Hao Li | Quantum Technologies | Best Researcher Award

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Prof. Hao Li | Quantum Technologies | Best Researcher Award

Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences (SIMIT, CAS) | China

Professor Hao Li is a Professor at the Shanghai Institute of Microsystem and Information Technology (SIMIT) under the Chinese Academy of Sciences (CAS). With a long-standing commitment to research in superconducting single-photon detection technology, he has made remarkable contributions to the fields of quantum information technology and weak light detection. Professor Li’s work has set new benchmarks in high-efficiency superconducting single-photon detectors (SSPDs), pushing the boundaries of quantum technologies and influencing scientific advancements globally.

👨‍🎓Profile

Early Academic Pursuits 🎓

Professor Li’s academic journey began with a deep interest in photonics and quantum technologies. Early on, he focused on understanding the fundamental challenges in photon detection. Through years of rigorous study, he honed his expertise in superconductivity and its application to optical sciences. His initial academic pursuits laid the foundation for his later work in superconducting detectors.

Professional Endeavors 💼

Throughout his career, Professor Li has worked closely with various renowned institutions, including Tsinghua University and the University of Science and Technology of China. These collaborations have allowed him to advance his research in fiber-optic quantum key distribution and photonic quantum computing. His professional endeavors have positioned him as a global leader in the field of quantum detection technologies.

Contributions and Research Focus 🔬

Professor Li’s key research focus is on the development of superconducting single-photon detectors (SSPDs), which are integral for advancing quantum communication, quantum computing, and high-precision light detection. His efforts in optimizing optical absorption and photon response in SSPDs have led to the development of near-unity efficiency detectors, solving complex challenges in photon detection. This has paved the way for applications in quantum information technology and weak light detection.

Impact and Influence 🌍

Professor Li’s research has had a profound global impact. His achievements in developing high-efficiency SSPDs have set new standards in quantum key distribution and quantum computing, rewriting world records multiple times. In addition, his contributions have enhanced China’s influence in the international quantum research community and brought about significant social benefits. His work continues to inspire scientists and engineers around the world.

Academic Citations 📚

Professor Li’s work has been widely recognized and cited in prominent journals and conferences. His innovative research in photon detection technology has been acknowledged by organizations such as the Optical Society of America (OSA). The recognition he received in 2020 for his high-efficiency SSPDs exemplifies the academic impact of his work, making him one of the most cited researchers in the field.

Research Skills 🧠

Professor Li possesses a strong command of several key research skills essential to his work, including:

  • Superconductivity and photonics
  • Quantum technology applications
  • Device optimization for high-efficiency photon detection
  • Collaboration with international institutions in advanced fields such as quantum computing His methodical approach to solving multi-dimensional challenges in photon detection technology has played a significant role in his success.

Awards and Honors 🏅

Professor Li has received several prestigious awards, including:

  • Recognition by the Optical Society of America (OSA) in 2020 for his high-efficiency superconducting single-photon detectors.
  • Multiple international accolades for his role in advancing quantum key distribution and quantum computing. These honors highlight his outstanding contributions to the field of quantum technologies and photon detection.

Legacy and Future Contributions 🌱

Professor Li’s legacy is already evident in his groundbreaking work on superconducting single-photon detectors, which have revolutionized quantum detection technologies. Moving forward, his work will likely continue to shape the evolution of quantum computing, communication systems, and weak light detection. His ongoing research promises to drive further advancements in the scalability and integration of quantum systems into practical, real-world applications, cementing his status as a visionary in the field.

