Max Planck Society
Florian Marquardt mainly focuses on Quantum, Quantum mechanics, Phonon, Photon and Nonlinear system. His research on Quantum focuses in particular on Optomechanics. The Quantum mechanics study which covers Classical mechanics that intersects with Dissipation, Dissipative system and Quantum dynamics.
His studies in Phonon integrate themes in fields like Quantum noise and Optics. The concepts of his Photon study are interwoven with issues in Photonics, Yttrium iron garnet, Lattice and Lorentz force, Magnetic field. His study in Nonlinear system is interdisciplinary in nature, drawing from both Attractor and Optical cavity.
Florian Marquardt spends much of his time researching Quantum mechanics, Quantum, Photon, Optomechanics and Phonon. His research on Quantum mechanics often connects related topics like Quantum electrodynamics. His study ties his expertise on Classical mechanics together with the subject of Quantum.
His Photon study combines topics in areas such as Lattice, Magnetic field, Laser and Coupling. As part of his research on Optomechanics, studies on Resonator and Optoelectronics are part of the effort. His studies examine the connections between Phonon and genetics, as well as such issues in Atomic physics, with regards to Laser cooling.
Florian Marquardt mainly investigates Quantum, Artificial neural network, Nonlinear system, Many body and Reinforcement learning. Florian Marquardt is involved in the study of Quantum that focuses on Quantum simulator in particular. His Nonlinear system study integrates concerns from other disciplines, such as Non-equilibrium thermodynamics, Topological order, Laser and Dynamics.
His research integrates issues of Ion, Statistical physics and Dephasing in his study of Many body. Florian Marquardt focuses mostly in the field of Reinforcement learning, narrowing it down to topics relating to Quantum algorithm and, in certain cases, Electronic circuit. Magnetization is a subfield of Quantum mechanics that Florian Marquardt tackles.
Florian Marquardt mostly deals with Quantum, Nonlinear system, Quantum mechanics, Laser and Topological order. The Quantum simulator research Florian Marquardt does as part of his general Quantum study is frequently linked to other disciplines of science, such as Exponential function, therefore creating a link between diverse domains of science. His Nonlinear system research includes themes of Chaotic, Quasiperiodic function, Attractor and Classical mechanics.
Quantum mechanics is represented through his Bound state, Ising model, Magnetization, Coupling and Phonon research. His studies deal with areas such as Non-equilibrium thermodynamics, Range, Condensed matter physics and Dynamics as well as Laser.
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Markus Aspelmeyer;Tobias J. Kippenberg;Florian Marquardt.
Reviews of Modern Physics (2013)
Introduction to quantum noise, measurement, and amplification
A. A. Clerk;M. H. Devoret;S. M. Girvin;Florian Marquardt.
Reviews of Modern Physics (2010)
Strong dispersive coupling of a high-finesse cavity to a micromechanical membrane.
J. D. Thompson;B. M. Zwickl;A. M. Jayich;Florian Marquardt.
Quantum Theory of Cavity-Assisted Sideband Cooling of Mechanical Motion
Florian Marquardt;Joe P. Chen;Joe P. Chen;A. A. Clerk;S. M. Girvin.
Physical Review Letters (2007)
Quantum squeezing of motion in a mechanical resonator
E. E. Wollman;C. U. Lei;A. J. Weinstein;J. Suh.
Dispersive optomechanics: a membrane inside a cavity
A M Jayich;J C Sankey;B M Zwickl;C Yang.
New Journal of Physics (2008)
Dynamical multistability induced by radiation pressure in high-finesse micromechanical optical cavities.
Florian Marquardt;Florian Marquardt;J. G. E. Harris;S. M. Girvin.
Physical Review Letters (2006)
Topological Phases of Sound and Light
V. Peano;C. Brendel;M. Schmidt;F. Marquardt;F. Marquardt.
Physical Review X (2015)
Generalized non-reciprocity in an optomechanical circuit via synthetic magnetism and reservoir engineering
Kejie Fang;Jie Luo;Anja Metelmann;Anja Metelmann;Matthew H. Matheny.
Nature Physics (2017)
Back-action evasion and squeezing of a mechanical resonator using a cavity detector
A A Clerk;F Marquardt;K Jacobs.
New Journal of Physics (2008)
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