Jean-Pierre Baronick scite author profile

Advanced Virgo is the project to upgrade the Virgo interferometric detector of gravitational waves, with the aim of increasing the number of observable galaxies (and thus the detection rate) by three orders of magnitude. The project is now in an advanced construction phase and the assembly and integration will be completed by the end of 2015. Advanced Virgo will be part of a network, alongside the two Advanced LIGO detectors in the US and GEO HF in Germany, with the goal of contributing to the early detections of gravitational waves and to the opening a new window of observation on the universe. In this paper we describe the main features of the Advanced Virgo detector and outline the status of the construction.

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MUST2: A new generation array for direct reaction studies

Pollacco

Beaumel

Roussel‐Chomaz

et al. 2005

Eur. Phys. J. A

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Photo-fission for the production of radioactive beams ALTO project

Essabaa

Arianer

Ausset

et al. 2003

Nuclear Instruments and Methods in Physics Research Section B:

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TARANIS XGRE and IDEE detection capability of terrestrial gamma-ray flashes and associated electron beams

Sarria

Lebrun

Blelly

et al. 2017

Geosci. Instrum. Method. Data Syst.

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Abstract. With a launch expected in 2018, the TARANIS microsatellite is dedicated to the study of transient phenomena observed in association with thunderstorms. On board the spacecraft, XGRE and IDEE are two instruments dedicated to studying terrestrial gamma-ray flashes (TGFs) and associated terrestrial electron beams (TEBs). XGRE can detect electrons (energy range: 1 to 10 MeV) and X-and gammarays (energy range: 20 keV to 10 MeV) with a very high counting capability (about 10 million counts per second) and the ability to discriminate one type of particle from another. The IDEE instrument is focused on electrons in the 80 keV to 4 MeV energy range, with the ability to estimate their pitch angles.Monte Carlo simulations of the TARANIS instruments, using a preliminary model of the spacecraft, allow sensitive area estimates for both instruments. This leads to an averaged effective area of 425 cm 2 for XGRE, used to detect Xand gamma-rays from TGFs, and the combination of XGRE and IDEE gives an average effective area of 255 cm 2 which can be used to detect electrons/positrons from TEBs. We then compare these performances to RHESSI, AGILE and Fermi GBM, using data extracted from literature for the TGF case and with the help of Monte Carlo simulations of their mass models for the TEB case.Combining this data with the help of the MC-PEPTITA Monte Carlo simulations of TGF propagation in the atmosphere, we build a self-consistent model of the TGF and TEB detection rates of RHESSI, AGILE and Fermi. It can then be used to estimate that TARANIS should detect about 200 TGFs yr −1 and 25 TEBs yr −1 .

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