Aiko NARAZAKI, National Institute of Advanced Industrial Science and Technology (AIST)

Original paper

1. “Towards understanding the mechanism of 3D printing using protein: Femtosecond laser direct writing of microstructures made from homopeptides”，D. Serien, A. Narazaki, K. Sugioka, Acta Biomaterialia, 164 (2023) 139-150; https://doi.org/10.1016/j.actbio.2023.04.007.
2. "In-process monitoring of femtosecond laser-induced periodic nanostructures on glass by using anti-reflective property", D. Nagai, H. Takada, A. Narazaki, G. Miyaji, Proc of SPIE Laser Applications in Microelectronic and Optoelectronic Manufacturing (LAMOM) XXVIII, 12408 (2023) 124080O.
3. “High Immobilization Efficiency of Basic Protein within Heparin-Immobilized Calcium Phosphate Nanoparticles”, M. Nakamura, W. Bunryo, A. Narazaki, A. Oyane, Int. J. Mol. Sci., 23 (2022) 11530; https://doi.org/10.3390/ijms231911530.
4. “Data-driven ultrashort pulse laser processing toward real-time CPS”, A. Narazaki, D. Yoshitomi, H. Takada, D. Nagai, G. Miyaji, ICALEO 2022 Proc, Micro701 (2022) 1-6.
5. “Comparative Study of Proteinaceous Microfabrication with Different Repetition Rates by Femtosecond Direct Laser Write”，D. Serien, A. Narazaki, Proc of SPIE Laser 3D Manufacturing IX, 11992 (2022) 1199208.
6. “Biological Modification of Tooth Surface by Laser-Based Apatite Coating Techniques”，H. Miyaji, A. Oyane, A. Narazaki, Journal of Oral Biosciences, 64-2 (2022) 217-221.
7. “Improvement in Laser-Based Micro-Processing of Carbon Nanotube Film Devices”，D. Suzuki, D. SERIEN Daniela, K. Obata, K. Sugioka, A. Narazaki, T. Terasaki, Applied Physcis Express, 115 (2022) 026503.
8. “Laser-Induced Transfer of Noble Metal Nanodots with Femtosecond Laser-Interference Processing”, Y. Nakata, K. Tsubakimoto, N. Miyanaga, A. Narazaki, T. Shoji, Y. Tsuboi, Nanomaterials, 11 (2021) 305; https://doi.org/10.3390/nano11020305.
9. “Ultrafast Laser Processing of Ceramics: Comprehensive Survey of Laser Parameters”, A. Narazaki, H. Takada, D. Yoshitomi, K. Torizuka, Y. Kobayashi, Journal of Laser Applications, 33 (2020) 012009; https://lia.scitation.org/doi/10.2351/7.0000310.
10. “Laser-Induced Forward Transfer with Optical Stamp of a Protein-Immobilized Calcium Phosphate Film Prepared by Biomimetic Process to a Human Dentin”, A. Narazaki, A. Oyane, H. Miyaji, Applied Sciences, 10 (2020) 7984; https://doi.org/10.3390/app10227984.
11. “Nanodot array deposition via single shot laser interference pattern using laser-induced forward transfer”, Yoshiki Nakata, Eiki Hayashi, Koji Tsubakimoto, Noriaki Miyanaga, Aiko Narazaki, Tatsuya Shoji, and Yasuyuki Tsuboi, International Journal of Extreme Manufacturing, 2 (2020) 025101; https://iopscience.iop.org/article/10.1088/2631-7990/ab88bf/pdf.
12. “Study on nonthermal–thermal processing boundary in drilling of ceramics using ultrashort pulse laser system with variable parameters over a wide range”, Aiko Narazaki, Hideyuki Takada, Dai Yoshitomi, Kenji Torizuka, and Yohei Kobayashi, Applied Physics A, 126 (2020) 252; https://link.springer.com/article/10.1007/s00339-020-3410-2.
