Coherent perfect absorption in one-sided reflectionless media

Abstract

In optical experiments one-sided reflectionless (ORL) and coherent perfect absorption (CPA) are unusual scattering properties yet fascinating for their fundamental aspects and for their practical interest. Although these two concepts have so far remained separated from each other, we prove that the two phenomena are indeed strictly connected. We show that a CPA–ORL connection exists between pairs of points lying along lines close to each other in the 3D space-parameters of a realistic lossy atomic photonic crystal. The connection is expected to be a generic feature of wave scattering in non-Hermitian optical media encompassing, as a particular case, wave scattering in parity-time (PT) symmetric media.

Introduction

Scattering from complex potentials and the associated non-Hermitian Hamiltonians¹ are usually introduced to describe dissipation or decay processes in open systems. Likewise light wave propagation phenomena through media with complex susceptibilities are genuine realizations of scattering from localized non-Hermitian potentials and provide a clear illustration of how Hermitian and non-Hermitian processes differ from one another. The optical scattering matrix S fully governs the propagation of light and, in particular, one-sided reflectionless (ORL) scattering of light waves impinging from “one” direction^2,3,4,5,6 can be associated with a non-Hermitian degeneracy⁷ of the scattering matrix (also known as an exceptional point⁸). More intriguing phenomena appear, however, when coherent waves impinge on “both” sides of a complex potential⁹. Among them, coherent perfect absorption (CPA)¹⁰, which refers to complete absorption of both incident waves, is being extensively investigated^{11,12,13,14,15,16,17,18}. The interest in CPA stems not only for fundamental reasons^10,11,13, since it can be interpreted as the time-reversed counterpart of lasing and related to parity-time (PT) symmetry¹⁹, but also in view of its potential applications. Such efforts have spurred investigations and experiments in various areas that span, among others, absorption enhancement²⁰, perfect energy feeding into nanoscale systems²¹, intersubband polaritons²², slow light waveguides²³, graphene-based perfect absorbers^24,25,26,27, and Fano resonant plasmonic metasurfaces²⁸.

The concepts of one-sided reflectionless and coherent perfect absorption have remained so far separated from each other, probably because of the lack of suitable physical systems in which both features would be accessible. Here, we show how a lossy medium that exhibits ORL can in general also exhibit CPA. The connection is general, not restricted to PT symmetric media and could be easily observed in a realistic 1D lossy medium through smooth deformations of the system’s externally tunable parameters. We further argue how this connection, intrinsic to the structure of non-Hermitian degeneracies of scattering matrix S, can actually be extended to all points of a CPA-line. Such a line is a novel topological structure of non-Hermitian optical media predicted to occur next to a ORL-line. Although there has been a number of recent advances in each of these areas of research, particularly restricted to the case of PT symmetric media requiring a balance of loss and gain^{29,30,31,32,33,34}, one-sided reflectionless and coherent perfect absorption – taken together – may lead to a more complete understanding of non-Hermitian optics in a large class of materials where absorption plays a key role for applications. Photodetectors, photovoltaics and non-reciprocal optical devices just to mention a few instances. The connection we present here is fairly general, hinges on non-Hermitian scattering degeneracies with common notions from quantum mechanics and, though clearly relevant to optics in view of one-way mirrors, cloaks of invisibility and coherent laser absorbers, may well be relevant to unusual phenomena recently observed for acoustic waves^{35,36,37,38,39,40,41}.

ORL and CPA

The scattering properties of a 1D-medium are fully determined by the complex amplitudes t = t_L = t_R, r_L and r_R respectively for (reciprocal) transmission and reflection upon incidence from the left (L) or from the right (R). ORL means that r_L = 0 with r_R ≠ 0 (or vice versa). The CPA condition corresponds, instead, to a specific configuration of input beams, incident at the same time one from the left and one from the right with a definite phase relationship, which are completely absorbed by the sample. Thus, for this configuration of input beams, the output beams to the right and to the left are both vanishing. This means that the CPA input beams represent an eigenvector of the scattering matrix S with eigenvalue zero. As discussed below, the CPA condition can finally be stated as t² = r_Rr_L, i.e. det S = 0¹⁰ (see Eq. (3)).

