Code to calculate the properties of a stable massive particle in a generic model. First developed to compute the relic density of a stable massive particle, the code also computes the rates for direct and indirect detection rates of dark matter. It is assumed that a discrete symmetry like R-parity ensures the stability of the lightest odd particle. All annihilation and coannihilation channels are included in the computation of the relic density. Specific examples of this general approach include the MSSM and various extensions. Extensions to other models can be implemented by the user. The New Physics model first requires to write a new CalcHEP model file, a package for the automatic generation of squared matrix elements. This can be done through LanHEP. Once this is done, all annihilation and coannihilation channels are included automatically in any model. The cross-sections for both spin dependent and spin independent interactions of WIMPS on protons are computed automatically as well as the rates for WIMP scattering on nuclei in a large detector. Annihilation cross-sections of the dark matter candidate at zero velocity, relevant for indirect detection of dark matter, are also computed automatically. The propagation of charged particles in the Galactic halo is handled with a new module.

References in zbMATH (referenced in 33 articles , 1 standard article )

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  1. Li, Jinmian; Thomas, Anthony W.: Bottom quark contribution to spin-dependent dark matter detection (2016)
  2. Allanach, B.C.; Bednyakov, A.; Ruiz de Austri, R.: Higher order corrections and unification in the minimal supersymmetric standard model: SOFTSUSY3.5 (2015)
  3. Allanach, B.C.; George, Damien P.; Nachman, Benjamin: Investigating multiple solutions in the constrained minimal supersymmetric standard model (2014)
  4. Falkowski, Adam; Hochberg, Yonit; Ruderman, Joshua T.: Displaced vertices from X-ray lines (2014)
  5. Arbey, Alexandre; Cacciapaglia, Giacomo; Deandrea, Aldo; Kubik, Bogna: Dark matter in a twisted bottle (2013)
  6. Belyaev, Alexander; Christensen, Neil D.; Pukhov, Alexander: CalcHEP 3.4 for collider physics within and beyond the standard model (2013)
  7. Hasenkamp, Jasper; Winkler, Martin Wolfgang: NMSSM with gravitino dark matter to be tested at LHC (2013)
  8. Heeck, Julian; Zhang, He: Exotic charges, multicomponent dark matter and light sterile neutrinos (2013)
  9. Liu, Chun; Lu, Jia-Shu: Dark matter and gauge coupling unification in a supersymmetry model with vector-like matter (2013)
  10. Arbeláez, C.; Hirsch, M.; Reichert, L.: Supersymmetric mass spectra and the seesaw type-I scale (2012)
  11. Cerdeño, David G.; Delahaye, Timur; Lavalle, Julien: Cosmic-ray antiproton constraints on light singlino-like dark matter candidates (2012)
  12. Ellwanger, Ulrich; Hugonie, Cyril: Higgs bosons near 125 GeVv in the NMSSM with constraints at the GUT scale (2012)
  13. Feldman, Daniel; Perez, Pavel Fileviez; Nath, Pran: R-parity conservation via the Stueckelberg mechanism: LHC and dark matter signals (2012)
  14. Covi, Laura; Olechowski, Marek; Pokorski, Stefan; Turzyński, Krzysztof; Wells, James D.: Supersymmetric mass spectra for gravitino dark matter with a high reheating temperature (2011)
  15. Hall, Jonathan P.; King, Stephen F.: Bino dark matter and big bang nucleosynthesis in the constrained $E_6$ SSM with massless inert singlinos (2011)
  16. Kawase, Hidetoshi: Light neutralino dark matter scenario in supersymmetric four-Higgs doublet model (2011)
  17. Arbey, A.; Mahmoudi, F.: SuperIso Relic: a program for calculating relic density and flavor physics observables in supersymmetry (2010)
  18. Bhattacharyya, Gautam; Ray, Tirtha Sankar: A phenomenological study of 5d supersymmetry (2010)
  19. Brümmer, F.; Fichet, S.; Kraml, S.; Singh, R.K.: On SUSY GUTs with a degenerate Higgs mass matrix (2010)
  20. Cao, Junjie; Heng, Zhaoxia; Yang, Jin Min: Rare $Z$-decay into light CP-odd Higgs bosons: a comparative study in different new physics models (2010)

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