13. “Laser additive micro-patterning for biomedical applications using laser-induced transfer”, Aiko Narazaki, Ayako Oyane, and Hirofumi Miyaji, ICALEO 2019 Proceedings, (2019) Nano301.
14. “Pulse Width Dependence of Heat Accumulation in Ultrashort Pulse Laser Processing”, Aiko Narazaki, Hideyuki Takada, Dai Yoshitomi, Kenji Torizuka, and Yohei Kobayashi, ICALEO 2019 Proceedings, (2019) Nano604.
15. “Bioactive micropatterning of apatite immobilizing cell adhesion protein by laser-induced forward transfer with a shock absorber”, Aiko Narazaki, Ayako Oyane, Saki Komuro, Ryozo Kurosaki, Tomoko Kameyama, Ikuko Sakamaki, Hiroko Araki, and Hirofumi Miyaji, Optical Materials Express, 9 (2019) 2807; https://doi.org/10.1364/OME.9.002807.
16. “Local Melting of Gold Thin Films by Femtosecond Laser-Interference Processing to Generate Nanoparticles on a Source Target”, Yoshiki Nakata, Keiichi Murakawa, Noriaki Miyanaga, Aiko Narazaki, Tatsuya Shoji and Yasuyuki Tsuboi, Nanomaterials, 8 (2018) 477; https://doi.org/10.3390/nano8070477
17. “Evaluation of femtosecond laser-scribed Cu(In,Ga)Se2 solar cells using scanning spreading resistance microscopy”, Aiko Narazaki, Jiro Nishinaga, Hideyuki Takada, Tadatake Sato, Hiroyuki Niino, Kenji Torizuka, Yukiko Kamikawa-Shimizu, Shogo Ishizuka, Hajime Shibata, and Shigeru Niki, Applied Physics Express, 11 (2018) 032301
18. “Laser-induced forward transfer with optical stamp for high-quality film printing” (Conference Presentation), A. Narazaki, T. Sato, and H. Niino, Proceedings Volume 10519, Laser Applications in Microelectronic and Optoelectronic Manufacturing (LAMOM) XXIII; 105190O (2018) https://doi.org/10.1117/12.2288695, SPIE LASE, 2018, San Francisco, California, United States.
19. “Fabrication of Micropits by LIBWE for Laser Marking of Glass Materials”, Tadatake Sato, Aiko Narazaki, and Hiroyuki Niino, Journal of Laser Micro / Nanoengineering, 12 (2017) 248-253.
20. “Ultrafast laser scribing of transparent conductive oxides in Cu(In,Ga)Se2 solar cells via laser lift-off process: The control of laser-induced damage", A. Narazaki, T. Sato, H. Niino, H. Takada, K. Toriduka, J. Nishinaga, Y. Kamikawa-Shimizu, S. Ishizuka, H. Shibata, and S. Niki, Proceedings of SPIE, 10091 (2017) 100911E.
21. “Beam shaping by spatial light modulator and 4f system to square and top-flat for interference laser processing”, Kazuhito Osawa, Masataka Yoshida, Yoshiki Nakata, Noriaki Miyanaga, Aiko Narazaki, Tatsuya Shoji, and Yasuyuki Tsuboi, Proceedings of SPIE, 10091 (2017) 100911C.
22. “Femtosecond Laser Scribing of Cu(In,Ga)Se2 Thin-Film Solar Cell”, A. Narazaki, R. Kurosaki, T. Sato, H. Niino, H. Takada, K. Torizuka, J. Nishinaga, Y. Kamikawa-Shimizu, S. Ishizuka, H. Shibata, and S. Niki, Journal of Laser Micro / Nanoengineering, 11 (2016) 130.
23. “Laser Marking on Soda-Lime Glass by Laser-Induced Backside Wet Etching with Two-Beam Interference”, Tomoka Nakazumi, Tadatake Sato, Aiko Narazaki, and Hiroyuki Niino, Journal of Micromechanics and Microengineering, 26 (2016) 95015.
