Twisted soft photon hair implants on Black Holes

The Hawking-Perry-Strominger (HPS) work [1] states a new controversial idea about the black hole (BH) information paradox [2-5] where BHs maximally entropize and encode information in their event horizon area [6,7], with no"hair"were thought to reveal information outside but angular momentum, mass and electric charge only [8,9] in a unique quantum gravity (QG) vacuum state. This new idea invokes new conservation laws involving gravitation and electromagnetism [10,11], to generate different QG vacua and preserve more information in hair implants. In the context of black holes and the HPS proposal we find that BH photon hair implants can be spatially shaped ad hoc and encode structured and densely organized information on the event horizon involving novel aspect in the discussion a particular aspect of EM fields, namely the spatial information of the field associated to its orbital angular momentum. BHs can have"curly", twisted, soft-hair implants with vorticity where structured information is holographically encoded in the event horizon in an organized way.

The Hawking-Perry-Strominger (HPS) work [1] states a new controversial idea about the black hole (BH) information paradox [2][3][4][5] where BHs maximally entropize and encode information in their event horizon area [6,7], with no "hair" thought to reveal information outside but angular momentum, mass and electric charge only [8,9] in a unique quantum gravity (QG) vacuum state. This new idea invokes new conservation laws involving gravitation and electromagnetism [10,11], to generate different QG vacua and preserve more information in soft photon/graviton hair implants. In the context of black holes and the HPS proposal we find that BH photon hair implants can be spatially shaped ad hoc and encode structured and densely organized information on the event horizon involving novel aspect in the discussion a particular aspect of EM fields, namely the spatial information of the field associated to its orbital angular momentum. BHs can have "curly", twisted, soft-hair implants with vorticity where structured information is holographically encoded in an organized way in the event horizon.
The BH information paradox, information loss and the nohair theorem were mainly based on the supposed unicity of the quantum gravity vacuum that revealed outside only the macroscopical quantities angular momentum, mass and electric charge. HPS changed this scenario with new results in GR and QG, new invariants and symmetries such as supertranslations [10,12] and superrotations [13] and observable effects [14][15][16]. Anyway, in our knowledge, it is still an open question whether HPS soft hair can account for the Bekenstein-Hawking entropy and capture the information of black-hole microstates.
When one includes the set of conserved quantities of the electromagnetic (EM) field too [11,[17][18][19], EM analogs of the supertranslation charges are introduced as a generalization of the electric charge conservation principle. Also in this case HPS suggest that the unicity of the QG vacuum state is invalidated because of the creation or annihilation of actual physical quantum zero-energy state particles, soft photons. When EM phenomena act on BHs, BHs are expected to carry a soft electric hair implant, made with soft photons that store information of any process in the event horizon, with different QG vacuum states and different BHs with identical macroscopical parameters.
Consider the metric obtained from the collapse of neutral matter at advanced time v = 0, written in terms of the round metric γ zz on the unit sphere S 2 in complex coordinates (v, r, z,z), where v = t + r and r the radial coordinate, z = tan(φ /2) exp(−iθ ) and z = 1/z, M the BH mass and Θ = 0 before the shell at v = 0 and Θ = 1 af-ter the shell at v = 0. The complete information is stored in the S 2 future boundary of the horizon, H + of the BH horizon, H, an holographic plate made of quantum pixels whose excitation corresponds to the creation of a spatially localized soft photon on the event horizon with polarization vector ε jm (σ ) ∝ ∂ z Y jm (z,z) when, for example, a null shock wave with divergence-free charge current carrying an angular momentum eigenstate j fall into the BH at v = v 0 > 0, generating a multipolar radiation field where F (0) indicates the photon term of the field and Y jm are spherical harmonics [1]. A generic non-trivial asymptotic supertranslation field given by an arbitrary combination of spherical harmonics modifies the spacetime in Eq 1 becomes [15] C are the components of the supertranslation field C, C 0,0 is the lowest spherical harmonic mode of C with the auxiliary quantities U(θ , φ ) ≡ , t s = t + C (0,0) and ρ s = (ρ − C + C (0,0) ) 2 + D z CD z C. The modified field is revealed by experiments that take into account the effects of the Typeset by REVT E X whole sphere around the BH such as an array of rulers around the central object or by deviations from closed null geodesics in strong lensing effects. The simple bending of light of a distant star in a finite solid angular range outside of the supertranslation horizon remains unaffected by supertranslations.

