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Researcher Information

last modified:2024/10/12

Associate Professor FUJITAKE Masaharu

Mail

Faculty, Affiliation

Faculty of Mathematics and Physics, Institute of Science and Engineering School of Mathematics and Physics

College and School Educational Field

Division of Mathematical and Physical Science, Graduate School of Natural Science and Technology
Division of Mathematical and Physical Sciences, Graduate School of Natural Science and Technology
School of Mathematics and Physics, College of Science and Engineering

Laboratory

Molecular Physics TEL:076-264-5659 FAX:076-265-5739

Academic Background

【Academic background(Doctoral/Master's Degree)】
Hiroshima University Doctor Graduate School, Division of Natural Science 198903 Completed
【Academic background(Bachelor's Degree)】
Hiroshima University 198403
【Degree】
doctor of science

Career

Year & Month of Birth

Academic Society


Japan Society for Molecular Science

Award

Specialities

Molecular Spectroscopy

Speciality Keywords

Molecular Structure,Molecular Complex,High Resolution Molecular Spectroscopy

Research Themes

Studies on the structure and dynamical behavior of the bio-related moleculer complexes by high-resolution spectroscopy

Studies on the structure and dynamical behavior of the bio-related moleculer complexes by high-resolution spectroscopy I observe hydrogen-bonded molecular complexes, multilple molecules bonded with one another by hydrogen bonding, through spectroscopic experiments in gas-phase independent systems, and by investigating molecular structures and qualities related to dynamic behavior, I intend to explain various phenomena in liquids and water solutions at the molecular level. More specifically, I aim to investigate the effects of hydrogen-bonded complexes, including protein, and explain higher-order structure formation processes and the basic characteristics of function manifestation, focusing on the small-model molecules that are the basic components of biomolecules.

High resolution Spectroscopic study on unstable (transieut) Molecules.

High resolution Spectroscopic study on unstable (transieut) Molecules. I conduct high-resolution molecular spectroscopic research on highly reactive transient molecules such as those called radicals. These unstable molecules form and exist in special environments, including space, at high temperatures, and in plasma, and provide clues for examining important information about the environment through observation of their spectrum. They also attract attention as reaction intermediates. In addition, since electronic motion is significantly reflected in the molecular energy and quality of these molecules, its precise research will further our understanding of the basic theories in molucular science.

Studies on the structure and dynamical behavior of the bio-related moleculer complexes by high-resolution spectroscopy

High resolution Spectroscopic study on unstable (transieut) Molecules.

Books

Papers

  •  Fourier transformation microwave spectroscopy of the methyl glycolate–H2O complex M. Fujitake, T. Tanaka and N. Ohashi Journal of Molecular Spectroscopy 343 3-17 2017/09/22
  •  Microwave spectroscopy of HCOO13CH3 in the second methyl torsional excited state K. Kobayashi, T. Kuwahara, H. Tachi, Y. Urata, S. Tsunekawa, N. Hayashi, H. Higuchi, M. Fujitake, N. Ohashi Journal of Molecular Spectroscopy 343 50-53 2017/08/24
  •  Reanalysis of the ground and three torsional excited states of trans-ethyl methyl ether by using an IAM-like tunneling matrix formalism Kaori Kobayashi, Yusuke Sakai, Shozo Tsunekawa, Taihei Miyamoto, Masaharu Fujitake, Nobukimi Ohashi Journal of Molecular Spectroscopy 321 1 63-77 2016
  •  Fourier-transform microwave spectroscopy of N-methylaniline Junpei Aoyama, Nobukimi Ohashi Journal of Molecular Spectroscopy 235 1 27-34 2006/01
  •  Fourier-transform microwave spectroscopy of N,N-dimethylacetamide Yuji Kubota, Nobukimi Ohashi Journal of Molecular Spectroscopy 236 1 97-109 2006/05

