Landau Singularities Revisited: Computational Algebraic Geometry for Feynman Integrals
Claudia Fevola, Sebastian Mizera, Simon Telen
Abstract
We reformulate the analysis of singularities of Feynman integrals in a way that can be practically applied to perturbative computations in the standard model in dimensional regularization. After highlighting issues in the textbook treatment of Landau singularities, we develop an algorithm for classifying and computing them using techniques from computational algebraic geometry. We introduce an algebraic variety called the principal Landau determinant, which captures the singularities even in the presence of massless particles or UV/IR divergences. We illustrate this for 114 example diagrams, including a cutting-edge 2-loop 5-point nonplanar QCD process with multiple mass scales.
Topics & Concepts
Gravitational singularityFeynman diagramRegularization (linguistics)Massless particleComputationDimensional regularizationAlgebraic numberAlgebraic geometrySingularityPhysicsAlgebra over a fieldMathematicsTheoretical physicsMathematical physicsGeometryPure mathematicsComputer scienceMathematical analysisAlgorithmQuantum mechanicsRenormalizationArtificial intelligenceBlack Holes and Theoretical PhysicsPolynomial and algebraic computationParticle physics theoretical and experimental studies