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- Deprecated function: TYPO3\PharStreamWrapper\Manager::__construct(): Implicitly marking parameter $collection as nullable is deprecated, the explicit nullable type must be used instead in include_once() (line 19 of includes/file.phar.inc).
Submitted by
Khammerer on Wed, 27/03/2019 - 11:23.
Modern physics has been founded by the development of two fundamental theories in the first half of the 20th century: general relativity and quantum mechanics. Quantum mechanics governs the physics of the small fundamental particles such as electrons; general relativity describes large objects with gravitational interactions such as stars and galaxies. Despite the great success of modern physics in explaining most of our physical observations, there are a number of open, unanswered questions.
Submitted by
Demko on Thu, 07/03/2019 - 13:45.
Description of tasks
Study of fundamental bounds and optimal protocols in quantum metrology in presence of realistic noise models in optical and atomic systems both in single and multiparamter problems as well as investigations of connections between quantum metrology and quantum thermodynamics.
The candidates have to conform to the conditions stated in art. 113 of Higher Education Law dated 20.07.2018 (Journal of Laws of the Republic of Poland 2018, item 1668).
Requirements:
Faculty of Physics, University of Warsaw, Poland
Research topics:
- Quantum limits to optical interferometric protocols in presence of decoherence
- Fundamental limits to stability of atomic clocks using matrix product operator techniques
- Many-body and non-linear effects in quantum metrology
- Connections between quantum estimation theory and quantum thermodynamics
- Connections between quantum estimation and quantum communication theories
- Multiparameter quantum estimation and quantum imaging
Submitted by
Demko on Tue, 17/07/2018 - 09:59.
Application deadline:
Saturday, September 15, 2018
I am happy to announce a call for two 20-month Post-Doc positions in my project entitled:
"Photonic, Atomic and Thermodynamic Processes from a Quantum Metrological Perspective" financed by Polish National Science Center under SONATA BIS programme.
Scope of research for the project include:
Submission deadline:
Sunday, September 30, 2018
Registration deadline:
Sunday, September 30, 2018
Quantum simulation is an exceptionally vivid field of research embracing several areas of physics, ranging from atomic, molecular, and optical physics, to condensed-matter, nuclear, gravitational and high-energy physics, as well as quantum information science. The goal of quantum simulation is to address important, yet unsolved quantum Hamiltonians by “synthesizing” them in experimental quantum systems so as to directly measure the properties of these models, otherwise very hard to be handled by classical computations.
Submitted by
Kbanasz on Sat, 05/05/2018 - 16:27.
The Centre for Quantum Optical Technologies, established under the International Research Agenda Programme operated by the Foundation for Polish Science and hosted by the Centre of New Technologies, University of Warsaw, seeks to fill several junior research positions in the Quantum Technologies Laboratory led by Professor Konrad Banaszek. Current research effort in the Laboratory covers problems related to quantum optical communication, quantum metrology, and quantum imaging.
Submitted by
Torades on Wed, 21/03/2018 - 11:02.
Multiphoton quantum interference is one of the most intriguing phenomena in quantum physics, and is at the very heart of quantum computing and metrology technologies. However, the post-classical sensing and computational capabilities of multiphoton networks are yet far from being fully explored in practical experimental scenarios.
This theoretical project aims to develop scalable sensing and computational techniques based on the use of optimal linear interferometers with experimentally available photonic input states. The main idea is to exploit the full quantum information encoded in the interferometric evolution of the input photonic quantum states by employing novel measurement techniques (e.g. iterative interferometric dynamics, conditional dynamics, multiplexing and correlation measurements sensitive to the photonic inner and spatial modes).
Start date: 1 October 2018 or 1 February 2019
Application deadline: 7 May 2018
Supervisors: Dr V Tamma, Dr H Yu (Univeresity of Portsmouth), Prof G Adesso (University of Nottingham)
Submitted by
Demko on Sun, 17/09/2017 - 23:26.
Application deadline:
Saturday, September 30, 2017
2-year post-doc position will be devoted to study of fundamental bounds and optimal protocols in quantum metrology in presence of realistic noise models in optical and atomic systems both in single and multiparamter problems as well as investigations of connections between quantum metrology and quantum thermodynamics.
Post-doc position will be financed under the project “Photonic, Atomic and Thermodynamic Processes from a Quantum Metrological Perspective” financed by the Polish National Science Center under SONATA BIS programme.
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