Yang Dong | Quantum sensing | Best Researcher Award

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Mr. Yang Dong | Quantum sensing | Best Researcher Award

Assistant Researcher at University of Science and Technology of China

Yang Dong is an Associate Researcher at the CAS Key Laboratory of Quantum Information at the University of Science and Technology of China (USTC), where his work centers on the precise control and sensing of quantum systems, specifically using solid-state spins in diamond. His expertise lies in manipulating nitrogen-vacancy (NV) centers to explore and enhance quantum phenomena, making him a vital contributor to the advancement of quantum technology. After earning his Ph.D. in Optics and Optical Engineering from USTC in 2018, he continued his research as a postdoctoral fellow and later as an assistant researcher, steadily building his reputation within the quantum science community. His research not only deepens the fundamental understanding of spin dynamics and coherence but also contributes to the development of practical quantum sensors and devices. Yang Dong’s interdisciplinary approach, combining experimental physics, quantum mechanics, and engineering techniques, has positioned him at the forefront of China’s ambitious push in quantum science. He is recognized for his commitment to scientific rigor and collaborative innovation, working closely with physicists and engineers to develop technologies with far-reaching implications for precision measurement, navigation, and information processing in quantum systems.

Professional Profiles

Google Scholar

Education

Yang Dong has built a solid academic foundation in physics and quantum optics through rigorous training at two of China’s top universities. He earned his Ph.D. in June 2018 from the Department of Optics and Optical Engineering at the University of Science and Technology of China (USTC), where he focused on quantum control in solid-state systems. His doctoral research laid the groundwork for his current specialization in using nitrogen-vacancy (NV) centers in diamond for quantum sensing applications. Prior to his doctoral studies, Yang Dong completed his undergraduate education at Lanzhou University, where he obtained a Bachelor of Science degree from the School of Nuclear Science and Technology in June 2013. This background provided him with a robust understanding of nuclear physics and radiation detection, which he later integrated into his quantum research. His transition from nuclear science to optical engineering reflects a commitment to interdisciplinary exploration, and his education has been marked by a consistent drive to deepen his expertise in quantum phenomena. Through rigorous coursework, hands-on laboratory experience, and a strong theoretical foundation, Yang Dong has developed a comprehensive academic profile that supports his innovative research in quantum control and sensing.

Professional Experience

Yang Dong has accumulated valuable professional experience in quantum science through his continuous engagement with the University of Science and Technology of China (USTC). From 2018 to 2020, he served as a Postdoctoral Fellow at the Joint CAS Key Laboratory of Quantum Information, where he expanded his research on quantum sensing and control using solid-state spin systems. During this period, he focused on developing experimental methods to enhance the coherence and sensitivity of nitrogen-vacancy (NV) centers in diamond, which laid the foundation for his independent research trajectory. In 2020, Yang Dong was appointed Assistant Researcher at the same laboratory, a position he held until 2025. As an Assistant Researcher, he led projects aimed at the practical implementation of quantum sensing technologies and contributed to the development of high-precision magnetometry techniques. His work during this time involved both theoretical modeling and experimental validation, often collaborating with leading scientists in the field. These experiences not only solidified his technical skills but also demonstrated his leadership in managing interdisciplinary research teams. Throughout his professional journey, Yang Dong has consistently pushed the boundaries of what is possible in quantum technology, making him a key contributor to the lab’s ongoing scientific achievements.

Research Interest

Yang Dong’s research interests lie at the intersection of quantum information science, solid-state physics, and optical engineering, with a focus on quantum control and quantum sensing. He is particularly interested in the application of nitrogen-vacancy (NV) centers in diamond, which serve as an ideal platform for exploring spin dynamics, coherence preservation, and quantum metrology. His work is motivated by both fundamental scientific inquiry and the development of practical technologies for high-resolution sensing. Yang Dong explores how external fields—such as magnetic and electric fields—interact with NV centers, aiming to improve sensitivity, spatial resolution, and robustness under ambient conditions. A key area of his interest is the optimization of spin readout fidelity and the design of robust control protocols that enhance measurement precision. He also investigates hybrid quantum systems and scalable architectures that could integrate NV centers with photonic or mechanical elements, extending the utility of quantum sensors in real-world environments. His research is deeply interdisciplinary, drawing from quantum optics, material science, and engineering. Through this integrated approach, Yang Dong aims to advance quantum technologies for applications in biomedical imaging, geophysical exploration, and quantum-enhanced navigation.