24. “High-resolution printing of functional microdots by double-pulse laser-induced forward transfer”, A. Narazaki, R. Kurosaki, T. Sato, and H. Niino, Proceedings of SPIE，9350 (2015) 93500I.
25. “Flexible Patterning of Functional Microdot by Laser-Induced Dot Transfer"，A. Narazaki, R. Kurosaki, T. Sato, and H. Niino, Journal of Laser Micro / Nanoengineering, 9 (2014) 257.
26. “On-Demand Deposition of Functional Oxide Microdots by Double-Pulse Laser-Induced Dot Transfer"，A. Narazaki, R. Kurosaki, T. Sato, Y. Kawaguchi, and H. Niino, Journal of Laser Micro / Nanoengineering, 9 (2014) 10.
27. “Laser Ablation of Carbon Fiber Reinforced Plastics: Laser-Ionization TOF Mass Spectrometric Study"，A. Narazaki, T. Sato, Y. Kawaguchi, and H. Niino, Journal of Laser Micro / Nanoengineering，9 (2014) 59.
28. “Laser Cutting of Carbon Fiber Reinforced Thermo-Plastics (CFRTP) by IR Laser Irradiation”，H. Niino, Y. Kawaguchi, T. Sato, A. Narazaki, R. Kurosaki, M. Muramatsu, S. Harada, K. Wakabayashi, M. Nagashima, J. Kase, M. Matsushita, K. Furukawa, M. Nishino，Journal of Laser Micro / Nanoengineering，9 (2014) 180.
29. “On-Demand Patterning of Indium Tin Oxide Microdots by Laser-Induced Dot Transfer"，A. Narazaki, R. Kurosaki, T. Sato, and H. Niino, Applied Physics Express，6 (2013) 92601.
30. “Laser-ionization Time-of-Flight mass spectrometric studies on laser ablation of carbon fiber reinforced plastics"，A. Narazaki, T. Sato, Y. Kawaguchi, R. Kurosaki, and H. Niino, Proceedings of LPCC, (2013) .
31. “On-Demand Preparation of Microdot Patterns by Laser-Induced Dot Transfer"，A. Narazaki, R. Kurosaki, T. Sato, Y. Kawaguchi, W. Watanabe, and H. Niino, Journal of Laser Micro / Nanoengineering， 7 (2012) 77.
32. “Variation in the etch rate of LIBWE fabricating deep microtrenches”，T. Sato, Y. Kawaguchi, R. Kurosaki, A. Narazaki, W. Watanabe, H. Niino，Journal of Laser Micro / Nanoengineering，7 (2012) 81.
33. “Laser-induced backside wet etching employing green DPSS laser and liquid metallic absorber”，T. Sato, Y. Kawaguchi, R. Kurosaki, A. Narazaki, W. Watanabe, H. Niino，Journal of Laser Micro / Nanoengineering，6 (2011) 204.
34. “Fabrication of multiple slanted microstructures on silica glass by laser-induced backside wet etching”，T. Sato, Y. Kawaguchi, R. Kurosaki, A. Narazaki, W. Watanabe, and H. Niino，Journal of Laser Micro / Nanoengineering， 5 (2010) 256.
35. “Flexible 3D deep microtrenches of silica glass by laser-induced backside wet etching”， T. Sato, R. Kurosaki, Y. Kawaguchi, A. Narazaki, and H. Niino，Applied Physics A-Materials Science & Processing，101 (2010) 319.
36. “Nano- and microdot array formation by laser-induced dot transfer"，A. Narazaki, R. Kurosaki, T. Sato, Y. Kawaguchi, and H. Niino, Applied Surface Science，255 (2009) 9703.
37. “Nano- and microdot array formation of FeSi2 by nanosecond excimer laser-induced forward transfer"，A. Narazaki, R. Kurosaki, T. Sato, Y. Kawaguchi, and H. Niino, Applied Physics Express，1 (2008) 57001.
