Chapter IV: A recipe for echoes from exotic compact objects

4.10 Appendix: Point Particle Waveforms

In this appendix we provide Green’s functions solutions for the scalar fieldψ_BH in the BH spacetime, specialized to point particle sources for observers at future null infinityI⁺ and the future horizonH⁺.

Green’s Function solution

The boundary conditions forψ_BH in Eq. (4.19) select the retarded solution to the Klein-Gordon equation

ψ_BH(x,t)= ∫ ∞

−∞

dt⁰

∫ ∞

−∞

dx⁰S(x,t)g_BH(x,x⁰,t−t⁰),

S(x,t)= −r f(r)ρ`m(x,t), (4.68) constructed from the retarded (biscalar) Green’s function g_BH(x,x⁰, τ) and the spherical harmonic components of the scalar charge density4. The retarded Green’s function obeysg_BH(x,x⁰,t−t⁰)= 0 whent−t⁰ < |x−x⁰|and the differential equation

∂²g_BH

∂x² − ∂²g_BH

∂t² − f(r)V(r)g_BH = δ(t−t⁰)δ(x− x⁰). (4.69) We are interested in the waveforms on either the BH horizon or at asymptotic infinity.

This leads us to consider the asymptotic Green’s functions g_BH ∼











g_H(x⁰,v−v⁰), asx → −∞, vfixed,

g∞(x⁰,u−u⁰), asx → ∞, ufixed, (4.70)

4Note thatS,ψ_BH,g_BHand all variants of them which appear in this appendix have(`,m)indices which we suppress for brevity.

which describe the response on the horizon and at infinity, respectively.

We also need the appropriate source functions, specialized to ingoing coordinates (v,x)and outgoing coordinates(u,x). The scalar charge density of a point particle of scalar chargeq, following the trajectoryx_p^µ(τ)is

ρ(x^µ)= q

∫

dτδ⁽⁴⁾(x^µ−x_p^µ(τ))

√−g , (4.71)

Resolving into spherical harmonics ρ=Í

`m ρ`mY`m, re-parameterizing by advanced time, and writing the result in ingoing coordinates leads to

S(x,v)= Sˆin(v)δ(x− xp), Sˆ_in(v)= −qY_`m^∗ (θ_p, φ_p)

r_p(dv_p/dτ) , (4.72)

where the trajectory is evaluated atv. Similarly, if we re-parameterize by the retarded time, and write the result in outgoing coordinates, the source is

S(x,u)= Sˆ_out(u)δ(x−x_p), Sˆout(u)= −qY_`m^∗ (θ_p, φ_p)

r_p(du_p/dτ) , (4.73)

where the trajectory is evaluated at the retarded timeu.

With these definitions, the horizon waveform is ψ_BH^H (v)= ∫ ∞

−∞

dx⁰

∫ ∞

−∞

dv⁰S(x⁰,v⁰)g_H(x⁰,v−v⁰)

= ∫ ∞

−∞

dv⁰Sˆin(v⁰)g_H(xp(v⁰),v−v⁰). (4.74) For a particle that crosses the horizon at an advance timev= v_H, this becomes, using the causal property of the retarded Green’s function,

ψ_BH^H (v)=













∫ v

−∞

dv⁰Sˆ_in(v⁰)g_H(x_p(v⁰),v−v⁰), v < v_H,

∫ vH

−∞

dv⁰Sˆ_in(v⁰)g_H(x_p(v⁰),v−v⁰), v ≥ v_H. (4.75) Meanwhile, the asymptotic waveform is given by

ψ_BH^∞ (u)= ∫ ∞

−∞

dx⁰

∫ ∞

−∞

du⁰S(x⁰,u⁰)g∞(x⁰,u−u⁰)

= ∫ u

−∞

du⁰Sˆ_out(u⁰)g∞(x_p(u⁰),u−u⁰). (4.76)

where we have again used causality to truncate the upper limit of the integration tou.

In this paper, we extensively study the radiation produced by a test charge on the ISCO plunge orbit. Such a particle asymptotes to the ISCO radius r = 6M as t → −∞and has a specific energyEISCO= 2√

2/3 and a specific angular momentum ofL_ISCO =√

12M. To calculate the waveformsψ_BH^∞ andψ_BH^H we rely on Eqs. (4.75) and (4.76) with analytic expressions for the trajectory found in [60], and a Green’s function that we compute numerically using a characteristic code detailed in Sec.4.10.

