Feyn Calc - Computer-algebraic calculation of Feynman amplitudes. We present the computer program Feyn Calc for automatic algebraic calculation of Feynman amplitudes. The purpose of the package is to facilitate the process of calculating radiative corrections in renormalizable gauge theories. We have used the program to calculate tree level diagrams as well as 1- and 2-loop corrections in the Standard Model. The package is written in the computer algebra languages Macsyma as well as Mathematica allowing the necessary degree of generality.

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  1. Adam Bzowski: TripleK: A Mathematica package for evaluating triple-K integrals and conformal correlation functions (2020) arXiv
  2. Cheung, Clifford; Solon, Mikhail P.: Classical gravitational scattering at (\mathcalO(G^3)) from Feynman diagrams (2020)
  3. Fortes, E. C. F. S.; Machado, A. C. B.; Montaño, J.; Pleitez, V.: Lepton masses and mixing in a scotogenic model (2020)
  4. Huang, Wei-Chih; Ng, Kin-Wang; Yuan, Tzu-Chiang: Circularly polarized gamma rays in effective dark matter theory (2020)
  5. Jamshidi, S.; Sepahvand, R.; Dadfar, S.: Production of (\mathrmB_c) meson at NLO (2020)
  6. R.A. Kycia, P. Lebiedowicz, A. Szczurek: Decay: A Monte Carlo library for the decay of a particle with ROOT compatibility (2020) arXiv
  7. A. Dedes, M. Paraskevas, J. Rosiek, K. Suxho, L. Trifyllis: SmeftFR - Feynman rules generator for the Standard Model Effective Field Theory (2019) arXiv
  8. Dekens, Wouter; Stoffer, Peter: Low-energy effective field theory below the electroweak scale: matching at one loop (2019)
  9. Fiol, Bartomeu; Martínez-Montoya, Jairo; Fukelman, Alan Rios: Wilson loops in terms of color invariants (2019)
  10. Nefedov, M. A.: Computing one-loop corrections to effective vertices with two scales in the EFT for Multi-Regge processes in QCD (2019)
  11. Abe, Tomohiro; Hisano, Junji; Nagai, Ryo: Model independent evaluation of the Wilson coefficient of the Weinberg operator in QCD (2018)
  12. Nandan, Dhritiman; Plefka, Jan; Travaglini, Gabriele: All rational one-loop Einstein-Yang-Mills amplitudes at four points (2018)
  13. Berezhnoy, A. V.; Likhoded, A. K.; Onishchenko, A. I.; Poslavsky, S. V.: Next-to-leading order QCD corrections to paired (B_c) production in (e^+e^-) annihilation (2017)
  14. Chadou, I.; Mebarki, N.; Bekli, M. R.: Minimal NCSM direct photon production in proton-antiproton collisions (2017)
  15. Cyrol, Anton K.; Mitter, Mario; Strodthoff, Nils: FormTracer. A Mathematica tracing package using FORM (2017)
  16. Fael, M.; Greub, C.: Next-to-leading order prediction for the decay ( \mu\rightarrowe\kern0.22em \left(e^+e^-\right);\nu\kern0.2em \overline\nu) (2017)
  17. Shtabovenko, Vladyslav: FeynHelpers: connecting feyncalc to FIRE and package-X (2017)
  18. Boels, Rutger H.; Horst, Christoph: Perturbative quantum gravity in double field theory (2016)
  19. Conkey, Peter; Dubovsky, Sergei: Four loop scattering in the Nambu-Goto theory (2016)
  20. Mastrolia, Pierpaolo; Primo, Amedeo; Schubert, Ulrich; Torres Bobadilla, William J.: Off-shell currents and color-kinematics duality (2016)

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