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press_release_en [2019/07/01 09:32]
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press_release_en [2019/07/01 16:19] (current)
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  //​Press Release, July 1st 2019//  //​Press Release, July 1st 2019//
  
-Today, July 1st 2019, 38 research institutions from nine countries ​officially ​signed the agreement for the creation of a new international R&D collaboration for a future wide field-of-view gamma ray observatory in the southern hemisphere. The founding countries of the newly created Southern Wide field-of-view Gamma-ray Observatory (SWGO) are Argentina, Brazil, Czech Republic, Germany, Italy, Mexico, Portugal, the United Kingdom and the United States of America, creating a worldwide community around the project. SWGO unifies different communities that were already involved in R&D in this field. The signature of the agreement comes after a successful meeting of the scientists from the different countries, held in Lisbon in May.+Today, July 1st 2019, 39 research institutions from nine countries signed the agreement for the creation of a new international R&D collaboration for a future wide field-of-view gamma ray observatory in the southern hemisphere. The aim of the collaboration is to develop, over the next three years, a detailed proposal for the implementation of such an observatory,​ including site selection and technology choices. The founding countries of the newly created Southern Wide field-of-view Gamma-ray Observatory (SWGO) are Argentina, Brazil, Czech Republic, Germany, Italy, Mexico, Portugal, the United Kingdom and the United States of America, creating a worldwide community around the project. SWGO unifies different communities that were already involved in R&D in this field. The signature of the agreement comes after a successful meeting of the scientists from the different countries, held in Lisbon in May.
  
 The new observatory is planned to be installed in the Andes, at an altitude above 4.4 km, to detect the highest energy gamma rays — particles of light billion or trillions of times more energetic than visible light. It will probe the most extreme phenomena and environments to address some of the most compelling questions about our Universe, from the origin of high-energy cosmic rays to searching for dark matter particles and for deviations from Einstein’s theory of relativity. Its location in the southern hemisphere will allow the most interesting region of our galaxy to be observed directly, in particularly the Galactic Centre, hosting a black hole four million times the mass of the sun. Wide field-of-view observations are ideal to search for transient sources but also to search for very extended emission regions, including the ‘Fermi Bubbles’ or annihilating dark matter, as well as to discover unexpected phenomena. The new observatory will be a powerful time-variability explorer, filling an empty space in the global multi-messenger network of gravitational,​ electromagnetic and neutrino observatories. It will also be able to issue alerts and be fully complementary to the next generation imaging atmospheric Cherenkov telescope array, CTA. The new observatory is planned to be installed in the Andes, at an altitude above 4.4 km, to detect the highest energy gamma rays — particles of light billion or trillions of times more energetic than visible light. It will probe the most extreme phenomena and environments to address some of the most compelling questions about our Universe, from the origin of high-energy cosmic rays to searching for dark matter particles and for deviations from Einstein’s theory of relativity. Its location in the southern hemisphere will allow the most interesting region of our galaxy to be observed directly, in particularly the Galactic Centre, hosting a black hole four million times the mass of the sun. Wide field-of-view observations are ideal to search for transient sources but also to search for very extended emission regions, including the ‘Fermi Bubbles’ or annihilating dark matter, as well as to discover unexpected phenomena. The new observatory will be a powerful time-variability explorer, filling an empty space in the global multi-messenger network of gravitational,​ electromagnetic and neutrino observatories. It will also be able to issue alerts and be fully complementary to the next generation imaging atmospheric Cherenkov telescope array, CTA.
  