Thus, the main focus of the work is how to connect in general the two conditions r_L = 0 (ORL) and t² = r_Rr_L (CPA) upon smooth deformations of medium’s external driving parameters. More specifically, for a lossy 1D-photonic crystal, the scattering properties near Bragg reflection can be described^5,4 by the following model susceptibility

with χ₀, , and w being non negative real parameters, a the crystal period and the phases {α, β} defined within the interval [0, π]. The real part of the spatially independent background susceptibility is ignored for simplicity as it plays no significant role, while its imaginary part χ₀ should be large enough with respect to to have everywhere a lossy medium, i.e., . In this rather generic model, the ORL condition (r_L = 0) is simply attained when w = 0^5,4, in which case the real and imaginary parts of the susceptibility modulation χ(z) − iχ₀ are spatially shifted by π/2 and satisfy the spatial Kramers-Kronig relations⁶. The reflection and transmission of a light beam with a wave-vector can be described on the basis of a minimal coupled-mode model accounting for Bragg scattering in a sample of length L ≫ a, as usual. Then, the CPA condition is attained when

where (with Re[η] > 0 due to losses). The last term in Eq. (2) holds when |e^ηL| ≫ 1 (|t| ≪ 1) and w ≪ 1, and this is precisely the regime we are interested in as it can occur near a ORL point in a lossy medium. It thus appears that, while the parameter α is immaterial, the CPA condition can in general be satisfied only if β can be tuned at will within the whole interval [0, π], regardless of the value of w. In fact, although , need not be small at the CPA point as kL ≫ 1.

Though solid-state photonic structures may be considered⁴, coherently-prepared multi-level atoms^5,42 are attractive for exploring non-Hermitian optics, because of the easy reconfiguration of the scattering process through well established control techniques enabled by electromagnetically induced transparency (EIT)⁴³. In fact, the realization of atomic platforms to investigate non-Hermitian models is currently a very active experimental endeavor^44,45. We consider the realistic atomic system of Fig. 1, which provides an implementation of the model of Eq.(1). The photonic crystal consists of cold atoms coherently driven by a near-resonant probe beam (Ω_p, Δ_p ≈ 0), a resonant coupling beam (Ω_c, Δ_c = 0) and an far-detuned dressing field (Ω_d,|Δ_d| ≫ 0). The latter has both a traveling-wave (TW) and a standing-wave (SW) components with opposite detunings and induces on level |2〉 a dynamic shift , where and the phase shift 2ϕ_d is relative to the optical lattice modulating the atomic density. As a matter of fact, by adjusting only three of the above independent control parameters, namely {Δ_p, δ_d0, ϕ_d}, it is possible to identify scattering processes for which the existence of the CPA–ORL connection can be proven. More specifically, this is done by solving the density matrix equations for the atomic level configuration of Fig. 1 whose matrix elements will depend, among other parameters kept fixed here as in Fig. 6 of ref. 45, on the three parameters (Δ_p, δ_d0, ϕ_d) (See sect. II of ref. 45). For each choice of these three experimentally tunable parameters, we numerically compute the full susceptibility χ(z), which can be cast in the form of Eq. (1) when its higher order Fourier components are disregarded. From χ(z) we then directly obtain through transfer matrix calculations⁴⁶ the scattering amplitudes t, r_L and r_R that identify a specific scattering process.

Figure 1

The CPA – ORL connection scattering scheme.

