Dr. Alan Santos | Quantum Mechanics | Young Scientist Award

Post-doc at Spanish National Research Council, Spain

Alan C. Santos is a post-doctoral researcher at CSIC in Madrid, Spain, specializing in quantum mechanics, quantum thermodynamics, and quantum computation. He has a robust academic background, having completed his Ph.D. in Physics at the Federal Fluminense University, Brazil, with a focus on adiabatic dynamics. His research interests include quantum control, superconducting circuits, quantum technology, and matter-light interaction in quantum optics. Throughout his career, he has received multiple research grants and contributed to significant publications in quantum science. 🌍💡🔬

Professional Profile:

Orcid

Google Scholar

Education and Experience:

Regional University of Cariri, Brazil: Undergraduate in Physics (2010-2014) 📚
Federal Fluminense University, Brazil: Master’s degree in Physics (2014-2016) 🎓
Federal Fluminense University, Brazil: Ph.D. in Physics (2016-2020) 🔬
Federal University of São Carlos, Brazil: Post-Doctoral Researcher (2020-2022) 👩‍🔬
Department of Physics, Stockholm University, Sweden: Post-Doctoral Researcher (2022-2023) ✈️
CSIC, Madrid, Spain: Post-Doctoral Researcher (2024-Present) 🧑‍🔬

Professional Development:

Alan has honed his skills with a wide range of courses in quantum information, superconductivity, and quantum optics. He has participated in international internships, including at Stockholm University, and has received funding from prestigious institutions like CAPES, CNPq, and FAPESP. These experiences allow him to stay on the cutting edge of quantum research. His continuous growth is evident through his active participation in major international collaborations and the development of quantum devices. 🏫🌐📈

Research Focus:

Alan’s research spans across fundamental areas of quantum mechanics, quantum thermodynamics, and quantum computation. His primary focus is on adiabatic quantum dynamics, quantum control (including both closed and open systems), and quantum information theory. He also investigates the applications of superconducting qubits, quantum technology, and the interaction between matter and light in quantum optics. His work contributes to the advancement of quantum technologies, paving the way for innovations in quantum devices and computational methods. ⚛️💻🔍

Awards and Honors:

CNPq Fellowship for Ph.D. Research 🏅
FAPESP Funding for Postdoctoral Research 🧑‍🔬
Sinergico CAM 2020 Y2020/TCS-6545 Project Funding (NanoQuCo-CM) 💼
European Union’s Horizon 2020 FET-Open Project Funding (SuperQuLAN) 🌍
“Cesar Nombela” Fellow for Atracción de Talentos CM 2024

Publication Top Notes

1. Validity Condition for High-Fidelity Digitized Quantum Annealing

Journal: Physical Review A
Publication Date: February 18, 2025
DOI: 10.1103/physreva.111.022618
ISSN: 2469-9926, 2469-9934
Summary: This paper explores the conditions required to achieve high fidelity in digitized quantum annealing, a computational method that seeks to solve optimization problems by simulating the behavior of quantum systems.

2. Encoding Quantum Bits in Bound Electronic States of a Graphene Nanotorus

Journal: Annals of Physics
Publication Date: January 2025
DOI: 10.1016/j.aop.2024.169862
ISSN: 0003-4916
Summary: This paper investigates the possibility of encoding quantum bits (qubits) in the bound electronic states of graphene nanotorus structures. The study suggests potential uses of this system in quantum computing, focusing on the stability and control of the encoded quantum information.

3. Quantum Steering Ellipsoids and Quantum Obesity in Critical Systems

Journal: Europhysics Letters
Publication Date: November 1, 2024
DOI: 10.1209/0295-5075/ad8f5e
ISSN: 0295-5075, 1286-4854
Summary: The paper presents a novel approach to studying quantum steering in critical systems, introducing the concept of “quantum obesity” as a way of understanding complex quantum phenomena in critical conditions, potentially shedding light on the behavior of quantum systems at phase transitions.

4. Quantum Battery Supercharging via Counter-Diabatic Dynamics

Journal: Quantum Science and Technology
Publication Date: October 1, 2024
DOI: 10.1088/2058-9565/ad71ed
ISSN: 2058-9565
Summary: This study delves into the theoretical possibilities of supercharging quantum batteries by employing counter-diabatic dynamics. By controlling the evolution of quantum systems, the paper demonstrates ways to enhance the efficiency and power output of quantum batteries.

5. Stable Collective Charging of Ultracold-Atom Quantum Batteries

Journal: Physical Review A
Publication Date: September 6, 2024
DOI: 10.1103/physreva.110.032205
ISSN: 2469-9926, 2469-9934
Summary: This paper explores the concept of quantum batteries made from ultracold atoms and their potential for stable, collective charging. The research investigates how collective effects in quantum systems can be harnessed to improve the performance of quantum energy storage systems.