Research Skills

Yang Dong possesses a comprehensive suite of research skills that span experimental techniques, theoretical modeling, and interdisciplinary collaboration. His primary technical expertise lies in quantum control of solid-state spin systems, particularly nitrogen-vacancy (NV) centers in diamond. He is proficient in optical and microwave instrumentation, including confocal microscopy, laser alignment, and pulse sequence generation for coherent spin manipulation. His skills in cryogenic and room-temperature experimental setups allow him to conduct quantum measurements under diverse environmental conditions. Additionally, Yang Dong has significant experience with magnetic resonance techniques such as optically detected magnetic resonance (ODMR) and electron spin resonance (ESR), which are vital for characterizing spin dynamics and coherence times. On the theoretical side, he applies quantum mechanics, solid-state physics, and numerical simulations to model spin behavior and optimize control strategies. He is also adept in data acquisition, signal processing, and software programming for experimental automation and analysis, using tools such as MATLAB, Python, and LabVIEW. His collaborative skills are evident through his work with interdisciplinary teams, combining insights from physics, engineering, and materials science. These diverse research capabilities enable Yang Dong to address complex scientific challenges and develop innovative solutions in quantum sensing and metrology.

Awards and Honors

Throughout his academic and professional career, Yang Dong has been recognized for his outstanding contributions to quantum science and his dedication to research excellence. While specific awards are not listed, it is evident from his progression from postdoctoral researcher to assistant and then associate researcher at one of China’s leading quantum laboratories that he has earned significant recognition within his field. His work in developing advanced techniques for quantum control and sensing has been published in reputable journals, earning citations and commendations from peers in the scientific community. It is common in such roles for researchers like Yang Dong to receive national or institutional accolades, such as funding from the National Natural Science Foundation of China (NSFC) or honors from the Chinese Academy of Sciences (CAS) for young scientists and early-career researchers. His involvement in high-impact collaborative projects and contributions to the technological advancement of quantum sensing platforms also point to his leadership and innovation. As Yang Dong continues to drive forward the development of quantum technologies, he remains a strong candidate for future distinctions in science and technology, both in China and internationally.

Conclusion

Yang Dong’s journey through the realms of quantum science reflects a seamless integration of academic rigor, professional dedication, and innovative research. From his early academic pursuits in nuclear science to his doctoral specialization in optics and eventual mastery of quantum control, he has demonstrated unwavering commitment to advancing knowledge and developing practical applications in quantum sensing. His work with nitrogen-vacancy centers in diamond places him at the leading edge of quantum metrology, where his contributions continue to shape future technologies. As an Associate Researcher at USTC’s CAS Key Laboratory of Quantum Information, he plays a crucial role in driving forward experimental quantum physics, fostering collaborations, and mentoring young researchers. His ability to balance theory with practice, precision with innovation, and leadership with teamwork, highlights his versatile skill set and enduring impact in the scientific community. With a strong foundation, a clear vision, and an expanding portfolio of achievements, Yang Dong is well-positioned to contribute meaningfully to global advancements in quantum technology. His trajectory promises continued excellence as he explores new frontiers in quantum science and inspires the next generation of researchers in China and beyond.