(a) Cold ⁸⁷Rb atoms are loaded in a 1D optical lattice (black-solid) of period a. These atoms suffer a dynamic level shift (red-dashed) with the same periodicity, but phase shifted with respect to the optical lattice. The incident probe electric field amplitudes () are scattered by the atomic lattice into the outgoing electric field amplitudes (). For fields () incident from the right, e.g., outgoing amplitudes consist of waves () transmitted with amplitude t_R in the −z direction as well as waves () reflected with amplitude r_R in the +z direction; likewise for fields () incident from the left and reflected (transmitted) with amplitude r_L (t_L); while in general r_L ≠ r_R, t_L = t_R = t. (b) A four-level N-configuration through which ⁸⁷Rb atoms are driven by a weak near-resonant probe field (green) on the transition, a moderate resonant coupling field (blue) on the transition and a strong far-detuned dressing field (red) on the transition. (c) The probe, with Rabi frequency Ω_p and detuning Δ_p, and the resonant coupling (Δ_c = 0), with Rabi frequency Ω_c, propagate in the z direction. The dressing field has instead a TW component propagating in the x direction, with Rabi frequency Ω_d and detuning −Δ_d, and a SW component modulated in the z direction, with detuning +Δ_d.

Figure 6

Plots of ρ (a) and θ (b) along the directions marked by the two color-dashed arrows in Fig. 3(a) for {ϕ_d = 0.15 × π, Δ_p = 0.576δ_d0 − 0.220 MHz} (blue-dashed line) and for {ϕ_d = 0.25 × π, Δ_p = 0.0 MHz} (red-solid line). The two CPA-points () and () (circles) placed at δ_d0 = 3.025 MHz (ϕ_d = 0.15 × π) and at δ_d0 = 2.896 MHz (ϕ_d = 0.25 × π) correspond to those shown respectively in Fig. 5(a,b) (non-Hermitian) and Fig. 5(c,d) (pseudo-Hermitian). The two ORL-points () and () (squares) placed at δ_d0 = 2.748 MHz (ϕ_d = 0.15 × π) and at δ_d0 = 2.615 MHz (ϕ_d = 0.25 × π) correspond to those shown respectively in Fig. 5(a,b) (non-Hermitian) and Fig. 5(c,d) (pseudo-Hermitian). At the ORL-points the phase θ is not defined and changes by π, as shown by vertical dotted lines in panel (b). At the CPA-point () the ratio of right to left incoming intensities is about 0.082 while at the CPA-point () the ratio is 0.053.

A relevant sets of ORL points (r_L = 0) and the associated CPA-points (t² = r_Rr_L) are reported in the 3D parameter space {Δ_p, δ_d0, ϕ_d} of Fig. 2. A CPA-line lying roughly parallel to an ORL-line is shown there. Hence, we can access a CPA-point starting from a ORL-point essentially by adjusting the parameter δ_d0. The reason is simply that (i) the transmission amplitude t is always small in our lossy atomic medium and (ii) the reflection amplitudes r_L and r_R are more sensitive to δ_d0 than Δ_p at a fixed value of ϕ_d. A range of ϕ_d values centered at ϕ_d = π/4 is shown, being our system periodic in ϕ_d with period π, while varying ϕ_d from ϕ_d = π/4 to 3π/4 (or to −π/4) simply changes the reflectionless behavior from the “left” into reflectionless from the “right”. Notice also that the CPA-lines and ORL-lines are symmetric under the simultaneous changes ϕ_d → π/2−ϕ_d and Δ_p → −Δ_p. We can always find an isolated CPA-point associated to a nearby isolated ORL-point through cuts along {Δ_p, δ_d0}-planes as shown in Fig. 3. Figure 4 illustrates further examples of how ORL-points and the associated CPA-points are computed. ORL-points are characterized by r_L = 0 and are here obtained by solving the two real equations Re[r_L] = 0 and Im[r_L] = 0. In the neighborhood of a solution both Re[r_L] and Im[r_L] change sign and their product changes sign in four alternating sections (i.e., deformed quadrants) of the {Δ_p, δ_d0}-plane as shown in Fig. 4(a–c,e–g). This corresponds to the fact that the phase of r_L varies by 2π when a ORL-point is encircled in the {Δ_p, δ_d0}-plane, which embodies the freedom of choice of β in Eq. (2), and is a key point as discussed below. CPA-points, characterized by t² = r_Lr_R, are illustrated instead in Fig. 4(b–d,f–h) as minima of the function |t² − r_Lr_R|.

