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

Shri Krishna | High energy physics | Best Researcher Award

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Dr. Shri Krishna | High energy physics | Best Researcher Award

Assistant Professor at Zakir Husain Delhi College, University of Delhi, India

Dr. Shri Krishna is a distinguished researcher and academic in theoretical high-energy physics, currently serving as an Assistant Professor at Zakir Husain Delhi College, University of Delhi. He earned his Ph.D. in Theoretical High Energy Physics from Banaras Hindu University (BHU) in 2015 under the supervision of Prof. R.P. Malik. His research centers on supersymmetric quantum mechanics and BRST symmetry within the framework of higher p-form gauge theories. Dr. Krishna’s academic journey also includes post-doctoral research at the Indian Institute of Science Education and Research (IISER) Mohali, where he worked with Prof. C.S. Aulakh. With numerous scientific publications in reputable journals, his work has significantly contributed to advancing the understanding of gauge theories and quantum mechanics. He has presented his research at national and international conferences, enhancing his recognition in the scientific community.

Profile:

Education:

Dr. Shri Krishna holds a Ph.D. in Theoretical High Energy Physics from Banaras Hindu University (BHU), Varanasi, completed in 2015. His doctoral research, supervised by Prof. R.P. Malik, focused on investigating (Non-)Abelian p-form gauge theories and supersymmetric quantum mechanics. Before his Ph.D., Dr. Krishna pursued an M.Phil. in Physics at Chhatrapati Shahu Ji Maharaj University (CSJMU), Kanpur, in 2009, where he gained a strong foundation in advanced physics concepts. He also earned his M.Sc. in Physics from CSJMU in 2006, further refining his understanding of theoretical and experimental physics. Dr. Krishna’s undergraduate studies, completed in 2002 at CSJMU, focused on Physics, Mathematics, and Chemistry. His robust educational background has equipped him with the knowledge and expertise to contribute meaningfully to the field of high-energy theoretical physics, especially in gauge theory and supersymmetry.

Professional experience:

Dr. Shri Krishna brings a wealth of experience from both research and teaching roles. After completing his Ph.D. in 2015, he undertook post-doctoral research at IISER Mohali, working with Prof. C.S. Aulakh from September 2015 to August 2018. His post-doctoral work focused on gauge theories and supersymmetry, contributing to the field with several impactful publications. Following this, Dr. Krishna transitioned into academia as an Assistant Professor (Ad-hoc) at Zakir Husain Delhi College and Miranda House, University of Delhi, where he has been teaching since August 2018. His teaching portfolio includes Quantum Mechanics, Electronics, Wave & Optics, and Elements of Modern Physics, among other subjects. His dual experience in advanced research and teaching has allowed him to bridge the gap between theoretical physics and pedagogical practice, offering students insights from cutting-edge research while guiding them through complex physics concepts.

Research focus:

Dr. Shri Krishna’s research focuses on higher p-form (p = 2, 3, 4) gauge theories within the framework of BRST and super field formulations. His work delves into the intricacies of supersymmetric quantum mechanics, particularly exploring N = 2, 4 systems and their novel symmetries. He has made significant contributions to understanding (non-)Abelian 2-form and 3-form gauge theories, which play a pivotal role in field theory and quantum mechanics. A key aspect of his research is developing theoretical models that unify aspects of gauge invariance, supersymmetry, and Hodge theory, aiming to offer deeper insights into the foundational principles of high-energy physics. Dr. Krishna continues to push the boundaries of these complex systems through his work on the BRST approach and super field methods, which hold promise for advancing theoretical models in high-energy particle physics.

Awards and Honors:

Dr. Shri Krishna has received several recognitions for his contributions to theoretical high-energy physics. During his academic career, he was awarded research fellowships at prestigious institutions, including his Ph.D. studies under the supervision of Prof. R.P. Malik at Banaras Hindu University (BHU). His research on BRST symmetry and gauge theories has been widely recognized, resulting in multiple publications in high-impact journals such as Annals of Physics and Eur. Phys. J. C. Additionally, Dr. Krishna has been invited to present his work at numerous national and international conferences, highlighting his research in areas like N = 2, 4 supersymmetric quantum mechanics and p-form gauge theories. These accolades reflect his dedication to advancing theoretical physics and his growing reputation within the academic and scientific communities.

Publication Top Notes:

  • A quantum mechanical example for Hodge theory
    S. Krishna, R. P. Malik
    Annals of Physics, 2024, 464, 169657.
    Citations: 1
  • A massive field-theoretic model for Hodge theory
    S. Krishna, R. Kumar, R. P. Malik
    Annals of Physics, 2020, 414, 168087.
    Citations: 12
  • Effective sextic superpotential and B – L violation in NMSGUT
    C. S. Aulakh, R. L. Awasthi, S. Krishna
    Pramana – Journal of Physics, 2017, 89(4), 51.
    Citations: 2
  • Augmented superfield approach to gauge-invariant massive 2-form theory
    R. Kumar, S. Krishna
    European Physical Journal C, 2017, 77(6), 387.
    Citations: 7
  • N = 4 supersymmetric quantum mechanical model: Novel symmetries
    S. Krishna
    International Journal of Modern Physics A, 2017, 32(11), 1750055.
    Citations: 1
  • Novel symmetries in an interacting N = 2 supersymmetric quantum mechanical model
    S. Krishna, D. Shukla, R. P. Malik
    International Journal of Modern Physics A, 2016, 31(19), 1650113.
    Citations: 8
  • N = 2 SUSY symmetries for a moving charged particle under influence of a magnetic field: Supervariable approach
    S. Krishna, R. P. Malik
    Annals of Physics, 2015, 355, pp. 204–216.
    Citations: 15
  • A free N = 2 supersymmetric system: Novel symmetries
    S. Krishna, R. P. Malik
    EPL, 2015, 109(3), 31001.
    Citations: 11
  • Augmented superfield approach to nilpotent symmetries of the modified version of 2D Proca theory
    A. Shukla, S. Krishna, R. P. Malik
    Advances in High Energy Physics, 2015, 2015, 258536.
    Citations: 9
  • Nilpotent and absolutely anticommuting symmetries in the Freedman-Townsend model: Augmented superfield formalism
    A. Shukla, S. Krishna, R. P. Malik
    International Journal of Modern Physics A, 2014, 29(31), 1450183.
    Citations: 5

Conclusion:

Dr. Shri Krishna is an accomplished researcher with a strong foundation in theoretical high-energy physics. His focus on supersymmetric quantum mechanics and gauge theories positions him as a strong candidate for the Best Researcher Award. With additional outreach and interdisciplinary collaborations, he could further elevate his already impressive academic standing.

 

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.