show all

  •  Detection of a new halosilylene SiFCl by microwave spectroscopy JOURNAL OF MOLECULAR STRUCTURE 413-414 21 1997
  •  Near-infrared band of the nitrate radical NO3 observed by diode laser spectroscopy JOURNAL OF CHEMICAL PHYSICS 107 8 2829 1997/08
  •  Structure and predissociation of the 3puD3u+ Rydberg state of N2: First extreme-ultraviolet and new near-infrared observations, with coupled-channels analysis B. R. Lewis, K. G. H. Baldwin, A. N. Heays, S. T. Gibson, J. P. Sprengers, W. Ubachs, M. Fujitake JOURNAL OF CHEMICAL PHYSICS 129 204303 2008/11
  •  Near-infrared diode laser spectroscopy of FeC in the 0.8-mu m region: A simultaneous analysis of the X3Di and [3.8]1D states JOURNAL OF MOLECULAR SPECTROSCOPY 208 1 253 2001
  •  Near-infrared diode laser spectroscopy of the nitrogen molecule in Rydberg state: Analysis of the c1Pu - a”1Sg+, v = 1 - 0 band JOURNAL OF MOLECULAR SPECTROSCOPY 185 2 330 1997
  •  Near-infrared diode-laser spectroscopy of the CCO radical in the A(010)3D - X(010)3P(b) band JOURNAL OF MOLECULAR SPECTROSCOPY 195 2 317 1999
  •  Newly observed vibrotational bands of N2O in 1.3-mu m region JOURNAL OF MOLECULAR SPECTROSCOPY 197 2 324 1999
  •  Near-Infrared Diode Laser Spectroscopy of the HCSi Radical JOURNAL OF MOLECULAR SPECTROSCOPY 223 113-119 2004
  •  Analysis and fit of the Fourier transformation microwave spectrum of the two-top molecule N-methylacetamide JOURNAL OF MOLECULAR SPECTROSCOPY 227 1 28-42 2004
  •  Near-infrared diode laser spectroscopy of free radicals 60 16 3277-3284 2004/12
  •  Identification of a vibrationally excited level in methyl formate through microwave and far-infrared spectroscopy Kaori Kobayashi,Yusuke Sakai,Masaharu Fujitake,Dennis W. Tokaryk,Brant E. Billinghurst,Nobukimi Ohashi Canadian Journal of Physics 98 6 551 2020/06 
  •  Microwave spectroscopy of HCOO13CH3 in the second methyl torsional excited state Kaori Kobayashi,Takuro Kuwahara,Haruka Tachi,Yuki Urata,Shozo Tsunekawa,Naoto Hayashi,Hiroyuki Higuchi,Masaharu Fujitake,Nobukimi Ohashi Journal of Molecular Spectroscopy 343 50 2018/01/01
  •  Fourier transformation microwave spectroscopy of the methyl glycolate–H2O complex Masaharu Fujitake,Toshihiro Tanaka,Nobukimi Ohashi Journal of Molecular Spectroscopy 343 3 2018/01/01

Conference Presentations

  • Fourier Transform Microwave Spectroscopy of Ethyl Glycolate(2023/12/02)
  • Fourier transform microwave spectroscopy of the ethyl glycolate-water complex(2023/12/02)
  • Fourier Transform Microwave Spectroscopy of Formamide-Methanol(13C) Complex(2023/12/02)
  • Calculation of energy level structure for the inversion motion of FA-MeOH(2023/12/02)
  • The Effect of Non-Covalent Interactions on Internal Rotation Potential Barrier of Methyl Groups in N-Methylformamide-Methanol Complex(2021/12/04)