Figure 2

A CPA-line and the nearby ORL-line for a typical photonic crystal structure are shown in the parameter space {Δ_p, δ_d0, ϕ_d}.

The two lines which are nearly “parallel” are also shown projected onto the {δ_d0, ϕ_d} plane (blue lines), the {Δ_p, ϕ_d} plane (green lines) and the {Δ_p, δ_d0} plane (red lines). The points labeled (), (), () and () correspond to those marked in Fig. 3.

Figure 3

Pairs of ORL (+) and CPA (*) points in the {Δ _p, δ_d0} plane (yellow plane in Fig. 2) corresponding to values of ϕ_d ranging from 0.15 × π to 0.30 × π (top to bottom).

Figure 4

a–c,e–g (left column)] Contour plots of Re[r_L] × Im[r_L]: ORL-points (white-dots) occur when both Re[r_L] and Im[r_L] change sign in the {Δ_p, δ_d0}-plane. [b–d,f–h (right column)] Corresponding CPA-points (white-dots) occur when |t² − r_Lr_R| vanishes. Each pair of ORL-CPA points is found for a given value of ϕ_d (from top to bottom: ϕ_d/π = 0.20, 0.25, 0.30, 0.35).

Discussion

The CPA – ORL connection can also be assessed in more general terms starting from the two-ports scattering process,

where the S matrix relates the outgoing (electric) field amplitudes and to the incoming (electric) field amplitudes and (see Fig. 1a). The eigenvalues and eigenvectors of S are obtained through the last term in Eq. (3). It is here worth noting that we have chosen one of the most common representations of the S matrix, the other one having instead r_L and r_R on the diagonal. While the scattering is solely determined by the measurable complex amplitudes t, r_L and r_R and all physical results are independent of which S matrix representation is used, the specific choice of S in Eq. (3) is appropriate to prove the CPA – ORL connection, where the ORL condition is in this case directly related to a non-Hermitian degeneracy (or exceptional point) of S, as we illustrate in the following.

In general, S is non-Hermitian, its eigenvalues

are complex and the (unnormalized) eigenvectors are not orthogonal. Non-Hermitian degeneracies of S occur when the eigenvalues merge into one another [Fig. 5(a–d)] and the eigenvectors coalesce into a single state⁷, being the S matrix no longer diagonalizable. The two coalescing eigenvalues are analytically connected by a square-root branch-point, with associated Riemann sheets, and are physically associated with unidirectional reflectionless scattering states occurring when r_L = 0 (or r_R = 0)^4,5. For a non-Hermitian matrix, degeneracies are of codimension two, that is points in a two-parameter space (NHD-point) and curves in a three-parameter space (NHD-line). Meanwhile, CPA occurs when either one of the two eigenvalues or vanishes [Fig. 5(a–d)] along with the determinant of S (this condition is independent of the specific choice of S matrix representation). The corresponding eigenvector describes a perfect absorption state¹⁰ with amplitudes and phases of the incoming fields from the left and from the right precisely chosen so that no outgoing light intensity can be observed^13,18.

Figure 5

Coherent Perfect Absorption (CPA) and Non-Hermitian Degeneracies (NHD).

Typical topology of the S-matrix eigenvalues (4) around a NHD (circle) for non-Hermitian (a,b) and pseudo-Hermitian (c,d) scattering processes in the photonic crystal structure of Fig. 1. Vertical green line indicate CPA-points next to a NHD-point respectively at (a,b) δ_d0 = 3.02 MHz (with Δ_p = 1.52 MHz, point () in Fig. 3) and δ_d0 = 2.75 MHz (with Δ_p = 1.36 MHz, point () in Fig. 3) and at (c,d) δ_d0 = 2.89 MHz (with Δ_p = 0, point () in Fig. 3) and δ_d0 = 2.61 MHz (with Δ_p = 0, point () in Fig. 3). Polar representation of the two eigenvalues before (e) and at (f ) the NHD-point, and at (g) and after (h) the CPA-point for the case (c,d) (with Δ_p = 0). Light green and violet arrows mark respectively the two eigenvalues half-sum (t) and half-difference ().

