVANCES, 4(27), 1573-1577, 201902
  5. Requirements for photochromism in double-layer metal oxide films, CHEMICAL PHYSICS LETTERS, 732, 201910
  6. Effect of thickness of carbon nanotube films on enhancement of sensor response, CHEMICAL PHYSICS LETTERS, 734, 201911
  7. Transient behavior of carbon nanotube thin film for adsorption of polar and non-polar molecules, CHEMICAL PHYSICS LETTERS, 691, 351-354, 201801
  8. Effects of physical and chemical adsorption on the electric conductance of carbon nanotube films, AIP ADVANCES, 8(1), 201801
  9. Spontaneous and controlled-diameter synthesis of single-walled and few-walled carbon nanotubes, CHEMICAL PHYSICS LETTERS, 699, 88-92, 201805
  10. Effect of Single-walled Carbon Nanotube Catalysts on Hydrothermal Pretreatment of Cellulose, JOURNAL OF THE JAPAN PETROLEUM INSTITUTE, 61(3), 199-204, 201805
  11. Principles of detection mechanism for adsorbed gases using carbon nanotube nanomat, CHEMICAL PHYSICS LETTERS, 709, 77-81, 201810
  12. Suppression of Radical Char Production in Supercritical Water Gasification by Addition of Organic Acid Radical Scavenger, ENERGY & FUELS, 32(9), 9568-9571, 201809
  13. Photochromic behavior at the interface of two transparent thin films and the possibility for its use in a high-performance battery, CHEMICAL PHYSICS LETTERS, 712, 25-29, 20181116
  14. Conversion of guaiacol in supercritical water gasification: Detailed effect of feedstock concentration, JOURNAL OF SUPERCRITICAL FLUIDS, 142, 32-37, 201812
  15. Effect of preparation conditions in sol-gel method on yellow phosphor with wide spectrum, AIP ADVANCES, 7(1), 201701
  16. In-situ Mass Spectroscopic Analysis of Glucose Decomposition under Hydrothermal Condition: Quantitative Analysis for Reaction Kinetics, JOURNAL OF THE JAPAN PETROLEUM INSTITUTE, 60(2), 101-109, 201703
  17. In situ mass spectrometry of glucose decomposition under hydrothermal reactions, KOREAN JOURNAL OF CHEMICAL ENGINEERING, 34(5), 1524-1530, 201705
  18. Effect of the Heating Rate on the Supercritical Water Gasification of a Glucose/Guaiacol Mixture, INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 56(22), 6401-6407, 20170607
  19. Transport phenomena of electrons at the carbon nanotube interface with molecular adsorption, JOURNAL OF APPLIED PHYSICS, 122(1), 20170707
  20. Thermal decomposition products of various carbon sources in chemical vapor deposition synthesis of carbon nanotube, Diamond and Related Materials, 75, 1-5, 201705
  21. Defects control in the synthesis of low-dimensional zinc oxide, Chemical Physics Letters, 684, 113-116, 20170916
  22. Real-Time Mass Spectrometric Analysis of Hydrothermal Reaction Products, INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH, 56(36), 9993-9998, 20170913
  23. Quantitative In Situ Mass Spectrometry Analysis of Mannitol Decomposition Products under Hydrothermal Conditions, ENERGY & FUELS, 31(10), 10866-10873, 201710
  24. Inhibition of char deposition using a particle bed in heating section of supercritical water gasification, KOREAN JOURNAL OF CHEMICAL ENGINEERING, 33(4), 1261-1266, 201604
  25. Effect of molecular coverage on the electric conductance of a multi-walled carbon nanotube thin film, CHEMICAL PHYSICS LETTERS, 654, 9-12, 20160616
  26. Synthesis of photochromic nanoparticles and determination of the mechanism of photochromism, AIP ADVANCES, 6(5), 201605
  27. Estimation of adsorption energy for water molecules on a multi-walled carbon nanotube thin film by measuring electric resistance, AIP ADVANCES, 6(11), 201611
  28. Trial for simple gas sensor composed of as-grown carbon nanotubes, CHEMICAL PHYSICS LETTERS, 628, 81-84, 20150516
  29. Enhancement of the effective thermal conductivity in packed beds by direct synthesis of carbon nanotubes, JOURNAL OF THERMAL SCIENCE AND TECHNOLOGY, 10(1), 201501
  30. In situ measurement of activation energy for pyrolysis of ethanol as a first reaction in the synthesis of carbon nanotubes, CHEMICAL PHYSICS LETTERS, 639, 261-265, 20151016
  31. Molecular dynamic simulation for the evaluation of free energy distribution along the reaction coordinates at the initial stage of carbon nanotube nucleation, Chemical Physics Letters, 634, 194-197, 20150801
  32. Simulation of catalyst behavior during chemical vapor deposition processing of carbon nanotubes, CHEMICAL PHYSICS LETTERS, 604, 1-4, 20140603
  33. Gasification Characteristics of Alanine in Supercritical Water, JOURNAL OF THE JAPAN PETROLEUM INSTITUTE, 57(5), 225-229, 201409
  34. Precursor and formation mechanism in the synthesis of carbon nanotubes by chemical vapor deposition, CHEMICAL PHYSICS LETTERS, 616, 217-221, 20141125