ORGANIZED STRUCTURES OF SOFT PHOTONS
Consider the conserved quantity total angular momentum J of a particle. This can be decomposed in spin angular momentum (SAM), S, and orbital angular momentum (OAM), L. Whilst the splitting of the total angular momentum in two observables, J = L + S, is valid for massive particles, it has not always a precise physical meaning for the EM field and for the photon; in any case SAM and OAM are auxiliary concepts that describe the photon wavefunction properties with respect to rotations and OAM gives the order of the spherical functions involved in the radiation field together with the parity of the photon state, following precise rules for the composition of L and S from the classical field formulation down to the single photon level, where intensity corresponds to the probability of generating a photon in a specific region of spacetime [22][23][24]. EM-OAM is currently widely applied in many research fields [30] and technology: quantum and classical communications [25][26][27], astrophysics [28] and nanotechnology. Prototype examples of fields carrying specific SAM and OAM eigenvalues are Laguerre-Gaussian (LG) modes that provide an orthogonal fundamental basis to expand any OAM field. They represent cylindrically symmetric structured EM beams that carry lh OAM per photon relative to their symmetry axis with amplitude, in cylindrical coordinates (r, z, ϕ), where z R is the Rayleigh range of the beam, w(z) the beam waist, L l m (x) the associated Laguerre polynomial and R(z) the curvature radius. The azimuthal and radial indices l and m give the OAM and the number of radial nodes of the associated intensity profile, respectively [18,20].
All fields carry energy, linear momentum and orbital angular momentum [29]. The EM field is a vector field and therefore carries both spin and orbital angular momentum. These observables are emitted in the form of volumetric densities [19] and can therefore not be measured at a single point but have to be integrated/averaged over a finite (possibly very small) volume, for instance the volume occupied by a sensor.
Any generic field can be written as a superposition of LG modes and decomposed into multipolar fields, spherical harmonics and in terms of paraxial fields that depend only on the wavelength [31]. These properties remain valid down to the single photon level. For a simple LG beam with m = 0 the vector potential A, in terms of multipolar superpositions of circularly polarized plane waves, is and where the vector potential A is decomposed in the magnetic (m) and electric (e) terms, k is the wavenumber, w 0 the waist of the associated Gaussian beam and L p l is the associated Laguerre polynomial. The field is composed of multipolar solutions with different total angular momenta, but with the same projection of the angular momentum in the direction z, which is +1 or −1 depending on the polarization of the field and ( j, m = l + p), p represents the circular polarization operator and k the wavevector.
LG modes with OAM l and polarization p present multipolar modes with a fixed component m = l + p along z of the angular momentum [32].
Superpositions of multipolar sources from an arbitrary distribution of charges and currents j * v in a finite source volume V ′ can generate spatially-structured EM fields that carry a well-precise combination of spherical harmonics and OAM with respect to a given point in spacetime. We consider fields that are characterized by precise phase structures in space and OAM values, independently from the radiating system, as angular momentum and its volumetric density is a property of the field emitted by every radiation, not the property of the radiator itself [18,20,21,33]. We find, numerically and from simple analytic considerations that when these currents fall into the static BH, they not only produce structured fields and then supertranslation states modifying the spacetime, but also induce local spatial structures in the soft photon hair implant in a neighborhood of the BH event horizon.
In the numerical simulations we consider, for the sake of simplicity, a distribution of dipolar currents in a set of azimuthally-dephased radiating dipoles on a circle with radius r c and center O c that produce a radiating EM field with a welldefined OAM value l. The circle is orthogonal to the direction r ⊥ connecting 0 c and the center of the BH. We calculate the spatial distribution of the soft photon implant on the event horizon of the BH from Eqs. 2 and 3 in a neighborhood of the point O. We assume that the BH radius, r * , is r * ≫ r c and approximate the metrics near the horizon r ∼ 2MG in a small angular region θ = 0, where a small neighborhood of an observer can be described in first approximation as a Rindler coordinate system and a set of observers on the direction r ⊥ identify, at a first approximation, a class of Rindler observers. For these observers and with the approximations here adopted, the radiating field from the currents is not significantly affected by the free-fall radiating process [34,35] neglected in first approximation. The soft photon hair implant is here induced by four falling dipolar currents distributed on a circle with radius r c = λ /10 have a spatial extension much smaller than the wavelength emitted, d = λ /100 and are azimuthally dephased of δ ϕ = π/4 to generate an EM field with l = 1 OAM value calculated with respect to the center of symmetry of the dipole array with linear polarization across the x 1 = x axis of the new accelerated local frame (x i ). The upper panels of Fig. 1 show the probability of emission of a photon in a superposition of OAM states and the spatial phase distribution of the EM field in a window of 25λ × 25λ . The point of observation is located at 300 wavelengths distance in the direction r ⊥ . The lower panels show the probability of associating a soft photon in the soft photon hair implant and the corresponding phase profile in the neighborhood of the event horizon, after neglecting the backreaction of the shell and of the EM field on the geometry. All numerical simulations were performed with Matlab and NEC (Numerical Electromagnetics Code) [36][37][38] that morphed the standard NEC input and output into the correct shape of the static spacetime geometry here considered through a geometrical optics transformation from analog gravity [39,40].