38. “Surface microstructuring of inclined trench structures of silica glass by laser-induced backside wet etching”，H. Niino, Y. Kawaguchi, T. Sato, A. Narazaki, and R. Kurosaki，Journal of Laser Micro / Nanoengineering，3 (2008) 182.
39. “Synthesis and Photolysis of Biphenylenetetracarboxylic Dianhydride in Low-Temperature Neon Matrixes”，T. Sato, A. Narazaki, Y. Kawaguchi, and H. Niino，Chemistry Letters，37 (2008) 334.
40. “Surface microstructuring of silica glass by laser-induced backside wet etching with a DPSS UV laser”, Hiroyuki Niino, Yoshizo Kawaguchi, Tadatake Sato, Aiko Narazaki, and Ryozo Kurosaki, Applied Surface Science, 253 (2007) 8287-8291.
41. “Laser direct-write and crystallization of FeSi2 micro-dot array for NIR light-emitting device application"，A. Narazaki, R. Kurosaki, T. Sato, Y. Kawaguchi, and H. Niino, Proceedings of SPIE，6458 (2007) 645814.
42. “Laser-induced formation of photocatalytic TiO2 micronetworks on a UV-absorbing glass surface", A. Narazaki, Y. Kawaguchi, H. Niino, M. Shojiya, H. Koyo, K. Tsunetomo, Proceedings of SPIE，6459 (2007) 64590Q1.
43. “Surface Micro-Structuring of Silica Glass by Laser-Induced Backside Wet Etching with ns-Pulsed UV Laser at a High Repetition Rate”, Hiroyuki Niino, Yoshizo Kawaguchi, Tadatake Sato, Aiko Narazaki, Thomas Gumpenberger, and Ryozo Kurosaki, Journal of Laser Micro / Nanoengineering, 1 (2006) 39-43.
44. “Fabrication and characterisation of a microfluidic device for bead-array analysis by the LIBWE method”，T. Gumpenberger Thomas, T. Sato, R. Kurosaki, A. Narazaki, Y. Kawaguchi, and H. Niino, Journal of Laser Micro / Nanoengineering, 1 (2006) 201.
45. “Fabrication of a novel microfluidic device incorporating 2-D array of microbeads: Surface reaction on microbeads fixed within microchannels”，T. Gumpenberger, T. Sato, R. Kurosaki, A. Narazaki, Y. Kawaguchi, and H. Niino, Chemistry Letters，35 (2006) 218.
46. “Rapid prototyping of silica glass microstructures by the LIBWE method: Fabrication of deep microtrenches”, Yoshizo Kawaguchi, Tadatake Sato, Aiko Narazaki, Ryozo Kurosaki, and Hiroyuki Niino, Journal of Photochemistry and Photobiology A: Chemistry, 182 (2006) 319-324.
47. “Laser-induced Formation of a Photocatalytic TiO2 Micronetwork on a UV-absorbing SiO2-based Glass Surface"，A. Narazaki, Y. Kawaguchi, H. Niino, M. Shojiya, H. Koyo, and K. Tsunetomo, Online Proceedings of LAMP2006, (2006) #6-38
48. “Formation of a TiO2 micro-network on a UV-absorbing SiO2-based glass surface by excimer laser irradiation"，A. Narazaki, Y. Kawaguchi, H. Niino, M. Shojiya, H. Koyo, K. Tsunetomo，Chemistry of Materials，17 (2005) 6651.
49. “Etching a micro-trench with a maximum aspect ratio of 60 on silica glass by laser-induced backside wet etching (LIBWE)”, Yoshizo Kawaguchi, Tadatake Sato, Aiko Narazaki, Ryozo Kurosaki and Hiroyuki Niino, Japanese Journal of Applied Physics, 44 (2005) L176.
50. “Transient pressure induced by laser ablation of toluene, a highly laser-absorbing liquid”，Y. Kawaguchi, X. Ding, A. Narazaki, T. Sato, and H. Niino，Applied Physics A-Materials Science & Processing，80 (2005) 275.
