学術論文リスト

2020年度から論文リストの整理に着手しました。過去に遡って順次更新していきます(2021.4.5 更新、なお学術論文・国際会議主体で記載。国内学会発表は紙面節約のために割愛)

PY2021

  1. Kawasaki, “Application of mid-infrared free-electron laser for structural analysis of biological materials”, J. Synchrotron Rad. 28(1), 28–35 (2021).
  2. T. Kawasaki, “Use of Intense Terahertz Waves for Regulation of Amyloid Fibrillation”, The 8th International Workshop on Far-Infrared Technologies (IW-FIRT 2021), Online, Invited speaker.

PY2020

  1. Yamanoi et al., “Luminescence Properties of Nd 3+ ‐Doped AlF 3 ‐Based Fluoride Glass in the Vacuum Ultraviolet Region”, Physica Status Solidi (B), 1900475, 2020.
  2. Kawasaki et al., “Cellulose Degradation by Infrared Free Electron Laser”, Energy Fuels, 34, 9064-9068, 2020. https://pubs.acs.org/doi/10.1021/acs.energyfuels.0c01069
  3. Kawasaki et al., “Infrared Laser-Induced Amyloid Fibril Dissociation: A Joint Experimental/Theoretical Study on the GNNQQNY Peptide”, J. Phys. Chem. B 124, 6266-6277, 2020. https://pubs.acs.org/doi/10.1021/acs.jpcb.0c05385
  4. Kawasaki et al,., “Irradiation effect of a submillimeter wave from 420 GHz gyrotron on amyloid peptides in vitro”, Biomedical Optics express, 11, 5341, 2020.
  5. Watanabe et al., “Development of in situ A-SAXS and XAS Measurements of Pt Catalyst under Controlled Electrochemical Condition Using Channel Flow Electrode Cell”, ECS Trans. 98, 477, 2020.
  6. Yasuno et al., “Relative Sensitivity Factors for Hard X-ray Photoelectron Spectroscopy with Photon Energies of 3.0, 5.9, 7.9, and 9.9 keV”, Surface and Interface Analysis, 52, pp.869-874, 2020. DOI : 10.1002/sia.6855
  7. Kawasaki , “Laser Processing of Fiber Biopolymers by using Infrared Free Electron Laser Combined with ESI-MS Analysis”, American Society for Mass Spectrometry 2020 Reboot, Online, Poster presentation.
  8. T. Kawasaki , “Degradation of Cellulose Aggregate by using Infrared Free Electron Laser”, The 11th Intentional Symposium of Advanced Energy Science, Kyoto University, Invited speaker of session 2, 2020.

(下期分は集計中)

PY2019

  1. Yasuno et al., “Relative Sensitivity factors in hard X-ray photoelectron spectroscopy up to 10 keV”, ECASIA’19 , P1-DAT-06, 2019.
  2. Kawasaki et al., “Application of Infrared Free-Electron Laser for Amyloidosis Therapy” 44th Int’l Conf. on Infrared, Millimeter, and Terahertz Waves, pp.1-2, 2019.
  3. Yasuno et al., “Charge Compensation in Hard X-ray Photoelectron Spectroscopy by Electron Beam of Several Kilo-electron-volts”, J. Surf. Analysis, 26, pp.202-203, 2019.
  4. Kawasaki et al., “Dissolution of a fibrous peptide by terahertz free electron laser”, Sci. Rep. 9, 10636 (2019).
  5. Kawasaki et al., “Study on Irradiation Effect of Mid-Infrared Free Electron Laser on Hen Egg-White Lysozyme by Using Terahertz-Time Domain Spectroscopy and Synchrotron-Radiation Vacuum-Ultraviolet Circular-Dichroism Spectroscopy”, J. Infrared Milli. Terahz Waves, 40, pp.998-1009, 2019.
  6. Iwasa et al., “Synthesis, Optical Properties, and Band Structures of a Series of Layered Mixed-Anion Compounds”, J. Mater. Sci. Mater., 30, pp.16827-32, 2019.
  7. Motohashi et al., “Liquid Phase Pulsed Laser Ablation on Pyrite”, Chem. Lett., 48, pp. 712-14, 2019.
  8. Minami et al., “Spectroscopic Investigation of Praseodymium and Cerium Co-Doped 20Al(PO3)3-80LiF Glass for Potential Scintillator Applications”, J. Non-Cryst. Solids, 521,119495, 2019.
  9. Lai et al., “Direct Measurement of Refractive Index and Dispersion of Optical Glass by Dual-Prism Configuration with Imaging Spectrograph.” Jpn. J. Appl. Phys., 58, 096503, 2019.
  10. Kawasaki et al., “Laser Dissolution of Fibrous Peptide at Terahertz Region”, “The 56th Japanese Peptide Symposium, Tokyo.