Characteristic Initial Value Problem for the Green’s function

We obtain the retarded Green’s functiong_BHfor the scalar field in the BH spacetime as the solution of a characteristic initial value problem. In null coordinates(v,u), Eq. (4.69) forg_BH(v,v⁰,u,u⁰)takes the form

∂²g_BH

∂v∂u + f V

4 g_BH = −1

2δ(∆u)δ(∆v) (4.77)

where∆u=u−u⁰,∆v = v−v⁰. Causality motivates us to look for a distributional solution

g_BH(v,v⁰,u,u⁰)= gˆ(v,v⁰,u,u⁰)θ(∆u)θ(∆v), (4.78) where ˆg is a smooth function defined in the future light cone of the source point (v⁰,u⁰). Substitution of the ansatz (4.78) in (4.77) yields

δ(∆u)δ(∆v)gˆ+θ(∆u)δ(∆v)∂gˆ

∂u +θ(∆v)δ(∆u)∂gˆ

∂v +θ(∆u)θ(∆v)

∂²gˆ

∂v∂u + f V 4 gˆ

= −1

2δ(∆u)δ(∆v) (4.79) We now equate terms of equal singularity strength. The first term on the LHS balances the RHS if we demand [g] ≡ˆ g(v⁰,v⁰,u⁰,u⁰) = −1/2. The second term, which is only nonzero alongv =v⁰, vanishes if we demand ∂_ugˆ|_v=v0 =0, which can be integrated to yield ˆg|_v=v⁰ =−1/2. Likewise, setting the third term to zero yields gˆ|_u=u⁰ =−1/2. Finally, the fourth term vanishes if ˆgsatisfies the homogeneous wave equation equation

∂²gˆ

∂v∂u + f V

4 gˆ = 0 (4.80)

in the forward light cone of source point.

Equation (4.80), together with the initial data ˆg=−1/2 posed on the future part of the null cone formed by the raysu= u⁰and v = v⁰, is a characteristic initial value problem forg_BH. We solve this numerically using a characteristic code described in Sec.4.10.

Characteristic Code

We numerically compute ˆg_BH using a finite-difference characteristic code based on the method of Price and Lousto [67]. For this, we fix a source point(v⁰,u⁰)and solve the homogeneous wave equation (4.80) obeyed by ˆg(v,u). We discretize the field point coordinates(v,u)onto a rectangular grid with nodes spaced by 2h.

A standard computational cell centered on the pointC= (v,u)is shown in Fig.4.24.

Referring to the figure, given the dataψS,ψW, andψE on the bottom three corners of a computational cell, the value on top cornerψ_N can be obtained with the stepping algorithm

ψ_N =−ψ_S+(1+2W_Ch²)(ψ_E +ψ_W) (4.81) W_C = −f V

4 C

. (4.82)

This algorithm can be derived by integrating the homogeneous wave equation (4.80) over a computational cell withO(h⁴)accuracy. Our code inputs initial data on the future part of the light cone formed by the raysv =v⁰andu=u⁰and is second order convergent. We generate values forψon the remaining nodes of the grid using the stepping algorithm (4.81).

To obtaing∞(x⁰,∆u), we further fix∆uand use our characteristic code to obtaing_BH as a function of field point radiusr. Using the fact that the field has an expansion in powers of 1/r, we then extrapolate the field to future null infinity using Richardson extrapolation.

To extractg_H(x⁰,∆v), we use our characteristic code to obtaing_BHevaluated on the rayu = constant that is closest to the horizon in our computational domain. For early advanced time∆v, this ray is buried deep in the near horizon region, and we approximate g_H(x⁰,∆v) as g_BH evaluated on this ray. We check that this scheme converges as we move the extraction rayu =constant towardsH⁺.

We perform these calculations for radii between r⁰−2M = 1.7×10⁻⁵ and r⁰ = rISCO = 6M with ∆x⁰ = 1. We then interpolate between these values to obtain g_H(x⁰,∆v)andg∞(x⁰,∆u)that we use in the calculations presented in this paper.

Windowing and Frequency Domain Waveforms

Waveforms from physically relevant orbits are finite in duration. The waveforms produced by the exact ISCO plunge orbit are not; at late times, the waveforms ringdown to zero, but at arbitrarily early times they have an oscillation atω= mΩ_ISCO due to the test charge orbiting on the ISCO.

Hence, for all calculations in this paper we consider the echoes produced by a windowed horizon waveform. More precisely we apply a one-sided version of the Planck-Taper [68] window function to the exact ISCO plunge horizon waveforms:

σ_T(t,t₁,n)=

















0, t ≤ t1

1

1+e^z, t1 < t < t2

1, t ≥ t2

, (4.83)

wheret₁is free parameter indicating when the window starts,t₂=t₁+2aπ/Ω_ISCO with aafree parameter, and z is a function that goes from∞att₁to−∞att₂,

z = t₂−t₁

t−t₁ + t₂−t₁

t−t₂ . (4.84)

We choose parameters that leave 3 oscillations at early times nearω ≈ mΩISCOand smoothly turn on over the course of two oscillations.

We obtain the horizon waveform Z_BH^H in the frequency domain by numerically performing the inverse Fourier transform of the time domain waveformψ_BH^H .