Owing to the realistic simulation of the four dipoles, the spiral spectrum of the electric field component along x generated by the dipoles clearly shows a complex structure of OAM components where the dominant term is l = 1 (Fig. 2), as in the spiral spectra [41] of the EM field emitted by the dipoles and that of the corresponding soft photon field. Interestingly, the numerical results show that the spiral spectrum of the EM field generated by the four falling dipoles, peaked at l = +1, has similarities to that of the soft photon hair implant but for a translation of the peak to l = +2, apparently preserving the spatial information of the real photon field. Naively, this effect of spiral spectrum shift finds an interesting parallelism with the optical experiments involving OAM beams: the soft photon hair implant F soft behaves as if it were the product of the initial radiation field of the current j * v after crossing a singlebifurcation fork hologram that shifts the spiral spectrum of one OAM unit [20].
From an analytical point of view, the shift of the spiral spectrum can be explained as follows. Consider a set of charges that radiate an EM field described by a single ideal LG mode with topological charge l as in Eq. 4. This carries a finite value of polarization and OAM, with a precise spatial structure in intensity and phase. The decomposition in spherical modes of this field puts in immediate evidence the angular momentum properties through the eigenfunctions of the angular momentum operators, being Y jm the eigenfunction of the operators J 2 and J z , where z in this case is r ⊥ . By applying Eq. 3 and the derivation rules in the Riemann sphere [42,43], after some algebra, being d dx L l k = −L l+1 k−1 , where l and k are two arbitrary indexes, it is clear that the resulting soft photon field presents terms with increased OAM value of exactly one unit, l + 1, with respect to the spherical harmonic distribution of the field emitted by the charges of Eqs. 5 and 6, confirming our numerical findings in the spiral spectra.
All information regarding the spatial distribution of currents are thus encoded on the event horizon and written in the modified metric of Eq. 4. In this way we provide a novel physical interpretation to the lush head of BHs "soft hair" that have a modified spacetime with an organized spatial structure on the event horizon, like for "real" photons.
Conclusions. Following HPS, Black holes encode the spatial information of infalling currents generating OAM beams in twisted hair implants that present a local a spatial structure on the event horizon. All information is encoded in a new spacetime with supertranslation fields. We have shown that we can use the symmetries of EM fields to generate local spatial structures on soft photon implants encoding structured and densely organized information on the event horizon. Thus, BHs can have "curly", twisted, structured soft-hair implants where information can be written onto the horizon in an organized way. This procedure can be extended to more complex field configurations expressed in terms of conserved quantities and symmetries inducing additional supertranslation fields. Interestingly, a coherent and organized superposition of these quantum states corresponds to an organized quantum bits string of information encoded into the event horizon as in an holographic projection.
Multi-dimensional strings of qbits carrying ordered and structured information can excite pixels in an ordered way, creating structures on the event horizon can be built from the invariants and symmetries of the gravitational and EM fields, in a sort of quantum alphabet. This might represent a novel way to input controlled information on BHs that will evolve according to their computational complexity. Complexity can be encoded through a coherent [44] superposition and combination of states as a string of a quantum computer [45] where, possibly, a non-thermal spectrum characterizes the passage from macroscopic to microscopic information. This information is thought to be processed by the BH interior as in a quantum computer obeying the rules of quantum computation and complexity; BHs are supposed to be the fastest computers to process complexity in the most optimal way [46][47][48], encoding information in the structure of spacetime modifying it with the supertranslation fields. Any BH would resemble a quantum computer with high coherence and this information encoded so far could be located by the soft-hair implant in a neighborhood of the event horizon and in the modified spacetime. In any case, because of Shaw theorem that connects information and volume in the phases, any physical system must belong to one of these three classes: systems that preserve information, information dissipating systems and polynomial/exponential information amplifiers [49] that for BHs seems to be still an open debate.