His main research concerns Quantum cryptography, Quantum key distribution, Quantum information, Quantum information science and Quantum. His Quantum cryptography research includes elements of Theoretical computer science and Uncertainty principle. His work deals with themes such as Discrete mathematics and Statistical physics, which intersect with Quantum information.
His Statistical physics study combines topics from a wide range of disciplines, such as Quantum mutual information, Entropic uncertainty, Joint quantum entropy and Quantum algorithm. His studies in Quantum information science integrate themes in fields like Alice and Bob, Computer engineering, Digital signature, Security analysis and Topology. Marco Tomamichel works in the field of Quantum, namely Quantum channel.
Marco Tomamichel focuses on Quantum, Statistical physics, Quantum channel, Quantum information and Discrete mathematics. His Quantum study incorporates themes from Kullback–Leibler divergence and Channel capacity. He interconnects Conditional entropy, Limit, Quantum mechanics, Quantum state and Entropic uncertainty in the investigation of issues within Statistical physics.
The various areas that Marco Tomamichel examines in his Quantum channel study include Quantum simulator, State, Topology and Quantum capacity. His work carried out in the field of Quantum information brings together such families of science as Quantum information science and Mathematical proof. His Discrete mathematics study combines topics in areas such as Quantum discord, Quantum relative entropy, Joint quantum entropy and Rényi entropy.
Marco Tomamichel mainly investigates Quantum, Quantum state, Kullback–Leibler divergence, Quantum entanglement and Discrete mathematics. His Quantum research is multidisciplinary, relying on both Electronic circuit, Statistical physics, Coherence and Bounded function. Statistical physics is frequently linked to Bell state in his study.
His research investigates the connection between Quantum entanglement and topics such as Resonance that intersect with problems in Sigma, Combinatorics and Work. He combines subjects such as Mutual information, Rényi entropy and Interpolation with his study of Discrete mathematics. His Classical capacity study, which is part of a larger body of work in Quantum channel, is frequently linked to Device independence, bridging the gap between disciplines.
Marco Tomamichel mainly focuses on Quantum, Quantum entanglement, Electronic circuit, Quantum algorithm and Noise. His study in Quantum is interdisciplinary in nature, drawing from both Statistical physics and Digital signature. The Statistical physics study combines topics in areas such as Kullback–Leibler divergence and Bell state, Entanglement distillation.
His work in the fields of Quantum entanglement, such as Quantum channel, overlaps with other areas such as Converse. His study in Quantum channel focuses on Quantum mutual information in particular. The study incorporates disciplines such as Bounded function and Topology in addition to Quantum algorithm.
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Tight finite-key analysis for quantum cryptography
Marco Tomamichel;Charles Ci Wen Lim;Nicolas Gisin;Renato Renner.
Nature Communications (2012)
On quantum Rényi entropies: A new generalization and some properties
Martin Müller-Lennert;Frédéric Dupuis;Oleg Szehr;Serge Fehr.
Journal of Mathematical Physics (2013)
Advances in quantum cryptography
S. Pirandola;U. L. Andersen;L. Banchi;M. Berta.
Advances in Optics and Photonics (2020)
Entropic uncertainty relations and their applications
Patrick J. Coles;Mario Berta;Marco Tomamichel;Stephanie Wehner.
Reviews of Modern Physics (2017)
Uncertainty Relation for Smooth Entropies
Marco Tomamichel;Renato Renner.
Bulletin of the American Physical Society (2011)
A framework for non-asymptotic quantum information theory
arXiv: Quantum Physics (2012)
A Fully Quantum Asymptotic Equipartition Property
M. Tomamichel;R. Colbeck;R. Renner.
IEEE Transactions on Information Theory (2009)
Continuous variable quantum key distribution: finite-key analysis of composable security against coherent attacks.
Fabian Furrer;Torsten Franz;Mario Berta;Anthony Leverrier.
Physical Review Letters (2012)
Leftover Hashing Against Quantum Side Information
M. Tomamichel;C. Schaffner;A. Smith;R. Renner.
IEEE Transactions on Information Theory (2011)
Quantum Information Processing with Finite Resources
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