Prof. Kammogne Djoum Nana Anicet | Theoretical Condensed Matter Physics – University of Dschang, Cameroon
Dr. Kammogne Djoum Nana Anicet is an accomplished physicist and researcher in the Department of Physics at the University of Dschang, Cameroon. A dedicated academic, analytical thinker, and emerging voice in quantum theory, Dr. Kammogne has made significant contributions to the understanding of dissipation, interferometry, and spontaneous emission in quantum systems. He is affiliated with international academic platforms such as Scopus and ResearcherID and actively contributes to the development of theoretical condensed matter physics in Africa.
Academic Profile
ORCID
Education
Dr. Kammogne’s academic journey is deeply rooted in the University of Dschang, where he completed both his Master’s and Ph.D. in Physics. His doctoral research, supervised by Prof. Lukong Cornelius Fai and Dr. Nsangou Issofa, explored interferometry, quantum dissipation, and non-resonant spontaneous emission in quantum systems. This work was awarded the highest academic distinction, earning unanimous praise from the examination committee. His studies have laid a solid foundation for his expertise in open quantum systems and their interaction with the environment.
Experience
Dr. Kammogne’s professional experience spans both teaching and research roles within the University of Dschang. He began as a laboratory monitor and later served as a tutor and lecturer, delivering undergraduate and postgraduate courses in electromagnetism, quantum mechanics, solid-state physics, and electrostatics. From 2019 to 2023, he was a core member of the Laboratory of Condensed-Matter, Electronics, and Processing, where he played a central role in curriculum design, mentorship, and collaborative research activities. His dedication to academic excellence and scientific integrity has made him a respected figure among students and faculty alike.
Research Interests
Dr. Kammogne’s research focuses on the theoretical modeling of dissipative quantum systems, spontaneous emission, and interference phenomena in non-resonant environments. His recent work addresses key challenges in quantum level-crossing physics and coherence loss. In 2025, he co-authored two preprints on arXiv: “A Closed-Form Approach to Oscillatory Integrals in Level-Crossing Physics” (with Dr. Maseim B. Kenmoe) and “Effect of Spontaneous Emission on a Tanh Model.” These studies offer novel insights into quantum dissipation mechanisms, with implications for quantum computing, nanophotonics, and next-generation quantum devices.
Awards
Dr. Kammogne received the highest honors for his Ph.D. dissertation, reflecting the depth and originality of his research. He maintains an active presence on scientific platforms such as ResearchGate, Scopus, and ResearcherID. His continued contributions to the field of condensed matter physics have gained recognition within academic networks in Cameroon and internationally. His commitment to scientific progress and student development continues to elevate his standing in the global physics community.
📖Notable Publications
A Closed-Form Approach to Oscillatory Integrals in Level-Crossing Physics – arXiv (2025) – Developed analytical techniques for evaluating oscillatory integrals in quantum level-crossing models.
Effect of Spontaneous Emission on a Tanh Model – arXiv (2025) – Analyzed the impact of spontaneous emission on population dynamics in a hyperbolic-tangent quantum model.
Spontaneous Emission in an Exponential Model – arXiv (2024) – Investigated dissipative quantum transitions in exponential interaction systems.
Non-resonant Exponential Nikitin Models with Decay – Chinese Journal of Physics (2024) – Extended Nikitin-type models to include decay and non-resonant interactions in quantum dissipation studies.
Statistics of Interferograms in Three-Level Systems – Physics Letters A (2022) – Explored statistical properties of interferometric signals in multi-level quantum systems.
Conclusion
Dr. Kammogne Djoum Nana Anicet exemplifies the qualities of a leading theoretical physicist—analytical depth, research innovation, and academic integrity. His contributions to quantum dissipation and interferometry have significant implications for emerging fields like quantum computing and photonics. With continued scholarly engagement, he stands out as a strong nominee for the Best Researcher Award.