show all

  • Fourier transform microwave spectroscopy of microhydrated     N-methylformamide clusters(conference:Annual Meeting of Japan Society for Molecular Science)(2021/09/18)
  • Fourier transform microwave spectroscopy of the N-methylformamide-methanol complex(2021/12/04)
  • Effect of non-covalent interaction on methyl group internal rotation barrier in peptide moleculewater complex system(2021/12/04)
  • Fourier transform microwave spectroscopy of the N‐methyl formamide‐(H2O)3 complex(2021/12/04)
  • The Effects that Non-covalent Interactions have on the Isomerization of Methyl Glycolate・・・H2O(2020/12/05)
  • Study on the Effects of Non-covalent Interactions in Insertion-type Water Complexes of Methyl Glycolate(2020/09/16)
  • Development of a pattern-matching program using the hyperfine structure in pure rotational spectra(2020/12/05)
  • Study on the Effects of non-covalent Interactions on the Stability of Methyl Glycolate…(H2O)2 Complexes(2019/12/07)
  • Vibrational energy level structure in an asymmetric double minimum isomerization potential of hydrogen-bonded complexes(2019/12/07)
  • Fourier transform microwave spectroscopy of N-methylformamide…Formamide(15N) complex(2019/12/07)
  • Fourier transform microwave spectroscopy of the N‐methylformamide‐(𝐇𝟐𝐎)𝟐 complex(2019/12/07)
  • Estimation of inversion potential in micro-hydration clusters(2018/11/24)
  • Methyl group internal rotation potential of peptide molecules(2018/11/24)
  • Fourier transform microwave spectroscopy of trimethylene oxide⋯𝐇𝟐𝐎 complex(2018/11/24)
  • Program Development for the Computation of Dipole-Dipole Interactions in Hydrogen Bond Complexes(2018/11/24)
  • Isomerization of 1-amino-2-methyl-2-propanol-H2O complex (additional)(2018/11/24)
  • Fourier transform microwave spectroscopy of deutrated N-methylacetamide-Water complex(conference:Annual Meeting of Japan Society for Molecular Science)(2013/09/24)
  • Relationship between conformational structure and methyl internal rotation potential barriers in N-methylacetamide-wateromplexes(conference:Annual Meeting of Japan Society for Molecular Science)(2014/09/21)
  • Solvent isotope effect on methyl internal rotation potential barrier of N-Methylacetamide-H2O complex(conference:Annual Meeting of Hokuriku Branch of JPS in 2017 )(2017/12/02)
  • Fourier transform microwave spectroscopy of Formamide15N…(H2O)2 complex(conference:Annual Meeting of Hokuriku Branch of JPS in 2017 )(2017/12/02)
  • Fourier transform microwave spectroscopy of 1-amino-2-methyl-2-propanol-H2O complex(conference:Annual Meeting of Hokuriku Branch of JPS in 2017 )(2017/12/02)
  • Development of cross slit nozzle for the supersonic jet Fourier transform microwave spectroscopy Ⅱ(conference:Annual Meeting of Hokuriku Branch of JPS in 2017 )(2017/12/02)
  • Nitrgen nuclear quadrupole coupling constants of N-methylacetamide(conference:Annual Meeting of Japan Society for Molecular Science)(2013/09/24)

Others

Arts and Fieldwork

Patent

Theme to the desired joint research

○High-resolution spectroscopy of the hydrogen-bond complex.

Grant-in-Aid for Scientific Research

○「マイクロ波分光法による生態関連分子ミクロ水和クラスターの構造と内部運動の研究」(2006-2008) 
○「高分解能分子分光学的手法を活用した生体機能とくに情報伝達の機構の解明」(2002-2004) 

Competitive research funding,Contribution

Collaborative research,Consignment study

Classes (Bachelors)