 {{ :​wiki:​swgo_pressimages_sky_light.png?​nolink |Gamma-ray sky image as seen by the (current) HAWC and (future) SWGO observatories}} {{ :​wiki:​swgo_pressimages_sky_light.png?​nolink |Gamma-ray sky image as seen by the (current) HAWC and (future) SWGO observatories}}
-//Gamma-ray sky image as seen by the (current) HAWC and (future) SWGO observatories (Credit: Richard White ,MPIK)//+//Gamma-ray sky image as seen by the (current) HAWC and (future) SWGO observatories (Credit: Richard White, MPIK)//
  
 The baseline for the new observatory will be the approach of the current ground-based gamma-ray detectors, namely HAWC in Mexico and LHAASO in China. In particular, water Cherenkov detectors will be used to sample the particle showers produced by gamma rays in the atmosphere, by recording the light produced when particles pass through tanks full of purified water. New layouts and technologies will however be explored in order to increase the sensitivity and lower the energy threshold of the observatory. The baseline for the new observatory will be the approach of the current ground-based gamma-ray detectors, namely HAWC in Mexico and LHAASO in China. In particular, water Cherenkov detectors will be used to sample the particle showers produced by gamma rays in the atmosphere, by recording the light produced when particles pass through tanks full of purified water. New layouts and technologies will however be explored in order to increase the sensitivity and lower the energy threshold of the observatory.
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 Direct detection of primary gamma-rays is only possible with satellite-based detectors, such as Fermi. However, the cost of space technology limits the size of satellite-borne detectors, and thus their sensitivity,​ as fluxes become too small at higher energies. In the atmosphere, gammas interact creating a shower of particles. These showers can be studied in observatories of two complementary types: imaging atmospheric Cherenkov telescopes, pointing instruments such as CTA, and high altitude air shower arrays, such as SWGO. Cherenkov telescopes are highly sensitive pointing detectors, with high precision but limited duty cycle and narrow field-of-view,​ benefiting from pointing alerts provided by complementary observatories. Wide field-of-view observations from the ground have the highest energy reach, and are ideal to search for transient sources and for emissions from very extended regions of the sky. Direct detection of primary gamma-rays is only possible with satellite-based detectors, such as Fermi. However, the cost of space technology limits the size of satellite-borne detectors, and thus their sensitivity,​ as fluxes become too small at higher energies. In the atmosphere, gammas interact creating a shower of particles. These showers can be studied in observatories of two complementary types: imaging atmospheric Cherenkov telescopes, pointing instruments such as CTA, and high altitude air shower arrays, such as SWGO. Cherenkov telescopes are highly sensitive pointing detectors, with high precision but limited duty cycle and narrow field-of-view,​ benefiting from pointing alerts provided by complementary observatories. Wide field-of-view observations from the ground have the highest energy reach, and are ideal to search for transient sources and for emissions from very extended regions of the sky.
 {{ :​wiki:​swgo_pressimages_detector_light_tank.png?​nolink |Illustration of the complementary detection techniques of high-energy gamma rays on ground}} {{ :​wiki:​swgo_pressimages_detector_light_tank.png?​nolink |Illustration of the complementary detection techniques of high-energy gamma rays on ground}}
-//​Illustration of the complementary detection techniques of high-energy gamma rays on ground. (Credit: Richard White ,MPIK)//+//​Illustration of the complementary detection techniques of high-energy gamma rays on ground. (Credit: Richard White, MPIK)// 
 + 
 + 
 +Contacts (PIs representing the scientific communities of the different countries) 
 +  * Argentina: Adrian Rovero, Instituto de Astronomía y Física del Espacio 
 +  * Brazil: Ronald Shellard, Centro Brasileiro de Pesquisas Físicas, Rio de Janeiro,  
 +  * Czech Republic: Jakub Vicha, Institute of Physics of the Czech Academy of Sciences in Prague 
 +  * Germany: Jim Hinton, Max Planck Institute for Nuclear Physics, Heidelberg,​ 
 +  * Italy: ​ Alessandro De Angelis, University Udine/Padua and INFN Padua, +39 320 4366230 
 +  * Mexico: ​ Andre Sandoval, UNAM, Cidade do Mexico 
 +  * Portugal: Mário Pimenta, LIP/IST, Lisboa, +351 93 6992234 
 +  * UK : Jon Lapington, Univ. Leicester 
 +  * USA: Petra Huentemeyer,​ Michigan Technological University
press_release_en.1561966321.txt.gz · Last modified: 2019/07/01 09:32 by swgowikiadmin