What is he best known for?
The fields of study he is best known for:
- Quantum mechanics
- Photon
- Laser
His main research concerns Quantum mechanics, Photon, Quantum optics, Quantum cryptography and Quantum key distribution.
His Quantum mechanics and Quantum technology, Quantum, Quantum information, Bell's theorem and Bell test experiments investigations all form part of his Quantum mechanics research activities.
His work carried out in the field of Photon brings together such families of science as Nanocrystal, Excitation, Atomic physics and Quantum entanglement.
His study in Quantum optics is interdisciplinary in nature, drawing from both Quantum state and Squeezed coherent state.
His work deals with themes such as Repeater, Node, Computer network, Algorithm and Secure communication, which intersect with Quantum cryptography.
Quantum key distribution is a subfield of Optics that Philippe Grangier tackles.
His most cited work include:
- Experimental Realization of Einstein-Podolsky-Rosen-Bohm Gedankenexperiment : A New Violation of Bell's Inequalities (1852 citations)
- Experimental Tests of Realistic Local Theories via Bell's Theorem (1504 citations)
- Quantum key distribution using gaussian-modulated coherent states (879 citations)
What are the main themes of his work throughout his whole career to date?
Philippe Grangier mainly focuses on Quantum mechanics, Atomic physics, Optics, Quantum and Photon.
His work in Quantum information, Quantum optics, Quantum technology, Quantum network and Quantum cryptography are all subfields of Quantum mechanics research.
His biological study spans a wide range of topics, including Quantum key distribution, Homodyne detection, Coherent states and Nonlinear optics.
His research integrates issues of Dipole, Atom, Excitation and Optical tweezers in his study of Atomic physics.
His Optics research is multidisciplinary, incorporating elements of Quantum noise, Optoelectronics, Shot noise and Squeezed coherent state.
His research in Photon intersects with topics in Nanocrystal and Beam splitter.
He most often published in these fields:
- Quantum mechanics (25.14%)
- Atomic physics (23.46%)
- Optics (21.79%)
What were the highlights of his more recent work (between 2013-2021)?
- Quantum (18.99%)
- Vehicle routing problem (3.63%)
- Theoretical physics (6.70%)
In recent papers he was focusing on the following fields of study:
Philippe Grangier mostly deals with Quantum, Vehicle routing problem, Theoretical physics, Quantum mechanics and Quantum system.
The Quantum study combines topics in areas such as Beam splitter, Photon, Interference, Ground state and Inequality.
His Photon research incorporates themes from Photonics, Optoelectronics, Phase, Pulse and Quantum information.
His studies deal with areas such as Quantization, No-communication theorem, Quantum thermodynamics and Bell test experiments as well as Theoretical physics.
Borrowing concepts from Linear amplifier, Philippe Grangier weaves in ideas under Quantum mechanics.
His study explores the link between Quantum optics and topics such as Optical communication that cross with problems in Quantum key distribution.
Between 2013 and 2021, his most popular works were:
- An adaptive large neighborhood search for the two-echelon multiple-trip vehicle routing problem with satellite synchronization (98 citations)
- An adaptive large neighborhood search for the two-echelon multiple-trip vehicle routing problem with satellite synchronization (98 citations)
- Homodyne tomography of a single photon retrieved on demand from a cavity-enhanced cold atom memory. (74 citations)
In his most recent research, the most cited papers focused on:
- Quantum mechanics
- Photon
- Laser
Philippe Grangier focuses on Quantum, Quantum mechanics, Atomic physics, van der Waals force and Optical cavity.
His studies examine the connections between Quantum and genetics, as well as such issues in Phase, with regards to Wigner distribution function, Quantum tomography, Optics, Single-mode optical fiber and Density matrix.
His research brings together the fields of Point and Quantum mechanics.
His work on Excited state is typically connected to Rydberg atom as part of general Atomic physics study, connecting several disciplines of science.
His van der Waals force research is multidisciplinary, relying on both Beam and Ground state.
His Optical cavity study combines topics from a wide range of disciplines, such as Photonics, Optoelectronics, Quantum gate and Photon.
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