○Physical Optics B(2021)
○Physical Optics A(2021)
○Molecular Physics(2021)
○Experiments in Fundamental Physics(2021)
○Physics Experiments 2(2021)
○Practical Seminar for Teaching Profession C / Junior High School・High School(2021)
○Physics Experiments 1(2021)
○Lecture on Life in Campus and Society(2021)
○Physical Optics B(2020)
○Physical Optics A(2020)
○Molecular Physics(2020)
○Physics Experiments 2(2020)
○Physics Experiments 1(2020)
○Practical Seminar for Teaching Profession C / Junior High School・High School(2020)
○Lecture on Life in Campus and Society(2020)
○Experiments in Fundamental Physics(2020)
○World of Physics(2020)
○World of Physics(2020)
○Presentation and Debate (Freshman Seminar II)(2020)
○Physical Optics B(2019)
○Physical Optics A(2019)
○Molecular Physics(2019)
○World of Physics(2019)
○Physics Experiments 2(2019)
○Physics Experiments 1(2019)
○Lecture on Life in Campus and Society(2019)
○World of Physics(2019)
○Presentation and Debate (Freshman Seminar II)(2019)
○Lecture on Life in Campus and Society(2018)
○Physics Experiments 1(2018)
○Physical Optics A(2018)
○Physical Optics B(2018)
○World of Physics(2018)
○Presentation and Debate (Freshman Seminar II)(2018)
○Molecular Physics(2018)
○Physics Experiments 2(2018)
○World of Physics(2017)
○World of Physics(2017)
○Presentation and Debate (Freshman Seminar II)(2017)
○World of Physics(2017)
○World of Physics(2017)
○World of Physics(2017)
○World of Physics(2017)
○Physical Optics(2017)
○Physics Experiments 1(2017)
○Physics Experiments 2(2017)
○Presentation and Debate (Freshman Seminar II)(2017)
○Molecular Physics(2017)
○Freshman Seminar I(2017)
○Physical Optics(2016)
○Physics Experiments 1(2016)
○Presentation and Debate (Freshman Seminar II)(2016)
○World of Physics(2016)
○Freshman Seminar I(2016)
○Experiments in Fundamental Physics(2016)
○Physics Experiments 2(2016)
○Molecular Physics(2016)

Classes (Graduate Schools)

○Structural Theory of Gaseous Molecules(2019)
○Structural Theory of Gaseous Molecules(2019)
○Structural Theory of Gaseous Molecules(2019)
○Structural Theory of Gaseous Molecules(2019)
○Introduction to Molecular and Biophysics(2019)
○Scientific Presentation B(2019)
○Scientific Presentation B(2019)
○Research Work B(2019)
○Research Work B(2019)
○Physics Education b(2019)
○Physics Education a(2019)
○Optical Physics b(2019)
○Optical Physics a(2019)
○Introduction to Molecular and Biophysics b(2019)
○Introduction to Molecular and Biophysics a(2019)
○Optical Physics a(2018)
○Seminar B(2018)
○Exercise B(2018)
○Structural Theory of Gaseous Molecules(2018)
○Introduction to Molecular and Biophysics(2018)
○Introduction to Molecular and Biophysics a(2018)
○Research Work B(2018)
○Physics Education b(2018)
○Physics Education a(2018)
○Optical Physics b(2018)
○Introduction to Molecular and Biophysics b(2018)
○Structural Theory of Gaseous Molecules(2017)
○Optical Physics a(2017)
○Physics Education a(2017)
○Seminar B(2017)
○Introduction to Molecular and Biophysics a(2017)
○Exercise B(2017)
○Structural Theory of Gaseous Molecules(2017)
○Structural Theory of Gaseous Molecules(2017)
○Structural Theory of Gaseous Molecules(2017)
○Research Work B(2017)
○Introduction to Molecular and Biophysics b(2017)
○Optical Physics b(2017)
○Physics Education b(2017)
○Research Work B(2016)
○Exercise B(2016)
○Optical Physics(2016)
○Structural Theory of Gaseous Molecules(2016)
○Seminar B(2016)
○Physics Education b(2016)
○Introduction to Molecular and Biophysics b(2016)
○Introduction to Molecular and Biophysics a(2016)
○Physics Education a(2016)

International Project

International Students

Lecture themes

Others (Social Activities)

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