51. “Preferential Crystallization of β-FeSi2 from Micro-droplets Generated by Laser Ablation"，A. Narazaki, T. Sato, Y. Kawaguchi, and H. Niino, MRS Fall Meeting Proceedings，848 (2005) FF3.9.1.
52. “Micron-and submicron-sized surface patterning of silica glass by LIBWE method”, Ximing Ding, Yoshizo Kawaguchi, Tadatake Sato, Aiko Narazaki, Ryozo Kurosaki, Hiroyuki Niino, Journal of Photochemistry and Photobiology A: Chemistry, 166 (2004) 129-133.
53. “Fabrication of Microarrays on Fused Silica Plates Using the Laser-Induced Backside Wet Etching Method”, Ximing Ding, Yoshizo Kawaguchi, Tadatake Sato, Aiko Narazaki, and Hiroyuki Niino, Langmuir, 20 (2004) 9769-9774.
54. “Effect of annealing on the tolerance of LiCaAlF6 single crystals against F2 laser irradiation”，Y. Kawaguchi, A. Narazaki, T. Sato, R. Kurosaki, H. Niino, H. Sato, and T. Fukuda，Japanese Journal of Applied Physics，43-9A (2004) 6168.
55. “Preparation of carbon nitride film by cryogenic laser processing”， T. Sato, A. Narazaki, Y. Kawaguchi, and H. Niino, Applied Physics A-Materials Science & Processing，79 (2004) 1477.
56. “Micron- and Submicron-Sized Surface Patterning of Silica Glass by LIBWE Method”，X. Ding, Y. Kawaguchi, T. Sato, A. Narazaki, R. Kurosaki, and H. Niino, Journal of Photochemistry and Photobiology A-Chemistry, 166 (2004) 129.
57. “Imprinting by hot embossing in polymer substrates using a template of silica glass surface-structured by the ablation of LIBWE method”，H. Niino, X. Ding, R. Kurosaki, A. Narazaki, T. Sato, and Y. Kawaguchi, Applied Physics A-Materials Science & Processing，A79 (2004) 827.
58. “Transient pressure induced by laser ablation of toluene liquid: toward the understanding of laser-induced backside wet etching”，Y. Kawaguchi, X. Ding, A. Narazaki, T. Sato, and H. Niino, Applied Physics A-Materials Science & Processing，79 (2004) 883.
59. “Initial stage of laser ablation of LiCaAlF6 single crystal under F2 laser irradiation”， Y. Kawaguchi, A. Narazaki, T. Sato, R. Kurosaki, H. Niino, H. Sato, and T. Fukuda，Applied Physics A-Materials Science & Processing，79 (2004) 1579.
60. “Generation and photoreactions of 2, 4, 6-trinitreno-1, 3, 5-triazine, a septet trinitrene”, Tadatake Sato, Aiko Narazaki, Yoshizo Kawaguchi, Hiroyuki Niino, Götz Bucher, Dirk Grote, J. Jens Wol"Room-temperature fabrication of β-FeSi2 microprecipitates by pulsed laser deposition"，A. Narazaki, T. Sato, Y. Kawaguchi, and H. Niino, Proceedings of SPIE，5662 (2004) 400.
61. “Surface microfabrication of fused silica glass by UV laser irradiation”，H. Niino, Y. Kawaguchi, T. Sato, A. Narazaki, X. Ding, and R. Kurosaki, Proceedings of SPIE，5339 (2004) 112.
62. ff, Hans Henning Wenk, and Wolfram Sander, J. Am. Chem. Soc., 126 (2004) 7846–7852.
63. “Room-temperature preparation of β-FeSi2 microprecipitates by the KrF excimer laser ablation of an iron disilicide alloy target"， A. Narazaki, T. Sato, Y. Kawaguchi, and H. Niino, Applied Physics Letters, 83 (2003) 3078.
