中央研究院

原子與分子科學研究所

原子與分子科學研究所的研究，是從原子與分子的尺度出發，以理論與實驗方法探討自然界的物理、化學與生命現象

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This is a test 2026-01-24

恭喜鄭海峰博士(魏金明老師實驗室)榮獲本院115年度第1梯次「一般博士後研究學者」。 2025-12-19

恭喜莊羿廷同學 (許良彥老師實驗室) 榮獲113學年度國立臺灣大學研究生校長獎。 2025-11-24

Announcement

本所成所30週年紀念特刊(中文版)已出刊，歡迎閱覽。 2025-11-24

Welcome

歡迎本所新聘合聘研究員阮雪芬特聘教授 (國立臺灣大學生命科學系)。 2025-08-08

近期研究成果 Research Highlights

J. Chem. Phys. 162, 034107 (2025)

Liang-Yan Hsu, et. al

Non-Adiabatic Quantum Electrodynamic Effects on Electron–Nucleus–Photon Systems: Single Photonic Mode vs Infinite Photonic Modes [Feature Article]

Phys. Rev. Lett. (2026)

Efficient and high-fidelity entanglement in cavity QED

The so-called state-carving protocol generates high-fidelity entangled states at an atom-cavity interface without requiring high cavity cooperativity. However, this protocol is limited to 50% efficiency, which restricts its applicability. We propose a simple modification to the state-carving protocol to achieve efficient entanglement generation, with unit probability in principle. Unlike previous two-photon schemes, ours employs only one photon which interacts with the atoms twice - avoiding separate photon detections which causes irrecoverable probability loss.

Optica Quantum 3, 590 (2025)

Hsiang-Hua Jen, et. al

Satellites promise global-scale quantum networks

Adv. Funct. Mater. e13406 (2025)

Ultrathin Fluorescent Nanodiamond Films for Nanoscale

Nanoscale quantum sensing is playing an increasingly critical role across diverse areas of research, particularly in the rapidly evolving field of semiconductor nanoelectronics. In this work, ultrathin fluorescent nanodiamond (FND) films are developed to function as quantum sensors for in operando measurements of magnetic fields and temperature in semiconductor devices. FNDs are electrically insulating carbon nanomaterials containing nitrogen-vacancy (NV) centers, renowned for their exceptional photostability and distinctive quantum properties. An electrospray deposition method is first established to produce uniform, near-monolayer FND films on bipolar junction transistors (BJTs) and field-effect transistors (FETs) without compromising their performance. Then, optically detected magnetic resonance (ODMR)s is employed to detect magnetic fields and monitor temperature increases as electrical currents are passed through the FND-coated semiconductor chips.

學術榮譽 Academic Honors

Leap Fellowship of FAOS

恭賀賴品光老師榮獲傑出人才發展基金會「第二屆飛躍講座」。

2026/01/20

2025 APS Fellow

恭賀本所合聘研究員林敏聰特聘教授，獲選2025年美國物理學會會士。

2025/10/16

JCP Best Theory Paper

恭賀許良彥老師榮獲2024 JCP Best Theory Paper Award by an Emerging Investigator

2025/09/02

NSTC Outstanding Research Award

恭賀許良彥老師榮獲國科會113年度傑出研究獎。

2025/02/26