  35. Gasification characteristics of amino acids in supercritical water, Journal of the Japan Institute of Energy, 93, 936-943, 201409
  36. Report on the Seventh U.S.-Japan Joint Seminar on Nanoscale Transport Phenomena-Science and Engineering, NANOSCALE AND MICROSCALE THERMOPHYSICAL ENGINEERING, 17(1), 25-49, 20130101
  37. Gasification Rate of Various Biomass Feedstocks in Supercritical Water, JOURNAL OF THE JAPAN PETROLEUM INSTITUTE, 56(1), 1-10, 201301
  38. Heat Transfer Characteristics of Activated Carbon Suspended Slurry Near the Critical Point of Water, Journal of the Japan Institute of Energy, 92, 309-312, 2013
  39. Drastic enhancement of effective thermal conductivity of a metal hydride packed bed by direct synthesis of single-walled carbon nanotubes, INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 37(2), 1836-1841, 201201
  40. In situ mass spectroscopic analysis for chemical vapor deposition synthesis of single-walled carbon nanotubes, CHEMICAL PHYSICS LETTERS, 533, 56-59, 20120423
  41. In situ mass spectroscopic analysis of alcohol catalytic chemical vapor deposition process for single-walled carbon nanotube, CHEMICAL PHYSICS LETTERS, 536, 104-108, 20120521
  42. Synthesis of single-walled carbon nanotubes using laser-vaporized metal nanoparticle catalyst, JOURNAL OF MECHANICAL SCIENCE AND TECHNOLOGY, 25(1), 11-15, 201101
  43. Heat Transfer Charactristics of Biomass Slurry under High Pressure and High Temperature, Journal of Japan Institute of Energy, 90, 874-880, 2011
  44. MD Study of Functionalized Single-Walled Carbon Nanotube, JOURNAL OF THERMAL SCIENCE AND TECHNOLOGY, 6(2), 256-267, 2011
  45. The Rheological Characteristics of Biomass Slurry under High Pressure and High Temperature, Journal of Japan Institute of Energy, 90, 1165-1170, 2011
  46. Metal coating effect on thermal diffusivity of single-walled carbon nanotube, CHEMICAL PHYSICS LETTERS, 495(1-3), 80-83, 20100729
  47. Prospective growth region for chemical vapor deposition synthesis of carbon nanotube on C-H-O ternary diagram, DIAMOND AND RELATED MATERIALS, 19(11), 1401-1404, 201011
  48. Influence of metal coating on single-walled carbon nanotube: Molecular dynamics approach to determine tensile strength, CHEMICAL PHYSICS LETTERS, 469(1-3), 125-129, 20090203
  49. Influence of catalyst supporters on catalyst nanoparticles in synthesis of single-walled carbon nanotubes, MICROELECTRONICS JOURNAL, 40(4-5), 692-696, 2009
  50. Molecular dynamics simulation of metal coating on single-walled carbon nanotube, CHEMICAL PHYSICS LETTERS, 464(4-6), 160-165, 20081023
  51. Effect of catalyst combination on growth of single-walled carbon nanotubes, DIAMOND AND RELATED MATERIALS, 17(11), 1888-1890, 200811
  52. Molecular dynamics simulation of physical vapor deposition of metals onto a vertically aligned single-walled carbon nanotube surface, CARBON, 46(15), 2046-2052, 200812
  53. Mass Spectroscopy of Chemical Reaction of 3d Metal Clusters Involved in Chemical Vapor Deposition Synthesis for Carbon Nanotubes, Japanese Journal of Applied Physics, 47, 1931-1936, 2008
  54. Trial for diameter-selective synthesis of single-walled carbon nanotubes, CARBON, 44(7), 1287-1291, 200606
  55. Chemical Reactivity and Tendency of Fe, Co, and Ni Clusters with Ethanol by Using FT-ICR Mass Spectrometer, Transactions of the JSME, 71(707), 1915-1920, 2005
  56. Chemisorption of Silicon Cluster Ions (Sin+, n=10-30) with Ethylene (C2H4) by Using FT-ICR Mass Spectrometer, Transactions of the JSME, 71(704), 1148-1154, 2005
  57. Chemical Reaction of Cobalt Clusters with Ethanol by Using FT-ICR Mass Spectrometer, Transactions of the JSME, 71(707), 1909-1914, 2005
  58. Synthesis of single-wall carbon nanotubes from alcohol using Fe/Co, Mo/co, Rh/Pd catalysts, CHEMICAL PHYSICS LETTERS, 406(1-3), 184-187, 20050423
  59. Diameter control and growth mechanism of single-walled carbon nanotubes, CHEMICAL PHYSICS LETTERS, 410(4-6), 209-212, 20050720
  60. Chemical Reaction of Silicon Clusters with Nitric Oxide by Using FT-ICR Mass Spectrometer, 69(684), 1879-1885, 2003
  61. Mass Spectroscopy and Reaction Studies of Laser-Vaporized Clusters from Metal-Doped Carbon Materials, 69(684), 1886-1892, 2003
  62. FT-ICR Studies of Precursor Clusters of Single Wall Carbon Nanotubes (SWNTs), Microscale Thermophysical Engieering, 7(1), 33-39, 2003
  63. FT-ICR Studies of Laser Vaporized Clusters from Ni/Co and Ni/Y Loaded Graphite Samples, Physica B, 323(1-4), 193-195, 2002
  64. FT-ICR Study of Chemical Reaction of Silicon Clusters, Thermal Science and Engineering, 7(6), 69-74, 1999

Patented

  1. Patent, JP5493127, 2014/03/14