 Publications Top Notes

  1. Robust optical-levitation-based metrology of nanoparticle’s position and mass
    Authors: Y. Zheng, L.M. Zhou, Y. Dong, C.W. Qiu, X.D. Chen, G.C. Guo, F.W. Sun
    Year: 2020
    Citations: 83

  2. Non-Markovianity-assisted high-fidelity Deutsch–Jozsa algorithm in diamond
    Authors: Y. Dong, Y. Zheng, S. Li, C.C. Li, X.D. Chen, G.C. Guo, F.W. Sun
    Year: 2018
    Citations: 59

  3. Coherent dynamics of multi-spin V center in hexagonal boron nitride
    Authors: W. Liu, V. Ivády, Z.P. Li, Y.Z. Yang, S. Yu, Y. Meng, Z.A. Wang, N.J. Guo, F.F. Yan, 
    Year: 2022
    Citations: 55

  4. Temperature dependent energy gap shifts of single color center in diamond based on modified Varshni equation
    Authors: C.C. Li, M. Gong, X.D. Chen, S. Li, B.W. Zhao, Y. Dong, G.C. Guo, F.W. Sun
    Year: 2017
    Citations: 53

  5. A robust fiber-based quantum thermometer coupled with nitrogen-vacancy centers
    Authors: S.C. Zhang, Y. Dong, B. Du, H.B. Lin, S. Li, W. Zhu, G.Z. Wang, X.D. Chen, 
    Year: 2021
    Citations: 44

  6. Near-infrared-enhanced charge-state conversion for low-power optical nanoscopy with nitrogen-vacancy centers in diamond
    Authors: X.D. Chen, S. Li, A. Shen, Y. Dong, C.H. Dong, G.C. Guo, F.W. Sun
    Year: 2017
    Citations: 35

  7. Quantum imaging of the reconfigurable VO₂ synaptic electronics for neuromorphic computing
    Authors: C. Feng, B.W. Li, Y. Dong, X.D. Chen, Y. Zheng, Z.H. Wang, H.B. Lin, W. Jiang, 
    Year: 2023
    Citations: 28

  8. Focusing the electromagnetic field to 10⁻⁶λ for ultra-high enhancement of field-matter interaction
    Authors: X.D. Chen, E.H. Wang, L.K. Shan, C. Feng, Y. Zheng, Y. Dong, G.C. Guo, 
    Year: 2021
    Citations: 28

  9. Quantum enhanced radio detection and ranging with solid spins
    Authors: X.D. Chen, E.H. Wang, L.K. Shan, S.C. Zhang, C. Feng, Y. Zheng, Y. Dong, 
    Year: 2023
    Citations: 27

  10. Experimental implementation of universal holonomic quantum computation on solid-state spins with optimal control
    Authors: Y. Dong, S.C. Zhang, Y. Zheng, H.B. Lin, L.K. Shan, X.D. Chen, W. Zhu, 
    Year: 2021
    Citations: 26

  11. Thermal-demagnetization-enhanced hybrid fiber-based thermometer coupled with nitrogen-vacancy centers
    Authors: S.C. Zhang, S. Li, B. Du, Y. Dong, Y. Zheng, H.B. Lin, B.W. Zhao, W. Zhu, 
    Year: 2019
    Citations: 26

  12. Super resolution multifunctional sensing with the nitrogen-vacancy center in diamond
    Authors: X.D. Chen, D.F. Li, Y. Zheng, S. Li, B. Du, Y. Dong, C.H. Dong, G.C. Guo, F.W. Sun
    Year: 2019
    Citations: 25

  13. High-sensitivity and wide-bandwidth fiber-coupled diamond magnetometer with surface coating
    Authors: S.C. Zhang, H.B. Lin, Y. Dong, B. Du, X.D. Gao, C. Yu, Z.H. Feng, X.D. Chen, 
    Year: 2022
    Citations: 20

  14. Fast high-fidelity geometric quantum control with quantum brachistochrones
    Authors: Y. Dong, C. Feng, Y. Zheng, X.D. Chen, G.C. Guo, F.W. Sun
    Year: 2021
    Citations: 20

  15. Reviving the precision of multiple entangled probes in an open system by simple π-pulse sequences
    Authors: Y. Dong, X.D. Chen, G.C. Guo, F.W. Sun
    Year: 2016
    Citations: 17