64. “Plume dynamics of iron disilicide studied by time-of-flight mass spectroscopy"，A. Narazaki, T. Sato, Y. Kawaguchi, and H. Niino, Applied Surface Science，208-209 (2003) 52.
65. “Surface micro-fabrication of silica glass by excimer laser irradiation of organic solvent”, Hiroyuki Niino, Yoshimi Yasui, Ximing Ding, Aiko Narazaki, Tadatake Sato, Yoshizo Kawaguchi, AkiraYabe, Journal of Photochemistry and Photobiology A: Chemistry, 158 (2003) 179-182.
66. “Resistance of LiCaAlF6 single crystals against F2 laser irradiation”，Y. Kawaguchi, A. Narazaki, H. Niino, H. Sato, T. Fukuda, S. Shimamura, Japanese Journal of Applied Physics，42-8B (2003) L1015.
67. “Site-selective dye deposition on microstructures of fused silica fabricated using the LIBWE method”, X. Ding, Y. Kawaguchi, T. Sato, A. Narazaki, and H. Niino, Chemical Communications, 17 (2003) 2168-2169.
68. “Dicyanocarbodiimide and Trinitreno‐s‐triazine Generated by Consecutive Photolysis of Triazido‐s‐triazine in a Low‐Temperature Nitrogen Matrix”, Tadatake Sato, Aiko Narazaki, Yoshizo Kawaguchi, Hiroyuki Niino, and Götz Bucher, Angewandte Chemie International Edition, 42 (2003) 5206-5209.
69. “Pulsed Laser Deposition of Semiconductor-ITO Composite Films on Electric-Field-Applied Substrates"，A. Narazaki, T. Sato, Y. Kawaguchi, H. Niino, A. Yabe, T. Sasaki, and N. Koshizaki，Applied Surface Science，197-198 (2002) 438.
70. “Improvement in Electrical Conductivity of ITO Films Prepared via Pulsed Laser Deposition on Electric-Field-Applied Substrates"，A. Narazaki, Y. Kawaguchi, H. Niino, T. Sasaki, and N. Koshizaki，Japanese Journal of Applied Physics，41 (2002) 3760.
71. “Surface structure and second-order nonlinear optical properties of thermally poled WO3-TeO2 glasses doped with Na+"，A. Narazaki, K. Tanaka, and K. Hirao，Journal of the Optical Society of America B - Optical Physics，19 (2002) 54.
72. “Preparation of nanocrystalline titania films by pulsed laser deposition at room temperature”, Naoto Koshizaki, Aiko Narazaki, and Takeshi Sasaki, Applied Surface Science, 197-198 (2002) 624-627.
73. “Plume dynamics in ZnO under ArF laser radiation”，Y. Kawaguchi、A. Narazaki, T. Sato, H. Niino, A. Yabe，Applied Surface Science，197-198 (2002) 226.
74. “Laser Ablation and Photo-dissociation of Solid-Nitrogen Film by UV ps-Laser Irradiation”，H. niino, t. Sato, A. Narazaki, Y. Kawaguchi, and A. Yabe, Applied Surface Science，197-198 (2002) 67.
75. “The onset of optical breakdown in KrF-laser-irradiated silica glass”，Y. Kawaguchi, A. Narazaki, T. Sato, H. Niino, A. Yabe, S.C.Langford, and J.T.Dickinson, Applied Surface Science，197-198 (2002) 50.
76. “Relaxation Phenomena in Second-Order Nonlinearity of Thermally and Optically Poled Nb2O5-TeO2 Glasses”，A. Narazaki, K. Yonesaki, K. Tanaka, J. Si, K. Hirao, Journal of Physics D-Applied Physics, 35 (2002) 2026.
77. “DC-electric-field effect on CdSe nanocrystal embedded in indium tin oxide film and its second-order nonlinearity"，A. Narazaki, T. Sasaki, N. Koshizaki, T. Hirano, J. Sasai, K. Tanaka, and K. Hirao, Scripta Materialia, 44 (2001) 1219.