Publications Top Notes

Impact of Distributed Bragg Reflectors on the Intrinsic Detection Efficiency of Superconducting Nanowire Single-Photon Detectors

  • Authors: Hongxin Xu, Hailong Han, You Xiao, Jiamin Xiong, Chaomeng Ding, Zhiyun Shu, Yuchi Li, Xiaoyu Liu, Lixing You, Zhen Wang, Hao Li
    Journal: Superconductivity
    Year: 2025

High Performance Superconducting Nanowire Single Photon Detectors for QKD Applications

  • Authors: C. Bruscino, P. Ercolano, D. Salvoni, M. Di Giancamillo, C. Zhang, M. Ejrnaes, H. Li, L. You, L. Parlato, M. Martinelli, et al.
    Journal: IEEE Transactions on Applied Superconductivity
    Year: 2024

Reduction of g²(0) Value in Heralded Spontaneous Parametric Down-Conversion Sources Using Photon Number Resolving Detectors

  • Authors: C. Bruscino, M. Ejrnaes, P. Ercolano, D. Salvoni, C. Zhang, Li, H., You, L., Parlato, L., Pepe, G.P.
    Journal: Low Temperature Physics
    Year: 2024

Single-Shot Readout of a Nuclear Spin in Silicon Carbide

  • Authors: Lai, X.-Y., Fang, R.-Z., Li, T., Su, R.-Z., Huang, J., Li, H., You, L.-X., Bao, X.-H., Pan, J.-W.
    Journal: arXiv
    Year: 2024

Superconducting PNR Detector for Photon Sources Characterization

  • Authors: Pasquale Ercolano, Daniela Salvoni, Ciro Bruscino, Matteo Di Giancamillo, Chengjun Zhang, Mikkel Ejrnaes, Jia Huang, Hao Li, Lixing You, Loredana Parlato, et al.
    Journal: IEEE Transactions on Applied Superconductivity
    Year: 2024

Sudip Kumar Haldar | Quantum Technologies | Best Faculty Award

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Dr. Sudip Kumar Haldar | Quantum Technologies | Best Faculty Award

Jaypee Institute of Information Technology | India

Dr. Sudip Kumar Haldar is an accomplished Assistant Professor in the Department of Physics and Material Science & Engineering at Jaypee Institute of Information Technology, Noida. With an extensive academic and research career, Dr. Haldar specializes in Theoretical Condensed Matter Physics, focusing on quantum gases and quantum information theory (QIC). He has contributed significantly to the field, with research spanning multiple prestigious institutions, including a post-doctoral stint at the University of Haifa, Israel, and the Physical Research Laboratory, India. His diverse roles have influenced various subfields of physics, particularly many-body dynamics and quantum technologies.

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Early Academic Pursuits 📚

Dr. Haldar’s academic journey began with his early education in Kolkata, India, where he excelled in science subjects. He completed his B.Sc. (Hons.) in Physics from Calcutta University in 2006, securing First Class results. He further pursued M.Sc. in Physics from the same institution in 2008, followed by success in prestigious exams like GATE (2009) and the CSIR-JRF (2009). Dr. Haldar’s academic excellence culminated in his Ph.D. from Calcutta University in 2015, where his research focused on the stability of Bose-Einstein condensates in finite optical traps.

Professional Endeavors 🌏

Dr. Haldar has worked in prestigious institutions worldwide. He was a Post-doctoral Research Assistant at the University of Haifa, Israel (2016-2019), where he studied many-body dynamics and excitation spectra in trapped ultra-cold atomic gases. He also worked at the Physical Research Laboratory (ISRO) in Ahmedabad (2014-2016), exploring thermalization dynamics in quantum systems using embedded random matrix theory. In his current position at Jaypee Institute of Information Technology, Dr. Haldar continues to push the frontiers of quantum technologies and quantum information science.

Contributions and Research Focus 🔬

Dr. Haldar’s research interests primarily revolve around Theoretical Condensed Matter Physics and Quantum Information Science (QIC). His work explores the dynamics of quantum gases, the interaction effects in ultracold bosonic systems, and the role of entanglement in quantum phase transitions. He is currently investigating quantum technologies for next-generation quantum computing. His notable publications include a paper on topological quantum phase transitions and significant contributions to the study of bosonic Josephson junctions and finite-range interactions.