  16. A bright single-photon source from nitrogen-vacancy centers in diamond nanowires
    Authors: S. Li, C.H. Li, B.W. Zhao, Y. Dong, C.C. Li, X.D. Chen, Y.S. Ge, F.W. Sun
    Year: 2017
    Citations: 15

  17. Enhancing the sensitivity of a single electron spin sensor by multi-frequency control
    Authors: C.H. Li, Y. Dong, J.Y. Xu, D.F. Li, X.D. Chen, A.M. Du, Y.S. Ge, G.C. Guo, F.W. Sun
    Year: 2018
    Citations: 14

  18. Optical far-field super-resolution microscopy using nitrogen vacancy center ensemble in bulk diamond
    Authors: S. Li, X. Chen, B.W. Zhao, Y. Dong, C.W. Zou, G.C. Guo, F.W. Sun
    Year: 2016
    Citations: 13

  19. Robust scalable architecture for a hybrid spin-mechanical quantum entanglement system
    Authors: Y. Dong, X.D. Chen, G.C. Guo, F.W. Sun
    Year: 2019
    Citations: 12

  20. Composite-pulse enhanced room-temperature diamond magnetometry
    Authors: Y. Dong, J.Y. Xu, S.C. Zhang, Y. Zheng, X.D. Chen, W. Zhu, G.Z. Wang, G.C. Guo,
    Year: 2022
    Citations: 10

 

Kyuwook Ihm | Emerging Technologies | Best Researcher Award

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Dr. Kyuwook Ihm | Emerging Technologies | Best Researcher Award

Principal scientist at Pohang accelerator laboratory, South Korea 

Dr. Kyuwook Ihm is a prominent beamline scientist at the Pohang Accelerator Laboratory (PAL), where he leads the 4D Photoemission Spectroscopy (PES) beamline. His expertise lies in experimental condensed matter physics, with a specialized focus on low-dimensional materials, topological matter, and strongly correlated systems. Throughout his career, Dr. Ihm has consistently pushed the frontiers of soft X-ray spectroscopy and surface science through extensive work with PES, NEXAFS, XES, RIXS, and PEEM. He plays a vital role in the development of optical systems for soft X-ray beamlines and has also contributed significantly to beamline-related software engineering. Beyond his research at PAL, Dr. Ihm serves as an adjunct professor in the Physics Department at the University of Ulsan, further emphasizing his dedication to education and mentorship. He has actively contributed to various scientific communities through leadership roles, such as vice-president of the Korean Vacuum Society’s Surface and Interface Division and representative of the IUVSTA’s Surface Engineering Division. With his academic, technical, and organizational contributions, Dr. Ihm stands out as a multidisciplinary scientist whose research has been extensively published in top-tier journals. His efforts continue to enhance understanding in materials science and experimental physics on both national and international stages.

Professional Profiles

Education

Dr. Kyuwook Ihm received his Ph.D. in Physics from Pohang University of Science and Technology (POSTECH) in 2009, specializing in experimental condensed matter physics. His doctoral research, conducted under the mentorship of Professor Sukmin Chung, focused on the adsorption characteristics and thermodynamic behaviors of molecules with sp² hybrid orbitals on inorganic surfaces. This work laid a strong foundation for his future contributions to surface physics and spectroscopy. Prior to his doctoral studies, Dr. Ihm completed both his B.S. and M.S. degrees in Physics at Sung Kyun Kwan University in 2000, where he cultivated his early interest in surface science and material interactions. His academic journey reflects a deep and sustained engagement with complex physical systems and materials behavior at the atomic and molecular scale. These formative years equipped Dr. Ihm with the theoretical insight and experimental rigor needed to pursue a successful career in both academic and applied research. His educational background has not only shaped his research focus but also prepared him to contribute significantly to the scientific community, including his current role as a mentor and educator. The strong academic lineage and interdisciplinary training continue to inform his innovative work in spectroscopy and material science.

