Classical black hole scattering from a worldline quantum field theory

Classical observables from coherent-spin amplitudes, Classical gravitational scattering from a gauge-invariant double copy, Radiative classical gravitational observables at \(\mathcal{O} (G^3)\) from scattering amplitudes, Radiation reaction for spinning black-hole scattering, Self-force effects in post-Minkowskian scattering, Scattering amplitudes and \(N\)-body post-Minkowskian Hamiltonians in general relativity and beyond, Scrambling and entangling spinning particles, Spin Supplementary condition in quantum field theory: covariant SSC and physical state projection, Machine learning post-Minkowskian integrals, Self-dual black holes in celestial holography, Classical observables from the exponential representation of the gravitational S-matrix, Wave scattering event shapes at high energies, The 2PM Hamiltonian for binary Kerr to quartic in spin, Angular momentum of zero-frequency gravitons, Bootstrapping the relativistic two-body problem, The relation between KMOC and worldline formalisms for classical gravity, Classical off-shell currents, Recursion in the classical limit and the neutron-star Compton amplitude, Classical vs quantum eikonal scattering and its causal structure, The Reissner-Nordström-Tangherlini solution from scattering amplitudes of charged scalars, Quantization conditions and the double copy, Gravitational partial-wave absorption from scattering amplitudes, NLO deflections for spinning particles and Kerr black holes, All things retarded: radiation-reaction in worldline quantum field theory, Black holes in Klein space, One-loop gravitational bremsstrahlung and waveforms from a heavy-mass effective field theory, Classical observables from partial wave amplitudes, Inelastic exponentiation and classical gravitational scattering at one loop, Large gauge effects and the structure of amplitudes, Scattering in black hole backgrounds and higher-spin amplitudes. I., Bethe-Salpeter equation for classical gravitational bound states, Loop-level double-copy for massive fermions in the fundamental, Classical double copy of spinning worldline quantum field theory, Classical gravitational observables from the eikonal operator, Classical limit of higher-spin string amplitudes, Classical spin gravitational Compton scattering, Gravitoelectric dynamical tides at second post-Newtonian order, Unified treatment of null and spatial infinity. IV: Angular momentum at null and spatial infinity, Radiation-reaction in the effective field theory approach to post-Minkowskian dynamics, Radiation reaction from soft theorems, The amplitude for classical gravitational scattering at third post-Minkowskian order, The eikonal approach to gravitational scattering and radiation at \(\mathcal{O} (G^3)\), Tidal effects for spinning particles, A worldsheet for Kerr, Scattering of gravitons and spinning massive states from compact numerators, Light-ray operators, detectors and gravitational event shapes, Leading nonlinear tidal effects and scattering amplitudes, Classical solutions and their double copy in split signature, Radiated momentum in the post-Minkowskian worldline approach via reverse unitarity, Worldline description of a bi-adjoint scalar and the zeroth copy, Light bending from eikonal in worldline quantum field theory, Post-Newtonian waveforms from spinning scattering amplitudes, Anyons and the double copy, SUSY in the sky with gravitons, Yang-Mills observables: from KMOC to eikonal through EFT, Worldline master formulas for the dressed electron propagator. II: On-shell amplitudes, The radial action from probe amplitudes to all orders, Classical and quantum gravitational scattering with generalized Wilson lines, Graviton particle statistics and coherent states from classical scattering amplitudes, From boundary data to bound states. III: Radiative effects, Amplitudes from Coulomb to Kerr-Taub-NUT, NS-NS spacetimes from amplitudes, The eikonal operator at arbitrary velocities. I: The soft-radiation limit, The SAGEX review on scattering amplitudes Chapter 13: Post-Minkowskian expansion from scattering amplitudes, The SAGEX review on scattering amplitudes Chapter 14: Classical gravity from scattering amplitudes

• xPerm

• On-shell techniques and universal results in quantum gravity
• Black holes and the double copy
• The effective field theorist's approach to gravitational dynamics
• Worldline formalism in a gravitational background
• xPerm: fast index canonicalization for tensor computer algebra
• Progress in effective field theory approach to the binary inspiral problem
• On-shell heavy particle effective theories
• A worldline theory for supergravity
• Classical gravitational scattering at \(\mathcal{O} (G^3)\) from Feynman diagrams
• Proof of the classical soft graviton theorem in \(D = 4\)
• Universality of ultra-relativistic gravitational scattering
• Testing binary dynamics in gravity at the sixth post-Newtonian level
• Towers of gravitational theories
• The post-Newtonian approximation for relativistic compact binaries
• Gravitational radiation from color-kinematics duality
• Classical and quantum results on logarithmic terms in the soft theorem in four dimensions
• Amplitudes, observables, and classical scattering
• Inelastic black hole scattering from charged scalar amplitudes
• Kerr black holes as elementary particles
• From boundary data to bound states
• From boundary data to bound states. II: Scattering angle to dynamical invariants (with twist)
• A tale of two exponentiations in \(\mathcal{N} = 8\) supergravity at subleading level
• Compton-like scattering of a scalar particle with \(N\) photons and one graviton
• Fourth post-Newtonian Hamiltonian dynamics of two-body systems from an effective field theory approach
• Black hole binary dynamics from the double copy and effective theory
• Heavy black hole effective theory
• One-loop quantum gravity from the \(N\) particle 4 spinning
• Observables and amplitudes for spinning particles and black holes
• Scattering of spinning black holes from exponentiated soft factors
• The classical double copy for Taub-NUT spacetime
• Classical space-times from the S-matrix
• Spinning gravitating objects in the effective field theory in the post-Newtonian scheme
• Extremal black hole scattering at \(\mathcal{O} (G^3)\): graviton dominance, eikonal exponentiation, and differential equations
• Tidal effects in quantum field theory
• Gravity as a double copy of gauge theory: from amplitudes to black holes
• Next-to-leading-order spin–orbit effects in the motion of inspiralling compact binaries
• Scattering amplitudes: the most perfect microscopic structures in the universe
• Relativistic Closed-Form Hamiltonian for Many-Body Gravitating Systems in the Post-Minkowskian Approximation
• Scattering of two spinning black holes in post-Minkowskian gravity, to all orders in spin, and effective-one-body mappings
• Non-relativistic gravitation: from Newton to Einstein and back
• The third post-Newtonian gravitational wave polarizations and associated spherical harmonic modes for inspiralling compact binaries in quasi-circular orbits
• Effective field theory methods to model compact binaries
• Dynamical Theory in Curved Spaces. I. A Review of the Classical and Quantum Action Principles
• Mathematical Formulation of the Quantum Theory of Electromagnetic Interaction
• Gravitational radiation from post-Newtonian sources and inspiralling compact binaries
• Dimensional regularization of the path integral in curved space on an infinite time interval
• Perturbative quantum field theory in the string-inspired formalism