Agua Negra Deep Experiment Site (ANDES)

From Wikipedia, the free encyclopedia

The Agua Negra Deep Experiment Site (ANDES) is a project for the construction and operation of an underground laboratory in the Agua Negra Tunnel, between Argentina and Chile.[1] Argentina, Brazil, Chile, Mexico are involved in this project and are also expected to integrate the whole international scientific community.[2][3][4]

Possible Scientific Research Areas[]

Neutrino physics: For the study of geoneutrinos, underground laboratories in the absence of close by nuclear power plants are necessary.[5] Detailed studies of the nature and mass of the neutrinos helps in our understanding of Nature (geoneutrinos are related to the thermal equilibrium of the Earth).[6]

Dark Matter: experiments in this field greatly benefit from being in very deep underground laboratories. [7] It involves usually huge detection mass, very low detection thresholds, and an excellent control of the detector backgrounds. Furthermore, an indirect way to detect dark matter is to find a modulation caused by the movement of the Earth in the halo of dark matter.[8] A laboratory located in the southern hemisphere could unambiguously discriminate in between atmospheric induced backgrounds and dark matter signals.

Geoscience: The zone of the Agua Negra Pass one of the world most seismically active regions.[9] This is ideal to place highly sensitive seismographs, able to record seismic frequencies from around 1 Hz, of local earthquakes, to very ultra-long periods of more than 100 sec of the earth normal modes vibrations excited by a large earthquake. For this measurements, low background noise is required and can be achieve at an underground laboratory.

Biology: Experiments in a deep underground laboratory could investigate the possible contribution of cosmic radiation to the basal DNA damage, as it free from this kind of radiation.[10] This damages can develop pathologies like cancer.[11]

Low radioactivity measurements: the new generation of detectors used in the dark matter and neutrino underground experiments require the ability to measure extremely low radiation levels. These measurements are also useful in multiple areas like ecology, glaciology, microelectronics and in the selection of pure materials with almost no radioactive content. Nuclear astrophysics can also be researched with dedicated equipment.[12]

International support[]

The ANDES deep underground project has support from different institutions and scientists, both in Latin America[13] and worldwide.[14] Governments of Argentina and Chile has express their support for the development of the project.[15][16]

References[]

  1. ^ Dib, Claudio O. (2015). "ANDES: An Underground Laboratory in South America". Physics Procedia. 61: 534–541. Bibcode:2015PhPro..61..534D. doi:10.1016/j.phpro.2014.12.118.
  2. ^ Shivni, Rashmi. "1,000 meters below". symmetry magazine.
  3. ^ "ANDES | ITeDA". www.iteda.cnea.gov.ar.
  4. ^ Bertou, X. (September 20, 2012). "The ANDES underground laboratory". The European Physical Journal Plus. 127 (9): 104. Bibcode:2012EPJP..127..104B. doi:10.1140/epjp/i2012-12104-1. S2CID 121144855.
  5. ^ Smirnov, O. (2019). "Experimental aspects of geoneutrino detection: Status and perspectives". Progress in Particle and Nuclear Physics. 109: 103712. arXiv:1910.09321. Bibcode:2019PrPNP.10903712S. doi:10.1016/j.ppnp.2019.103712. S2CID 201256376.
  6. ^ Jenkins, Amber (July 28, 2005). "Earthly whispers of geoneutrinos". Nature Physics. doi:10.1038/nphys013 – via www.nature.com.
  7. ^ Irastorza, Igor G. (2009). "Physics at Underground Laboratories: Direct Detection of Dark Matter". arXiv:0911.2855 [astro-ph.CO].
  8. ^ Britto, Vivian; Meyers, Joel (2015). "Monthly modulation in dark matter direct-detection experiments". Journal of Cosmology and Astroparticle Physics. 2015 (11): 006. arXiv:1409.2858. Bibcode:2015JCAP...11..006B. doi:10.1088/1475-7516/2015/11/006. S2CID 119274007.
  9. ^ Dewey, J. F.; Lamb, S. H. (April 30, 1992). "Active tectonics of the Andes". Tectonophysics. 205 (1): 79–95. Bibcode:1992Tectp.205...79D. doi:10.1016/0040-1951(92)90419-7.
  10. ^ Cucinotta, Francis A.; Cacao, Eliedonna (May 12, 2017). "Non-Targeted Effects Models Predict Significantly Higher Mars Mission Cancer Risk than Targeted Effects Models". Scientific Reports. 7 (1): 1832. Bibcode:2017NatSR...7.1832C. doi:10.1038/s41598-017-02087-3. PMC 5431989. PMID 28500351.
  11. ^ Cucinotta, Francis A.; Durant, Marco (January 2006). "Cancer risk from exposure to galactic cosmic rays - implications for human space exploration. Francis A. Cucinotta, Marco Durante" (PDF).
  12. ^ Laubenstein, M.; Hult, M.; Gasparro, J.; Arnold, D.; Neumaier, S.; Heusser, G.; Köhler, M.; Povinec, P.; Reyss, J.-L; Schwaiger, M.; Theodórsson, P. (2004). "Underground measurements of radioactivity". Applied Radiation and Isotopes. 61 (2–3): 167–172. doi:10.1016/j.apradiso.2004.03.039. PMID 15177339.
  13. ^ "Latin-American support letters" (PDF).
  14. ^ "International support letters, including among others 2 Nobel prize winners" (PDF).
  15. ^ "Laboratorio subterráneo ANDES". Argentina.gob.ar. April 26, 2018.
  16. ^ "CONICYT apoya creación del laboratorio subterráneo ANDES | CONICYT". www.conicyt.cl.
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