Research Skills 🧠

Dr. Haldar possesses an advanced skill set in computational physics, with proficiency in LaTeX, Fortran95, C++, and HPC systems. His research often involves the use of high-performance computing (HPC) to simulate and analyze complex quantum dynamics. He regularly employs advanced computational techniques and methods such as Multiconfigurational Time-Dependent Hartree (MCTDH) for quantum simulations, contributing significantly to his field’s computational modeling advancements.

Teaching Experience 🎓

As an Assistant Professor, Dr. Haldar has taught various courses in Physics and Material Science. He has also been actively involved in conducting workshops and training sessions for students and faculty. Notably, he was a resource person for the One Week Workshop on Scientific & Technical Research Scripting Using LaTeX at SRM University in 2023. His teaching pedagogy emphasizes outcome-based education, incorporating interactive learning to inspire students in the fundamentals of theoretical physics.

Awards and Honors 🏆

Dr. Haldar’s excellence in research and academia has been recognized through various awards and fellowships. He received the CSIR Junior Research Fellowship (2010) based on his performance in the UGC-CSIR NET exam. He has been a Life Member of the Indian Society of Atomic & Molecular Physics (ISAMP). His post-doctoral fellowships include prestigious positions such as the Institute Post-Doctoral Fellowship from the University of Haifa and the BK21 Plus Postdoctoral Fellowship under the Brain Korea 21 Program.

Citations📚

A total of 165 citations for his publications, demonstrating the impact and recognition of his research within the academic community.

  • Citations –  165
  • h-index   –      8
  • i10-index –     7

Legacy and Future Contributions 🌱

Dr. Haldar’s work continues to inspire students and fellow researchers in the fields of quantum physics and condensed matter theory. His research on quantum dynamics, BECs, and quantum phase transitions has the potential to contribute significantly to the development of quantum computing technologies. With ongoing projects like the DST SERB funded project on quantum technologies, Dr. Haldar is at the forefront of the future of quantum science in India and globally. His legacy will likely be marked by his pivotal role in advancing quantum systems and theoretical physics.

Publications Top Notes

Many-Body Effects in a Composite Bosonic Josephson Junction

  • Authors: Sudip Kumar Haldar, Anal Bhowmik
    Journal: Atoms, 2024

Predicting a Topological Quantum Phase Transition from Dynamics via Multisite Entanglement

  • Authors: Leela Ganesh Chandra Lakkaraju, Sudip Kumar Haldar, Aditi Sen (De)
    Journal: Physical Review A, 2024

Impact of the Transverse Direction on the Many-Body Tunneling Dynamics in a Two-Dimensional Bosonic Josephson Junction

  • Authors: Anal Bhowmik, Sudip Kumar Haldar, Ofir E. Alon
    Journal: Scientific Reports, 2020

Relaxation of Shannon Entropy for Trapped Interacting Bosons with Dipolar Interactions

  • Authors: Sangita Bera, Sudip Kumar Haldar, Barnali Chakrabarti, Andrea Trombettoni, V. K. B. Kota
    Journal: The European Physical Journal D, 2020

Many-Body Quantum Dynamics of an Asymmetric Bosonic Josephson Junction

  • Authors: Sudip Kumar Haldar, Ofir E. Alon
    Journal: New Journal of Physics, 2019

 

 

Basudev Nag Chowdhury | Quantum Technologies | Best Researcher Award

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Dr. Basudev Nag Chowdhury | Quantum Technologies | Best Researcher Award

QSciT Research | India

Dr. Basudev Nag Chowdhury, an accomplished scientist and researcher, is currently the Head of Research & Innovation at QSciT Research Pvt. Ltd., Kolkata, India. He is also a Senior Research Consultant with the Nano Bio-Photonics Group at the Department of Electronics & Electrical Communication Engineering, IIT Kharagpur. With a strong background in Quantum Physics and Nanotechnology, Dr. Chowdhury has made notable contributions in areas such as quantum computing, quantum-enhanced sensing, and neuromorphic computing. His research combines both theoretical and experimental approaches to explore and manipulate quantum phenomena for practical applications.