78. and XPS studies on the surface structure of poled ZnO-TeO2 glasses with second-order nonlinearity"，A. Narazaki, K. Tanaka, K. Hirao, T. Hashimoto, H. Nasu, and K. Kamiya, Journal of the American Ceramics Society，84 (2001) 214.
79. “Parameter effect on the crystallization of Nd:yttrium aluminum garnet laser-ablated TiO2 thin film”，M. Pal, A. Narazaki, T. Sasaki, and N. Koshizaki, Journal of Materials Research，16 (2001) 3158.
80. “Size Distribution and Growth Mechanism of Co3O4 Nanoparticles Fabricated by Pulsed Laser Deposition”，N. Koshizaki, A. Narazaki, T. Sasaki, Scripta Materialia, 44 (2001) 1925.
81. “Second-harmonic generation in Ge–As–S glasses by electron beam irradiation and analysis of the poling mechanism”, Katsuhisa, Tanaka, Aiko Narazaki, Kazuyuki Hirao, Optics Communications, 198 (2001) 187-192.
82. “Second-harmonic generation in Ge20As25S55 glass irradiated by an electron beam”, Qiming Liu, Fuxi Gan, Xiujian Zhao, Katsuhisa Tanaka, Aiko Narazaki, and Kazuyuki Hirao, Optics Letters, 26 (2001), 1347-1349.
83. “Large optical second-order nonlinearity of poled WO 3–TeO 2 glass”, Katsuhisa, Tanaka, Aiko Narazaki, Kazuyuki Hirao, Optics Letters, 25 (2000) 251-253.
84. “Poling-induced structural change and second-order nonlinearity of Na+-doped Nb2O5-TeO2 glass”, Katsuhisa Tanaka, Aiko Narazaki, Yoshinori Yonezaki, and Kazuyuki Hirao, Journal of Physics: Condensed Matter, 12 (2000) L513.
85. “Poling-induced crystallization of tetragonal BaTiO3 and enhancement of optical second-harmonic intensity in BaO-TiO2-TeO2 glass system", A. Narazaki, K. Tanaka, and K. Hirao, Applied Physics Letters, 75 (1999) 3399.
86. “Optical second-order nonlinearity of transparent glass-ceramics containing BaTiO3 precipitated via surface-crystallization", A. Narazaki, K. Tanaka, and K. Hirao, Journal of Materials Research, 14, (1999) 3640.
87. “Induction and relaxation of optical second-order nonlinearity in tellurite glasses", A. Narazaki, K. Tanaka, K. Hirao, and N. Soga, Journal of Applied Physics, 85 (1999) 2046.
88. “Effect of poling temperature on optical second-harmonic intensity of lithium sodium tellurite glass", A. Narazaki, K. Tanaka, and K. Hirao, and N. Soga, Journal of the American Ceramics Society, 81(1998) 2735.
89. “Effect of poling temperature on optical second harmonic intensity of sodium zinc tellurite glasses", A. Narazaki, K. Tanaka, K. Hirao, and N. Soga, Journal of Applied Physics, 83 (1998) 3986.
90. “Optical second harmonic generation in poled MgO-ZnO-TeO2 and B2O3-TeO2 glasses”, A. Narazaki, K. Tanaka, K. Hirao, and N. Soga, Journal of Non-Crystalline Solids, 203 (1996) 49-54.
91. “Poling temperature dependence of optical second‐harmonic intensity of MgO–ZnO–TeO2 glasses”, A. Narazaki, K. Tanaka, K. Hirao, and N. Soga, Journal of Applied Physics, 79 (1996) 3798.