Conclusion:

Alan C. Santos is a strong candidate for the Young Scientist Award due to his impressive academic trajectory, substantial contributions to quantum physics, and ongoing engagement in groundbreaking research. His innovative work in quantum computation, thermodynamics, and control theory, coupled with his ability to secure competitive funding and collaborate on international projects, demonstrates his potential to become a leading figure in his field. His continued focus on quantum technologies positions him well to shape the future of quantum science and technology.

Given his proven capabilities, interdisciplinary contributions, and innovative approach to solving complex scientific problems, Alan C. Santos is highly deserving of the Young Scientist Award.

Dr. Muhammad Sajid | Quantum Science | Best Researcher Award

Dr. Muhammad Sajid, University of electronic science and technology of China, China

Dr. Muhammad Sajid is a Postdoctoral Researcher at the University of Electronic Science and Technology of China (UESTC). He holds a Ph.D. in Physics from Bonn University, Germany, with extensive experience in quantum simulations, condensed matter physics, and quantum information. Prior to joining UESTC, he served as an Assistant Professor at Kohat University of Science and Technology, Pakistan. His research focuses on Quantum Walks, Bose-Einstein Condensates, and topological phenomena in quantum systems.

PROFILE

Educational Details:

Dr. Muhammad Sajid is a physicist with expertise in quantum simulations, condensed matter physics, and quantum information. He earned his Ph.D. in Physics (Magna cum Laude) from Bonn University, Germany, in 2018, under the supervision of Professor Dieter Meschede and Dr. Andrea Alberti. His thesis focused on the “Magnetic Quantum Walks of Neutral Atoms in Optical Lattices.” Prior to his doctoral studies, Dr. Sajid completed an M.Phil. in Physics in 2012 at Quaid-i-Azam University, Islamabad, where he studied the behavior of Bose-Einstein Condensates under Gaussian random potentials. He also holds an M.Sc. in Physics (2010) from the same institution, where he was awarded the Chancellor Medal, and a B.Sc. with Distinction from the University of Peshawar (2007). His academic journey began with a distinguished performance during his F.Sc. Pre-Engineering studies in 2005 and matriculation in 2003, both completed with distinctions in Peshawar.

Professional Experience

Professionally, Dr. Sajid has been a Postdoctoral Researcher at the Institute of Fundamental and Frontier Sciences, University of Electronic Science and Technology of China (UESTC), since December 2023. Before that, he served as an Assistant Professor in Physics at Kohat University of Science and Technology, Pakistan, from February 2018 to December 2023, and as a Lecturer in Physics at the same institution from December 2010 to February 2018. His academic roles have involved both teaching and research, with a focus on advancing the understanding of quantum systems.

Research Interest

Dr. Sajid’s research interests encompass a broad range of topics within quantum physics. He is particularly interested in Quantum Walks, Quantum Simulations with Quantum Walks, Condensed Matter Physics, Quantum Information and Computation, Topological Phenomena in Driven Quantum Systems, Bose-Einstein Condensates, and Many-Body Localization. His work delves into both theoretical and experimental aspects of these phenomena, contributing to the advancement of knowledge in quantum systems and their potential applications.

Top Notable Publications

Sajid, M., Khan, N.A., & Shah, M. (2024). Topological pumping in an inhomogeneous Aubry–André model. Chinese Journal of Physics, 92, 311–320.
Citations: 0

Shah, M., Shah, M., Khan, N.A., Abo-Dief, H.M., & Alzahrani, E. (2024). Spin and valley-polarized Faraday rotation in irradiated buckled Xene materials. Optical Materials Express, 14(7), 1676–1689.
Citations: 1

Shah, M., Shah, M., Khan, N.A., Jan, M., & Xianlong, G. (2024). Tunable quantized spin Hall effect of light in graphene. Results in Physics, 60, 107676.
Citations: 2

Shah, M., Hayat, A., Sajid, M., Khan, N.A., & Jan, M. (2023). Photonic spin Hall effect in uniaxially strained graphene. Physica Scripta, 98(12), 125943.
Citations: 3

Sajid, M., Shah, M., Khan, N.A., & Jan, M. (2023). Quantum walks in an inhomogeneous off-diagonal Aubry-André-Harper model. Physics Letters A, 469, 128763.
Citations: 1

Shah, M., Khan, N.A., & Sajid, M. (2022). Optical conductivity of ultrathin Floquet topological insulators. Journal of Physics D: Applied Physics, 55(41), 415103.
Citations: 1

Khan, N.A., Muhammad, S., Sajid, M., & Saud, S. (2022). Single parameter scaling in the non-Hermitian Anderson model. Physica Scripta, 97(7), 075817.
Citations: 0

Khan, N.A., Jan, M., Shah, M., Ali, M., & Khan, D. (2022). Entanglement-based measure of non-Makovianity in relativistic frame. Optik, 260, 169016.
Citations: 0

Khan, N.A., Muhammad, S., & Sajid, M. (2022). Single parameter scaling in the correlated Anderson model. Physica E: Low-Dimensional Systems and Nanostructures, 139, 115150.
Citations: 6

Conclusion

Alan Santos | Quantum Mechanics | Young Scientist Award