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Early Academic Pursuits 🎓

Dr. Chowdhury’s academic journey began with a B.Sc. in Physics (Hons.) from Presidency College, University of Calcutta in 2006, followed by a M.Sc. in Physics from the Department of Physics, University of Calcutta in 2008. His passion for the frontier of nanotechnology led him to pursue a PhD at the Centre for Research in Nanoscience and Nanotechnology (CRNN), University of Calcutta, where he made significant contributions to transport behavior modeling in nanowires. His doctoral thesis was focused on Silicon Nanowire Field Effect Transistors (Si NWFETs), which has been highly influential in the field of nanoelectronics.

Professional Endeavors 🚀

Dr. Chowdhury has held several prestigious research positions over the years. From being a Project Fellow to a Post-Doctoral Research Associate at the University of Calcutta, his career trajectory shows consistent growth in both teaching and research. His tenure at IIT Kharagpur and University of Calcutta as a Visiting Researcher is marked by impactful contributions to quantum physics, nanotechnology, and neuromorphic computing. Notably, Dr. Chowdhury’s involvement in the Nano Bio-Photonics Group at IIT Kharagpur reflects his expanding role in integrating quantum technology with biological sciences.

Contributions and Research Focus 🔬

Dr. Chowdhury’s research focus lies primarily in quantum computing, quantum sensing, and nanotechnology. He is particularly interested in developing CMOS-compatible room-temperature qubits, manipulating quantum entanglement using voltage control, and quantum solar cells. His work on voltage-tunable quantum dots (VTQDs), quantum-enhanced biosensors, and exceptional point physics has been groundbreaking. Furthermore, Dr. Chowdhury is advancing the understanding of neuromorphic computing and brain-inspired physics using Non-equilibrium Green’s Function (NEGF) techniques.

Research Skills 🛠️

Dr. Chowdhury possesses a wide range of research skills, including theoretical modeling, experimental fabrication, and quantum device simulation. His expertise in the NEGF framework has facilitated the development of quantum simulators for various nanoelectronic applications. His work on quantum dots, nano-wire transistors, and nano-scale materials has provided insights into quantum transport and energy harvesting. His skillset also extends to quantum-enhanced sensing, bio-sensing, and strain-engineering of materials.

Teaching Experience 🍎

Dr. Chowdhury has contributed significantly to the education and mentoring of students in the fields of Quantum Mechanics, Nanotechnology, and Nanoscience. At IIT Kharagpur, he serves as a Senior Research Consultant, where he not only leads advanced research projects but also helps train the next generation of scientists and engineers in quantum physics and nanoelectronics. His ability to bridge the gap between theory and application makes him a highly respected figure in both teaching and research.

Awards and Honors 🏅

Dr. Chowdhury’s dedication and expertise have been recognized with several awards, including being named an IOP Trusted Reviewer (2022). His extensive contributions to quantum technology and nanoelectronics continue to earn him recognition within the scientific community.

Legacy and Future Contributions 🔮

Dr. Chowdhury is poised to continue making groundbreaking contributions in the fields of quantum technology, neuroscience-inspired computing, and nanoelectronics. His focus on quantum-based biosensors and exceptional-point-enhanced sensing could revolutionize healthcare diagnostics and environmental sensing. As he prepares to submit his monograph in 2025, Dr. Chowdhury’s legacy in the field of quantum physics will likely inspire future generations of researchers.

Citations📚

A total of 244 citations for his publications, demonstrating the impact and recognition of his research within the academic community.

