Progress in Semiconductor Quantum electronics
Date : June 24, 2024 13:00 ~ 18:00
Speaker : Andrew Dzurak(Univ. of New South Wales)
Professor : Prof. Dohun Kim
Location : 56-105
- Overview
Quantum computers, which utilize phenomena such as superposition and entanglement as resources, are anticipated to potentially transform paradigms across all areas of science and engineering. Research efforts to implement quantum computers in various physical systems are underway globally.
Among these, the semiconductor spin qubit approach is gaining attention as a promising method for developing scalable quantum processors, due to its long coherence times and high compatibility with silicon CMOS technology.
This workshop aims to present the latest research and the status of industry-academic collaboration in the field of semiconductor quantum circuits, inviting world-leading researchers in this cutting-edge area.
- Invited Speakers
Andrew Dzurak (Univ. of New South Wales)
Kenta Takeda (RIKEN)
Dohun Kim (Seoul National Univ.)
Sven Rogge (Univ. of New South Wales)
Ferdinand Kuemmeth (Univ. of Copenhagen)
Quantum computers, which utilize phenomena such as superposition and entanglement as resources, are anticipated to potentially transform paradigms across all areas of science and engineering. Research efforts to implement quantum computers in various physical systems are underway globally.
Among these, the semiconductor spin qubit approach is gaining attention as a promising method for developing scalable quantum processors, due to its long coherence times and high compatibility with silicon CMOS technology.
This workshop aims to present the latest research and the status of industry-academic collaboration in the field of semiconductor quantum circuits, inviting world-leading researchers in this cutting-edge area.
- Invited Speakers
Andrew Dzurak (Univ. of New South Wales)
Kenta Takeda (RIKEN)
Dohun Kim (Seoul National Univ.)
Sven Rogge (Univ. of New South Wales)
Ferdinand Kuemmeth (Univ. of Copenhagen)
Files (1)
- Poster_progress_in_Semiconductor_Quantum_Electronics_final.pptx (5 MB, download:87)