Gravitation

Searching for Supermassive Black Hole Binaries with Pulsar Timing Array

International Pulsar Timing Array is a consortium of four collaborations working on detecting gravitational waves (GWs) in the nano-Hz band. The analysis of the third combined dataset of radio observations from 9 worldwide telescopes will start at the end of 2023. We are searching for GWs from a population of supermassive black hole binaries (SMBHBs). The expected signal could be decomposed into two components: the stochastic signal that is the result of an incoherent superposition of thousands of weak signals and the resolvable signal(s) from particularly massive and nearby binaries.

Poste Maître.sse de Conférences 2023 -- LISA

L'Université Paris Cité ouvre un poste de Maître.sse de Conférences axé sur la
préparation de l’analyse des données de la mission LISA.

Le.a candidat.e retenu.e sera amené.e à travailler en astronomie des ondes gravitationnelles. En particulier, cette personne est appelée à devenir membre du projet LISA et à contribuer au développement et à la gestion du centre de traitement des données LISA en maintenant des liens étroits avec le CNES.

Informations administratives concernant ce poste

Quantum noise reduction for new-generation gravitational-wave detectors


Second generation gravitational wave (GW) detectors opened era of gravitational wave astronomy with the first GW detection in 2015 and are now approaching their design sensitivity. During the 3 past observations runs, they detected 90 GW signals produced by the merging of binary compact objects, providing a wealth of scientific results ranging from the general relativity, to astrophysics and cosmology.
 

Quantum noise reduction for new-generation gravitational-wave detectors

Second generation gravitational wave (GW) detectors opened era of gravitational wave astronomy with the first GW detection in 2015 and are now approaching their design sensitivity. During the 3 past observations runs, they detected 90 GW signals produced by the merging of binary compact objects, providing a wealth of scientific results ranging from the general relativity, to astrophysics and cosmology.
 

Optimal representation of Extreme Mass Ratio Insiral waveforms using ML techniques

Extreme Mass Ratio Inspirals (EMRI) are one of the most interesting signals which will be detected by Laser Interferometer Space Antenna (LISA). They will sample highly curved spacetime around Massive Black Holes (MBH) and allow for insight into the strong regime of gravity. EMRIs are signals which come from the compact objects falling onto MBH, they typically last for 10^5 number of cycles which translates into an order of one year length. They have relatively low signal-to-noise ratios (SNR) and typically it is required to observe them for a long time to be able to accumulate enough SNR.
LISA has passed a feasibility review and is officially entering the preliminary design phase.
LISA a passé  avec succès une revue de faisabilité et entre  officiellement en phase de conception préliminaire.

Constraining parameters of cosmic strings with Pulsar Timing Array

Pulsar timing array (PTA) uses long-term monitoring of ultra-stable millisecond pulsars to search for gravitational wave (GW) signal in the nano-Hz band. The recently detected common red noise could potentially be a stochastic GW signal.  Such a signal could be generated by a population of supper-massive black hole binaries or by violent processes in the early Universe. We will assume that this signal was produced by a network of cosmic strings and infer their properties using observational data. 

Using quantum correlations to study black-holes: squeezing techniques for present and next generation gravitational-wave detectors

Second generation gravitational wave (GW) detectors opened era of gravitational wave astronomy with the fist GW detection in 2015 and are now approaching their design sensitivity. During the 3 past observations runs, they detected 90 GW signals produced by the merging of binary compact objects, providing a wealth of scientific results ranging from the general relativity, to astrophysics and cosmology.
 

Using quantum correlations to study black-holes: squeezing techniques for present and next generation gravitational-wave detectors

Second generation gravitational wave (GW) detectors opened era of gravitational wave astronomy with the fist GW detection in 2015 and are now approaching their design sensitivity. During the 3 past observations runs, they detected 90 GW signals produced by the merging of binary compact objects, providing a wealth of scientific results ranging from the general relativity, to astrophysics and cosmology.
 

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