  • Citations – 244
  • h-index   –    10
  • i10-index –    11

Publications Top Notes

Exceptional-Point-Enhanced Superior Sensing Using Asymmetric Coupled-Lossy-Resonator Based Optical Metasurface

  • Authors: Nag Chowdhury, B., Lahiri, P., Johnson, N.P., De La Rue, R.M., Lahiri, B.
    Journal: Laser and Photonics Reviews

Nonequilibrium VLS-grown stable ST12-Ge thin film on Si substrate: a study on strain-induced band engineering

  • Authors: Mandal, S., Nag Chowdhury, B., Tiwari, A., Banerjee, A., Chattopadhyay, S.
    Journal: Journal of Materials Science

Dual-Gate GaAs-Nanowire FET for Room Temperature Charge-Qubit Operation: A NEGF Approach

  • Authors: Nag Chowdhury, B., Chattopadhyay, S.
    Journal: Advanced Quantum Technologies

Development of substrate engineered Si-<111>/[100] Patterned Features by anisotropic wet etching with Pt/Pt3Si mask

  • Authors: Mandal, S., Das, C., Sikdar, S., Karmakar, A., Chattopadhyay, S.
    Journal: Materials Chemistry and Physics

Voltage-Tunable Quantum-Dot Array by Patterned Ge-Nanowire-Based Metal-Oxide-Semiconductor Devices

  • Authors: Sikdar, S., Nag Chowdhury, B., Saha, R., Chattopadhyay, S.
    Journal: Physical Review Applied

 

 

 

Ni Liu | Quantum Technologies | Best Extension Activity Award

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Mrs. Ni Liu | Quantum Technologies | Best Extension Activity Award

Teacher at Shanxi University, China

Ni Liu, a 34-year-old female academic from Shanxi, China, is an Associate Professor at the Institute of Theoretical Physics of Shanxi University. With a PhD in Theoretical Physics from Shanxi University, her research primarily focuses on quantum optics, quantum computing, and condensed matter physics, especially in systems involving ultracold atoms and high-finesse optical cavities. Ni Liu has been involved in a range of pioneering theoretical and experimental work, contributing significantly to our understanding of quantum phase transitions and atom-photon interactions.

👨‍🎓 Profile

📚 Early Academic Pursuits

Ni Liu completed her BS in Physics at Taiyuan Normal University in 2008 and later earned her PhD in Theoretical Physics from the Institute of Theoretical Physics of Shanxi University (2008-2013). Her doctoral research, under the mentorship of Prof. Jiuqing Liang and Prof. Gang Chen, involved significant contributions to Dicke quantum phase transitions in open systems and the self-organization of Bose-Einstein condensates (BEC), laying the foundation for her future work in quantum optics.

🏫 Professional Endeavors

Ni Liu has been a prominent academic at Shanxi University since 2013. She began as a lecturer at the School of Physical and Electronic Engineering and later advanced to the role of Associate Professor at the Institute of Theoretical Physics. Over the years, she has gained significant recognition in both national and international academic communities for her theoretical work and contributions to quantum physics.

🔬 Contributions and Research Focus

Ni Liu’s research primarily revolves around the interaction between ultracold atoms and high-finesse optical cavities, exploring systems that bridge quantum optics and condensed matter physics. Her work in Dicke quantum phase transitions and nonlinear atom-photon interactions has broadened the understanding of quantum phase transitions, including in BEC-cavity systems. Liu has contributed to the theory behind Bose-Einstein condensates (BEC) in optomechanical cavities, where she has proposed novel quantum phase transitions and multi-component BEC systems.

💼 Research Grants & Funding

Ni Liu has been the principal investigator on several significant grants:

  • National Natural Science Foundation of China (2014-2017)
  • Scientific and Technological Innovation Programs of Higher Education Institutions in Shanxi Province (2014-2016)
  • Natural Science Foundation of Shanxi Province (2017-2019) Additionally, she has been a key participant in several other collaborative projects, contributing to the advancement of experimental and theoretical quantum physics.

🌍 Collaborations and Partnerships

Ni Liu’s research has fostered collaborations with both national and international researchers. Her contributions to quantum optics and condensed matter physics have involved joint efforts with leading universities and research institutions in China and beyond. Her work is at the intersection of experimental physics and theoretical quantum mechanics, fostering collaboration between these disciplines.

