Department of Electronics,Information and Communic

Mitsuhiro Kusaba

  (草場 光博)

Profile Information

Affiliation
Professor, Faculty of Engineering, Department of Electrical, Electronic and Information Engineering, Osaka Sangyo University
Degree
博士(工学)(大阪大学)

Researcher number
70268283
J-GLOBAL ID
200901067387235812
researchmap Member ID
1000183204

External link

Papers

 63
  • Kenta Hirai, Tomoyo Tanaka, Daisuke Tsutsumi, Masaki Hashida, Hitoshi Sakagami, Mitsuhiro Kusaba
    Journal of Physics D: Applied Physics, 57(38) 385101-385101, Jun 27, 2024  Peer-reviewedCorresponding author
    Abstract The surface morphology of silicon solar cells irradiated with KrF excimer laser pulses (λ = 248 nm, τ = 20 ns) was investigated below the experimentally observed melting threshold fluence (F th) of 0.47 J cm−2 (±20%). At laser fluences of 0.23–0.48 J cm−2 (equivalent to 0.49F th to 1.0F th), nanodot structures with a height and width of approximately 60–120 nm were periodically formed with an interdot spacing similar to the laser wavelength. The observed nanodot density (29 dots μm2) was higher than that previously obtained at longer wavelengths. Furthermore, crystallinity analysis by micro-Raman spectroscopy revealed a Raman shift of 519.56 cm−1 after irradiation (N= 1500 pulses), compared with 518.27 cm−1 prior to irradiation. A laser fluence of 0.41 J cm−2 ( = 0.87F th) was found to induce compressive stress on the silicon solar cell surface.
  • Kosei Yamamoto, Ryuhei Matsuda, Keisuke Takenaka, Yuji Sato, Yorihiro Yamashita, Ayahito Saikai, Taisei Yachi, Mitsuhiro Kusaba, Masahiro Tsukamoto
    Journal of Laser Applications, 36(1), Feb 1, 2024  Peer-reviewed
    A tungsten carbide-cobalt (WC-Co) composite layer was formed on a stainless-steel type 304 (SS304) substrate using multibeam laser metal deposition (LMD) with blue diode lasers. This paper aims to provide WC-Co layer formation with low porosity and high layer formation efficiency by using the multibeam LMD process. The effects of process parameters such as laser output power and powder feed rate are tied together to explain the geometry of the melt layer as well as the fraction of the laser energy used for melting a material. The experimental results show that the porosity rate and layer formation efficiency were recorded at 0.3% and 0.0042 mm3/J, respectively, at the laser output power of 180 W and a powder feed rate of 75 mg/s. It was revealed that layer formation efficiency was dependent on the laser output power.
  • Mitsuhiro Kusaba, Fumitaka Nigo, Masaki Hashida
    IEEJ Transactions on Fundamentals and Materials, 143(10) 314-319, Oct 1, 2023  Peer-reviewedLead authorCorresponding author
  • Keisuke Takenaka, Masaki Hashida, Hitoshi Sakagami, Shin-ichiro Masuno, Mitsuhiro Kusaba, Shigeru Yamaguchi, Satoru Iwamori, Yuji Sato, Masahiro Tsukamoto
    Review of Scientific Instruments, 93(9) 093001-093001, Sep 1, 2022  Peer-reviewed
    The Perpendicular Period and Phase Scanning (P3S) method can evaluate the uniformity of a laser-induced periodic surface structure (LIPSS). P3S assesses the uniformity of LIPSS using the standard deviation of the peak period and the average of the phase difference in the direction perpendicular to LIPSS. The P3S method demonstrates that LIPSS formed by two-color double-pulse irradiation is reduced to a quarter of the period dispersion, and the average phase difference of LIPSS is also reduced compared to the single-pulse irradiation. In addition, a 3D electromagnetic particle-in-cell simulation was performed to evaluate the possibility of an improved uniformity of LIPSS. The results confirm that the two-color double-pulse irradiation produces a uniform LIPSS and validates the effectiveness of the P3S method to assess the uniformity of LIPSS.
  • K. Takenaka, N. Shinohara, M. Hashida, M. Kusaba, H. Sakagami, Y. Sato, S. Masuno, T. Nagashima, M. Tsukamoto
    Applied Physics Letters, 119(23) 1-6, Dec 6, 2021  Peer-reviewed

Misc.

 62

Books and Other Publications

 4

Presentations

 88

Major Professional Memberships

 9

Research Projects

 5

研究テーマ

 5
  • 研究テーマ(英語)
    次世代太陽電池のためのレーザー加工技術の開発
    研究期間(開始)(英語)
    2015/04/01
  • 研究テーマ(英語)
    次世代量子線がん治療のための炭素源の開発
    研究期間(開始)(英語)
    2018/03/01
  • 研究テーマ(英語)
    レーザーによる元素分離の基礎的研究
    研究期間(開始)(英語)
    1989/04/01
  • 研究テーマ(英語)
    真空紫外レーザー照射により誘起された光化学に関する研究
    研究期間(開始)(英語)
    1999/04/01
    研究期間(終了)(英語)
    2007/08/31
  • 研究テーマ(英語)
    紫外レーザー照射によるカーボンナノチューブの生成
    研究期間(開始)(英語)
    2003/04/01
    研究期間(終了)(英語)
    2007/05/31