Professional Experience

Dr. Kyuwook Ihm has cultivated an illustrious career that spans over two decades, centered at the forefront of experimental condensed matter physics. Since 2001, he has served as the chief scientist at the 4D PES beamline of the Pohang Accelerator Laboratory, where he is responsible for overseeing beamline design, experimental implementation, and user support. In parallel, he has held an adjunct professorship at the University of Ulsan since 2021, further showcasing his commitment to education and research mentorship. Dr. Ihm’s professional leadership extends beyond the laboratory; he has been vice-president of the Surface and Interface Division of the Korean Vacuum Society since 2020 and a representative of the Surface Engineering Division of the International Union for Vacuum Science, Technique and Applications (IUVSTA) since 2022. His influence also reaches national scientific policy, as a member of PAL’s Planning Committee and an evaluator for Korea’s Ministry of SMEs and Startups. He has collaborated globally, serving as a visiting scholar at the Advanced Light Source (LBNL) from 2016–2017 and as a visiting scientist at Elettra in Italy in 2003. Earlier in his career, he worked on transistor simulations at Samsung Electronics, gaining valuable industrial experience that complements his academic pursuits.

Research Interest

Dr. Ihm’s research interests span a rich tapestry of scientific themes at the intersection of physics, chemistry, and engineering. He is deeply invested in understanding the physics and chemistry of condensed matter, with a specific emphasis on low-dimensional materials, topological matter, and strongly correlated systems. His curiosity extends into the transport properties of charge carriers, especially within organic functional materials where quantum chemical effects significantly influence performance. Dr. Ihm is particularly fascinated by how molecular and electronic structures affect material behavior under different conditions. On the experimental front, he specializes in soft X-ray spectroscopy techniques such as Photoemission Spectroscopy (PES), Near-Edge X-ray Absorption Fine Structure (NEXAFS), X-ray Emission Spectroscopy (XES), and Resonant Inelastic X-ray Scattering (RIXS). Additionally, he works extensively with Photoemission Electron Microscopy (PEEM) to investigate surface properties at high spatial resolution. His beamline development efforts at PAL underscore his interest in advancing optics for soft X-ray applications, as well as in engineering custom software for experimental data analysis and control. Altogether, Dr. Ihm’s interdisciplinary approach integrates fundamental theory with practical experimentation, bridging the gap between materials science and applied physics to generate new knowledge and technological innovation.

Research Skills

Dr. Kyuwook Ihm possesses an extensive skill set rooted in experimental condensed matter physics, with expertise that encompasses both foundational theory and sophisticated laboratory techniques. A cornerstone of his capabilities lies in soft X-ray spectroscopy, where he expertly applies methods such as PES, NEXAFS, XES, and RIXS to explore electronic and chemical structures of materials. His proficiency with Photoemission Electron Microscopy (PEEM) allows him to obtain spatially resolved surface data, adding further depth to his material investigations. Beyond experimental execution, Dr. Ihm is an accomplished optics designer, particularly for soft X-ray beamline systems, where he integrates precision engineering with theoretical modeling. His experience includes the conceptualization and realization of high-performance beamlines, such as the 4D PES beamline at PAL. He also demonstrates robust software development skills, focusing on control systems and data processing tools tailored for beamline experiments. These software tools enhance experimental reproducibility and accuracy, a testament to his attention to detail and innovative thinking. Dr. Ihm’s interdisciplinary training allows him to collaborate seamlessly with chemists, engineers, and theorists, making him a pivotal contributor to complex research teams. His ability to connect experimental insights with real-world applications defines him as a versatile and forward-thinking scientist.

Awards and Honors

Over the course of his distinguished career, Dr. Kyuwook Ihm has been honored with numerous accolades and professional appointments that reflect his outstanding contributions to science and technology. He has been a fellow of both the Korean Physical Society and the Korean Vacuum Society since 2015, affirming his standing as a leading expert in his field. As vice-president of the Surface and Interface Division of the Korean Vacuum Society, he plays a central role in guiding national research agendas related to surface science. His recognition on the international stage is highlighted by his role as the representative of the Surface Engineering Division within IUVSTA, where he contributes to shaping global strategies in vacuum and surface technologies. Dr. Ihm’s strategic influence extends to institutional leadership, as evidenced by his appointment to the Planning Committee of the Pohang Accelerator Laboratory, where he has served since 2018. His evaluative expertise is also called upon by Korea’s Ministry of SMEs and Startups, where he has helped assess research proposals since 2015. These prestigious appointments and honors not only celebrate his individual excellence but also illustrate the broad impact of his work across academic, governmental, and international scientific domains.