ResearcherID

Books

1. Narazaki A. (2021) Characterization of Laser-Processed Samples. In: Sugioka K. (eds) Handbook of Laser Micro- and Nano-Engineering.(https://doi.org/10.1007/978-3-319-69537-2_64-1)

Invited talks at international conferences

1. "Data-driven ultrashort pulse laser processing based on fast laser modulation, in-process monitoring and AI optimization"，Aiko Narazaki, Dai Yoshitomi, Hideyuki Takada, Godai Miyaji, PULMM2023 Progress in Ultrafast Laser Modifications of Materials，Nikko, Japan, Jun 8, 2023.
2. "Data-driven ultrashort pulse laser processing based on novel in-process monitoring & AI high-speed optimization"，Aiko Narazaki, Hideyuki Takada, Daisuke Nagai, Godai Miyaji, Naoyuki Nakamura, Jyunichi NIshimae, Toshio Otsu, Tomoharu Nakazato, Yohei Kobayashi, Dai Yoshitomi, CLEO2023，San Jose, USA, May 10, 2023.
3. "Glass Microfabrication with High-speed Laser Modulation and In-process Monitoring Toward Data-driven Ultrashort Pulse Laser Processing"，Aiko Narazaki, Dai Yoshitomi, Hideyuki Takada, Daisuke Nagai, Godai Miyaji，Optica laser congress and exhibition，Hybrid, Dec 12, 2022.
4. "Data-driven ultrashort pulse laser processing toward real-time CPS"，Aiko Narazaki, Dai Yoshitomi, Hideyuki Takada, Daisuke Nagai, Godai Miyaji, ICALEO 2022，Orland, USA, Oct 19, 2022.
5. "Laser-Induced Forward Transfer of Biomaterials Prepared by Biomimetic Process"，A. Narazaki, A. Oyane, H. Miyaji, Optics-2021, 2nd International Summit on OPTICS, PHOTONICS AND LASER TECHNOLOGIES，Online, Jun 30, 2021.
6. "Laser Additive Micro-patterning for Biomedical Applications using Laser-Induced Transfer", Aiko Narazaki, Ayako Oyane, Hirofumi Miyaji, ICALEO 2019, Orland, USA, Oct 8, 2019.
7. “Laser lift-off process for additive micropattering of functional particles and films”, MHS2018 The 29th 2018 International Symposium on Micro-NanoMechatronics and Human Science, Nagoya, Japan, Dec 12, 2018.
8. “Toward High-Resolution Printing of Microdots: Laser-Induced Forward Transfer and Finite Element Approach”, APLS 2016 The 10th Asia-Pacific Laser Symposium, Jeju, Korea, May 12, 2016.
9. “High-resolution printing of functional microdots by double-pulse laser-induced forward transfer”, Photonics West 2015, San Francisco, USA, Feb 10, 2015.
10. “Flexible patterning of functional microdot by double-pulse laser-induced dot transfer”，LPM2014，Vilnius, Lithuania, Jun 19, 2014.
11. “Laser-induced formation of photocatalytic TiO2 micronetworks on a UV-absorbing glass surface”, Photonics West 2007, San Jose, USA, Jan 23, 2007.

International conference committee

1. CLEO Pacific Rim 2024,Program sub-committee members:C5.Laser Processing and Innovative Applications
2. CLEO 2024,Program sub-committee members
3. Photonics WEST, LAMOM conference, Program committee (2023-)
4. LPM2023, Steering committee
5. COLA2024, Program committee
6. CLEO Pacific Rim 2022,Program sub-committee members:C5.Laser Processing and Innovative Applications（https://www.cleopr2022.org/committees-CLEOPR.html）
7. Photonics WEST, LAMOM conference,Chair (2020-2023)（https://spie.org/PWL/conferencedetails/lamom）
8. COLA2021/2022, Co-chair（https://cola2021.org/）
9. SLPC2020, Vice chair of program committee
10. Photonics WEST 2020, LAMOM conference, Co-chair
11. COLA2019, Steering committee （https://cola2019.org/）
12. LAMP2019, Steering committee（http://www.jlps.gr.jp/news/2018/01/lamp2019.html）