PY2018

  1. E. Welter et al., “An International Initiative for a Round Robin Test of XAFS Experiments”, XAFS2018, #77, IX-60, 2018.
  2. C. T. Chantler, et al., “A call for a round robin study of XAFS stability and platform dependence at synchrotron beamlines on well defined samples”, J. Synchrotron Rad. 25, pp.935-943, 2018.
  3. T. Kawasaki et al., “Dissociation of beta-Sheet Stacking of Amyloid beta Fibrils by Irradiation of Intense, Short-Pulsed Mid-infrared Laser”, Cellular and Molecular Neurobiology, 38, pp.1039-1048, 2018.
  4. Y. Lai et al., “Gamma-ray irradiation-induced absorption and refractive index change in BK7 glass”, LSC2018, LSCp6-1, 2018.
  5. Verdad C. Agulto et al., “Structural and optical properties of ZnO-PVP composites for potential phosphor-based applications”, LSC2018, LSCp6-2, 2018.
  6. Y. Minami et al., “Improved luminescence lifetime observed in Pr3+/Ce3+-codoped APLF glass”, LSC2018, LSCp6-3, 2018.
  7. M. Noumi et al., “Local Structure Study of C-F Bond on Fluorocarbon Polymer Species”, LSC2018, LSC11-1, 2018.
  8. T. Shimizu et al., “Increasing the band gap of a perfect LiCaAlF6 crystal”, LSC2018, LSC12-1, 2018.
  9. M. Cadatal-Raduban et al., “Spectroscopy of Praseodymium-doped APLF Glass Scintillator Using Laser and Synchrotron Radiation”, LSC2018, LSC13-3, 2018.
  10. M. Empizo, “Scintillator applications of hydrothermal-grown ZnO nanorods”, The 36th SPP Int’l Phys. Conf., 1G-01, 2018.
  11. VC Agulto et al., “Effects of polymer coating and thermal annealing on the structural and optical properties of ZnO microrods”, The 36th SPP Int’l Phys. Conf., 1G-02, 2018.
  12. Y. Minami et al., “Achromatic lens design using new complex fluoride crystals for vacuum ultraviolet region”, The 36th SPP Int’l Phys. Conf., EA-01, 2018.
  13. Y. Lai et al., “Assessment of gamma-ray irradiation-induced absorption and refractive index change in optical glass”, The 36th SPP Int’l Phys. Conf., EA-02, 2018.
  14. V. C. Agulto et al., “Structural and optical properties of ZnO-PVP composites for potential phosphor-based applications”, The 36th SPP Int’l Phys. Conf., EA-05, 2018.
  15. K. Kawano et al., “Optical properties of rare earth ion-doped 20Al(PO3)3-80LiF glasses as neutron scintillator materials”, The 36th SPP Int’l Phys. Conf., EA-19, 2018.
  16. H. Ogino et al., “Development and functionality of layered mixed-anion compounds”, The 6th Japan-China Symp. on Cryst. Grouth and Cryst. Tech., Invited-12, 2018.
  17. Y. You et al., “Achromatic lens design using new complex fluoride crystals for vacuum ultraviolet region”, The 6th Japan-China Symp. on Cryst. Grouth and Cryst. Tech., p-1, 2018.
  18. Y. Lai et al., “Assessment of gamma-ray irradiation-induced absorption and refractive index change in optical glass”, The 6th Japan-China Symp. on Cryst. Grouth and Cryst. Tech., p-2, 2018.
  19. N. Sarukura, ”Novel optical materials and their various applications”, Int’l School on Photonics and Applications, Lecture, 2018.
  20. M. Cadatal-Raduban et al., “Numerial and Experimental Investigation of Fluoride-based Laser Crystals”, The 10th Int’l Conf. Photonics & Applications, A-04, 2018.
  21. K. Yamanoi et al., “Optical Characterization of Fluoride Glass as Fast-response Scintillator”, The 10th Int’l Conf. Photonics & Applications, B-07, 2018.
  22. M. V. Luong et al., “Direct Band Gap Tunability of the LiYF4 Crystal Through High-pressure Applications”, The 10th Int’l Conf. Photonics & Applications, A-29, 2018.
  23. V. C. Agulto et al., “Photoluminescence Studies of Zinc Oxide: effect of Growth Modification”, The 10th Int’l Conf. Photonics & Applications, P-II-08, 2018.
  24. Y. Lai et al., “Measirement of Refractive Index Based on Dual-prism Configuration for Irradiation-induced Damage assesment in Optical Glass”, The 10th Int’l Conf. Photonics & Applications, P-II-10, 2018.
  25. N. Sarukura, “Various Fluoride crystals for Vacuum Ultraviolet Lasers”, The 10th Int’l Conf. Photonics & Applications, PL-08, 2018.

PY2017

  1. S. Yasuno et. al., ECASIA’17, P02.032-SS113.(論文は2018年に出版、上記参照)
  2. M. J. Empizo, et al., “Optical damage assessment and recovery investigation of hydrogen-ion and deuterium-ion plasma-irradiated bulk ZnO single crystals”, J. Appl. Phys., 121, 175102(2017). https://doi.org/10.1063/1.4982346
  3. T. Shimizu et al., “High pressure band gap modification of LiCaAlF6”, J. Appl. Phys., 110, 141902(2017). https://doi.org/10.1063/1.4979106

PY2016

  1. T. Shimizu et al., “X-ray diffraction spectroscopy with laser-shock compression of LiCaAlF6 crystals”, 31st ICHSIP, 2P-25, Nov. 8th (2016).
  2. N. Sarukura et al., “Optical properties of hydrogen-ion and deuterium-ion plasma-irradiated hydrothermal-grown bulk ZnO single crystals”, 5th CJSCGT, Nov. 21th (2016).
  3. Y. Minami et al., “Optical Properties of Nd:LiCAF as a Potential Vacuum Ultraviolet Laser Material”, 5th CJSCGT, Nov. 21th (2016).

 

【報道発表】

2020年8月5日
赤外レーザーの照射によるアミロイドタンパク質凝集体の解離機構を解明
~実験と理論計算の融合により難病の治療法開発に新たな光を灯す~
https://www.tus.ac.jp/mediarelations/archive/20200805_0101.html

2020年6月29日
赤外自由電子レーザー照射によりセルロースがグルコースに効率的に分解することを発見
~グリーンプロセスとしてバイオエタノール生産などへの活用に期待~
https://www.tus.ac.jp/mediarelations/archive/20200629_0102.html