Conclusion

Dr. Kyuwook Ihm’s career is a compelling example of how deep scientific inquiry, technical mastery, and interdisciplinary collaboration can converge to produce meaningful advancements in experimental physics and materials science. From his early academic work in surface physics to his current leadership at the 4D PES beamline at PAL, he has consistently demonstrated a commitment to pushing the boundaries of what is experimentally possible. His expertise in soft X-ray spectroscopy and photoemission methods has contributed valuable insights into the electronic and structural properties of novel materials, with applications spanning energy storage, catalysis, and semiconductor technology. Beyond research, Dr. Ihm is a dedicated mentor, educator, and scientific leader, influencing both policy and practice within Korea’s scientific community and beyond. His dual engagement in academic and industrial settings equips him with a rare versatility, making him an effective collaborator across sectors. Through roles in international scientific organizations and national evaluation committees, he actively shapes the future of experimental science and technological innovation. As he continues to contribute cutting-edge research and guide the development of next-generation beamline infrastructure, Dr. Ihm remains a vital force in advancing the frontiers of materials science and applied physics.

 Publications Top Notes

1. Theoretical and Experimental Optimization of P2-Type Sodium-Ion Battery Cathodes via Li, Mg, and Ni Co-Doping: A Path to Enhanced Capacity and Stability

  • Authors: M. Cho, N. Yaqoob, J. Yu, … P. Kaghazchi, S.-T. Myung

  • Year: 2025

  • Citations: 3

2. Interfacial contact-driven enhanced environmental photocatalysis of CdS-loaded OH-functionalized carbon nanotubes with low biotoxicity

  • Authors: H. Ju, D. T.H. Hoang, W.-S. Jang, … Y.-M. Kim, H. Lee

  • Year: 2025

3. Enhancing structural flexibility in P2-type Ni-Mn-based Na-layered cathodes for high power-capability and fast charging/discharging performance

  • Authors: B. Ku, J. Ahn, H. Lee, … J. Yoo, J. Kim

  • Year: 2025

4. Correction to: Impact of Transition Metal Layer Vacancy on the Structure and Performance of P2 Type Layered Sodium Cathode Material

  • Authors: O.Y. Zhanadilov, S. Baiju, N.V. Voronina, … P. Kaghazchi, S.-T. Myung

  • Year: 2024

5. Impact of Transition Metal Layer Vacancy on the Structure and Performance of P2 Type Layered Sodium Cathode Material

  • Authors: O.Y. Zhanadilov, S. Baiju, N.V. Voronina, … P. Kaghazchi, S.-T. Myung

  • Year: 2024

  • Citations: 5

6. Origin of Oxidation Variations in Ambient-Stable β-InSe

  • Authors: E. Sim, D. Kim, T.H. Nguyen, … S. Lim, K. Ihm

  • Year: 2024

7. Multi-Purpose Improvements in Catalytic Activity for Li-Ion Deposited TiO2, SnO2, and CeO2 Nanoparticles through Oxygen-Vacancy Control

  • Authors: D.T. Hoang, D. Lim, M.J. Kang, … H.S. Ahn, H. Lee

  • Year: 2024

  • Citations: 2

8. Migration of Mg in Na-O-Mg Configuration for Oxygen Redox of Sodium Cathode

  • Authors: J. Yu, N.V. Voronina, N. Yaqoob, … P. Kaghazchi, S.-T. Myung

  • Year: 2024

  • Citations: 9

9. Achieving volatile potassium promoted ammonia synthesis via mechanochemistry

  • Authors: J. Kim, T. Dai, M. Yang, … Q. Jiang, J.-B. Baek

  • Year: 2023

  • Citations: 18