Aulia Anisa Firdausさんが the 4th International Symposium on Physics and Applications (ISPA) に てBest Presenterを受賞
2025/11/28
- 地域環境システム専攻
受賞者
Aulia Anisa Firdausさん(地域環境システム専攻)
指導教員
石井 康之 教授(工学部)
学会・大会名
the 4th International Symposium on Physics and Applications (ISPA)
賞名
Best Presenter
発表題目
Establishment of pressure-temperature phase diagram of l-Ga by analysing the electrical and magnetic properties under pressure
研究内容
Superconductors can carry electricity without energy loss, making them key to future energy technologies. Our research focuses on the organic superconductor λ-(BETS)₂GaBrₓCl₄₋ₓ, where we create mixed crystals to study how pressure influences electron interactions and the stability of superconductivity. By tuning both chemical composition and applying physical pressure, we aim to reveal why superconductivity becomes stronger or weaker under different conditions.
This study clarified how pressure and chemical substitution affect the stability of superconductivity in λ-(BETS)₂GaBrₓCl₄₋ₓ. By measuring the lower critical field (Hc₁) and superconducting transition temperature, we provided new insights into the mechanisms of unconventional superconductivity.
研究目的
Superconductors can carry electricity without energy loss, making them key to future energy technologies. Our research focuses on the organic superconductor λ-(BETS)₂GaBrₓCl₄₋ₓ, where we create mixed crystals to study how pressure influences electron interactions and the stability of superconductivity. By tuning both chemical composition and applying physical pressure, we aim to reveal why superconductivity becomes stronger or weaker under different conditions.
This study clarified how pressure and chemical substitution affect the stability of superconductivity in λ-(BETS)₂GaBrₓCl₄₋ₓ. By measuring the lower critical field (Hc₁) and superconducting transition temperature, we provided new insights into the mechanisms of unconventional superconductivity.
研究目的
Superconductivity still has many mysteries, and we aim to uncover how it works through experiments.
今後の展望
Our goal is to develop more advanced and practical superconductors, not only eliminating energy loss but also paving the way for breakthroughs in quantum computing and other next-generation technologies. This research will help shape a future where these innovations become reality.