CVClient

Takashi Arikawa

  (有川 敬)

Profile Information

Affiliation
Associate Professor, Graduate School of Engineering, University of Hyogo
Degree
Ph.D.(May, 2009, Kyoto University)

ORCID ID
 https://orcid.org/0000-0002-7330-2275
J-GLOBAL ID
201401045950404460
researchmap Member ID
7000009115

External link

Papers

 80
  • Takashi Arikawa, Jaeyong Kim, Toshikazu Mukai, Naoki Nishigami, Masayuki Fujita, Tadao Nagatsuma, Koichiro Tanaka
    Nature Communications, 15(1), Jul 2, 2024  
    Abstract As a key component for next-generation wireless communications (6 G and beyond), terahertz (THz) electronic oscillators are being actively developed. Precise and dynamic phase control of ultrafast THz waveforms is essential for high-speed beam steering and high-capacity data transmission. However, measurement and control of such ultrafast dynamic process is beyond the scope of electronics due to the limited bandwidth of the electronic equipment. Here we surpass this limit by applying photonic technology. Using a femtosecond laser, we generate offset-free THz pulses to phase-lock the electronic oscillators based on resonant tunneling diode. This enables us to perform phase-resolved measurement of the emitted THz electric field waveform in time-domain with sub-cycle time resolution. Ultrafast dynamic response such as anti-phase locking behaviour is observed, which is distinct from in-phase stimulated emission observed in laser oscillators. We also show that the dynamics follows the universal synchronization theory for limit cycle oscillators. This provides a basic guideline for dynamic phase control of THz electronic oscillators, enabling many key performance indicators to be achieved in the new era of 6 G and beyond.
  • F. Blanchard, J. E. Nkeck, L. Guiramand, S. Zibod, K. Dolgaleva, T. Arikawa, K. Tanaka
    Optica, Sep 20, 2022  
  • Tomoki Hiraoka, Yuta Inose, Takashi Arikawa, Hiroshi Ito, Koichiro Tanaka
    Nature communications, 13(1) 3740-3740, Jun 29, 2022  
    Optical frequency combs in the terahertz frequency range are long-awaited frequency standards for spectroscopy of molecules and high-speed wireless communications. However, a terahertz frequency comb based on a low-cost, energy-efficient, and room-temperature-operating device remains unavailable especially in the frequency range of 0.1 to 3 THz. In this paper, we show that the resonant-tunneling-diode (RTD) oscillator can be passively mode-locked by optical feedback and generate a terahertz frequency comb. The standard deviation of the spacing between the comb lines, i.e., the repetition frequency, is reduced to less than 420 mHz by applying external bias modulation. A simulation model successfully reproduces the mode-locking behavior by including the nonlinear capacitance of RTD and multiple optical feedback. Since the mode-locked RTD oscillator is a simple semiconductor device that operates at room temperature and covers the frequency range of 0.1 to 2 THz (potentially up to 3 THz), it can be used as a frequency standard for future terahertz sensing and wireless communications.
  • François Blanchard, Takashi Arikawa, Koichiro Tanaka
    Sensors, 22(12) 4482-4482, Jun 14, 2022  
  • Hiraoka Tomoki, Arikawa Takashi, Inose Yuta, Ito Hiroshi, Tanaka Koichiro
    JSAP Annual Meetings Extended Abstracts, 2021.1 836-836, Feb 26, 2021  

Misc.

 35

Books and Other Publications

 2

Presentations

 99

Research Projects

 11