From boundary data to bound states. Part II. Scattering angle to dynamical invariants (with twist)

Kälin, Gregor; Porto, Rafael A.

doi:10.1007/jhep02(2020)120

Cited by 187 publications

(273 citation statements)

References 40 publications

Supporting

Mentioning

261

Contrasting

Order By: Relevance

“…(6.26) This result is obtained by analytically continuing the quasi-Keplerian representation of the hyperbolic motion used above [79] back to the elliptic-motion case (expressing all quantities in terms of γ and j and analytically continuing γ from γ hyperbolic > 1 to γ elliptic < 1). The result (6.26) is consistent with the analytic-continuation link between the scattering angle and the periastron precession [37], as is easily seen in view of the link [52] used above between the tail contribution to the scattering angle and the time integral of the gravitational-wave energy loss. The functional structure of ∆E elliptic GW (γ, j) is much simpler than that of ∆E hyperbolic GW (γ, j).…”

supporting

confidence: 82%

Sixth post-Newtonian local-in-time dynamics of binary systems

2020

View full text Add to dashboard Cite

We complete our previous derivation, at the sixth post-Newtonian (6PN) accuracy, of the localin-time dynamics of a gravitationally interacting two-body system by giving two gauge-invariant characterizations of its complementary nonlocal-in-time dynamics. On the one hand, we compute the nonlocal part of the scattering angle for hyberboliclike motions; and, on the other hand, we compute the nonlocal part of the averaged (Delaunay) Hamiltonian for ellipticlike motions. The former is computed as a large-angular-momentum expansion (given here to next-to-next-to-leading order), while the latter is given as a small-eccentricity expansion (given here to the tenth order). We note the appearance of ζ(3) in the nonlocal part of the scattering angle. The averaged Hamiltonian for ellipticlike motions then yields two more gauge-invariant observables: the energy and the periastron precession as functions of orbital frequencies. We point out the existence of a hidden simplicity in the mass-ratio dependence of the gravitational-wave energy loss of a two-body system.

show abstract

supporting

confidence: 82%

Sixth post-Newtonian local-in-time dynamics of binary systems

2020

View full text Add to dashboard Cite

show abstract

“…Two pieces of evidence were provided in support of this conjecture: first, the absence of precession for the full O(G 2 ) dynamics, which directly follows from an analog of the "no-triangle" hypothesis [80][81][82][83][84][85] for massive scattering; and second, various all-orders-in-G calculations in the probe limit for different charge configurations. It is known that O(G 3 ) (or any odd power of G) corrections to the conservative dynamics cannot yield precession [86,87]. Instead we will use the scattering angle at O(G 3 ) to test this conjecture, and see that it deviates from the integrable Newtonian result at this order.…”

Section: Jhep11(2020)023mentioning

confidence: 93%

Extremal black hole scattering at $$ \mathcal{O} $$(G3): graviton dominance, eikonal exponentiation, and differential equations

Parra-Martinez¹,

Ruf

Zeng

2020

J. High Energ. Phys.

141

211

View full text Add to dashboard Cite

We use $$ \mathcal{N} $$ N = 8 supergravity as a toy model for understanding the dynamics of black hole binary systems via the scattering amplitudes approach. We compute the conservative part of the classical scattering angle of two extremal (half-BPS) black holes with minimal charge misalignment at $$ \mathcal{O} $$ O (G3) using the eikonal approximation and effective field theory, finding agreement between both methods. We construct the massive loop integrands by Kaluza-Klein reduction of the known D-dimensional massless integrands. To carry out integration we formulate a novel method for calculating the post-Minkowskian expansion with exact velocity dependence, by solving velocity differential equations for the Feynman integrals subject to modified boundary conditions that isolate conservative contributions from the potential region. Motivated by a recent result for universality in massless scattering, we compare the scattering angle to the result found by Bern et. al. in Einstein gravity and find that they coincide in the high-energy limit, suggesting graviton dominance at this order.

show abstract

“…These include the study of the effect of these new 3PM corrections on the binding energy of a binary inspiral in comparison with numerical relativity [92]. Currently, the 5PN term of the 3PM result has been verified [93], while other methods for EFT matching have also been devised [16][17][18][19]. The case of massless scattering has also received more recent attention with new computations in supergravity as well as in Einstein gravity [94][95][96][97].…”

Section: Jhep06(2020)144mentioning

confidence: 99%

“…The breakthrough observation of gravitational waves at LIGO/Virgo [1,2] has triggered immense interest in bridging developments from the modern scattering amplitudes program to the physics of gravitational waves. Building on past work on the inspiral problem based on graviton effective field theory (EFT) [3][4][5][6][7] and matching to a classical potential [8,9,[11][12][13], many developments have now emerged which exploit classic methods [14][15][16][17][18][19][20][21] as well as recent amplitudes advances [22][23][24][25] to investigate systems with [26][27][28][29][30][31][32][33][34][35][36][37][38] and without spin [39,40].…”

Section: Introductionmentioning

confidence: 99%

Classical gravitational scattering at $$ \mathcal{O} $$(G3) from Feynman diagrams

Cheung

Solon

2020

J. High Energ. Phys.

127

View full text Add to dashboard Cite

We perform a Feynman diagram calculation of the two-loop scattering amplitude for gravitationally interacting massive particles in the classical limit. Conveniently, we are able to sidestep the most taxing diagrams by exploiting the test-particle limit in which the system is fully characterized by a particle propagating in a Schwarzschild spacetime. We assume a general choice of graviton field basis and gauge fixing that contains as a subset the well-known deDonder gauge and its various cousins. As a highly nontrivial consistency check, all gauge parameters evaporate from the final answer. Moreover, our result exactly matches that of Bern et al. [39], here verified up to sixth post-Newtonian order while also reproducing the same unique velocity resummation at third post-Minkowksian order.

show abstract

From boundary data to bound states. Part II. Scattering angle to dynamical invariants (with twist)

Cited by 187 publications

References 40 publications

Sixth post-Newtonian local-in-time dynamics of binary systems

Sixth post-Newtonian local-in-time dynamics of binary systems

Extremal black hole scattering at $$ \mathcal{O} $$(G3): graviton dominance, eikonal exponentiation, and differential equations

Classical gravitational scattering at $$ \mathcal{O} $$(G3) from Feynman diagrams

Contact Info

Product

Resources

About