Top Noted Publications

 

 

Aniket Nag | Quantum Technologies | Best Researcher Award

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Mr. Aniket Nag | Quantum Technologies | Best Researcher Award

Ph D Scholar at Indian Institute of Technology, Kanpur in India

Aniket Nag is an emerging physicist with a focus on quantum information and atomic-molecular physics. He completed his M.Sc. in Physics from the National Institute of Technology (NIT) Durgapur, achieving a commendable CGPA of 8.94. Aniket’s research interests lie in understanding complex physical phenomena, including the effects of the generalized uncertainty principle. He has actively participated in academic discussions on econophysics and sociophysics and contributed to seminars and science exhibitions. His academic journey reflects both excellence and curiosity, with multiple publications in renowned journals such as the Ukrainian Journal of Physics and Canadian Journal of Physics. With a solid background in computational tools like Fortran and Matlab, Aniket aims to advance his research career while contributing to the broader field of physics.

Profile:

Education:

Aniket Nag completed his M.Sc. in Physics from the National Institute of Technology, Durgapur, West Bengal, in 2022, with a CGPA of 8.94. Prior to that, he obtained his B.Sc. in Physics from Serampore College under the University of Calcutta, graduating in 2020 with 74.37%. During his undergraduate studies, he focused on Physics as his major, with Chemistry and Mathematics as general subjects. He had a strong academic performance during his Higher Secondary (10+2) education at Dainhat High School, securing 87.2% with Physics, Chemistry, Mathematics, and Biological Science as his core subjects. Aniket demonstrated academic excellence from an early age, achieving an impressive 87.75% during his Secondary School (10th) education in 2015. His education laid a strong foundation for his future research interests in quantum information and atomic-molecular physics.

Professional experience:

Aniket Nag’s academic experience extends beyond traditional coursework. In 2019, he participated in a discussion on Econo physics and Socio physics led by Dr. Bikas Kanta Chakrabarti, an Emeritus Professor at Saha Institute of Nuclear Physics (SINP). Additionally, Aniket demonstrated hands-on expertise during the Annual Science Exhibition at Serampore College in 2019, where he successfully created and showcased a Tesla Coil project. His model explained the principles behind wireless power transmission. He also took part in a science show on LIGO and Gravitational Waves organized by the Promote Science team in 2017. Aniket’s academic journey highlights his practical engagement with physics concepts and his passion for exploring innovative solutions. He has also presented research at conferences, including a seminar on the “Generalized Uncertainty Principle and Delta-function potential well” at an UG Symposium organized by Presidency University in 2021.

Research focus:

Aniket Nag’s research is centered around quantum information and atomic-molecular physics, with a particular emphasis on the generalized uncertainty principle. His work explores the fundamental principles that govern quantum systems, contributing to the understanding of how these concepts apply to both theoretical and practical physics. Aniket’s interest in this area has led to multiple publications, including papers on the impact of the generalized uncertainty principle on anharmonic oscillators. His focus also extends to computational physics, where he employs tools like Fortran and Matlab to simulate and analyze complex systems. Aniket’s commitment to advancing the field of quantum physics is further demonstrated by his participation in discussions, seminars, and exhibitions related to cutting-edge topics such as LIGO and gravitational waves. His research aims to push the boundaries of knowledge in quantum information theory and its applications.

Publication Top Notes:

  • Paramanik, S., Nag, A., and Sahoo, S. Generalized uncertainty principle and delta-function potential, Ukrainian Journal of Physics, 67(8), pp.568-568 (2022)
  • Nag, A., and Sahoo, S. Effect of generalized uncertainty principle on anharmonic oscillator, Canadian Journal of Physics, 101(8), pp.373-377 (2023)

Conclusion:

Aniket Nag has laid a strong foundation for a promising career in research, particularly in the areas of quantum mechanics and uncertainty principles. His academic excellence, early research contributions, and technical skills make him a strong candidate for the Best Researcher Award. With a continued focus on broadening his research impact and gaining international exposure, he is poised to become a leading researcher in his field.