We start providing an intuitive illustration of how CPA and ORL are connected with one another in the particular, but important, case for which (i) the reflection phases are such that ϕ_L + ϕ_R = {0, π} and (ii) the transmission amplitude t is real. The corresponding eigenvalues are either real or complex conjugate in pairs depending on whether the two phases add up to 0 or to π [Fig. 5(c,d)]. Thus (half) sum of the two eigenvalues represents t and can be depicted, as we move in the parameter space toward degeneracy, by a vector whose magnitude decreases along the real axis of Fig. 5(e) for decreasing transmission. So does (half) difference of the two eigenvalues representing the geometric mean of r_L and r_R, which can be depicted by a vector parallel to the imaginary axis. As we move through degeneracy, the eigenvalues sum will keep decreasing but their difference will increase after moving away from zero (degeneracy) [Fig. 5(f)] owing to the intrinsic bifurcation (topological) structure of the branch-point. Hence there will always be a point where sum and difference will be equal (to each other), i.e., [Fig. 5(g)]. It is worth noting that under the conditions (i.) and (ii.) an Hermitian invertible transformation η exists indeed for which the adjoint of the (non-Hermitian) scattering matrix S satisfies S^† = ηSη⁻¹, i.e., S is pseudo-Hermitian⁴⁸. The reverse is also true and hence the pseudo-Hermiticity of S is the basic mathematical structure responsible for the direct connection between the ORL and the CPA point, at least for the specific spectrum of S shown in Fig. 5(c,d). Note that this particular case – realized in the all-optically tunable atomic system of Fig. 1 simply setting Δ_p = 0 – is essentially analogous to a PT symmetric one, even though our system is always lossy, both before and after the NHD point.

Yet, a CPA-point can be typically found in the vicinity of a ORL-point under more general conditions and, in particular, without restricting ourselves to pseudo-Hermiticity. For definiteness we take the NHD-point at assuming, without loss of generality, that around this point |r_R| and |t| are nonvanishing. For lossy media we may further take |t| ≪ 1, with |r_R| being in general on the order of unity⁵. The perfect absorption condition is satisfied when r_Lr_R = t², i.e. when

are both satisfied, implying that |r_L| and arg(r_L) should be independently adjusted (just as the phase β in Eq. (2) should be tuned at will, regardless of the value of w). Note that the CPA conditions in Eq. (5) generalize those given above for the pseudo-Hermitian case, and are only restricted by the requirement that |r_L| be small at the CPA-point, which occurs when this point is associated to a nearby ORL-point. In general, we do expect t²/r_R to be smoothly varying in the vicinity of this point while arg(r_L) can be varied at will when the parameters defining the system are smoothly changed so to encircle the ORL-point, i.e. the NHD of S⁵. A simple geometric illustration of this property similar to that provided in Fig. 5(e–h) is not so viable in the general, non pseudo-Hermitian case (such as that of Fig. 5(a,b)); yet, a direct analytical argument shows that |r_L| and arg(r_L) can be independently adjusted when encircling the ORL-point.

In a typical scattering process, r_L depends smoothly on several experimental parameters. We consider here how the real (u) and the imaginary (v) parts of r_L vary near the ORL-point as a function of only two of these parameters, keeping all other ones fixed. In terms of these two parameters, say x and y, one has

where the partial derivatives u_x = ∂u/∂x, u_y = ∂u/∂y, v_x = ∂v/∂x, and v_y = ∂v/∂y are evaluated at the ORL-point taken at (x, y) = (0, 0). Note that it is not needed to combine x and y into a single complex parameter x + iy as r_L is not assumed to be holomorphic here. When u_xv_y − v_xu_y ≠ 0, it is always possible to select x and y to obtain any required values of arg(r_L) and of |r_L|, provided the latter is small enough that higher order terms in Eq. (6) are indeed negligible. Thus, under typical circumstances we expect a CPA and a ORL points to be close to each other in a scattering process from lossy media with |t| small. For example, in Fig. 3 the case ϕ_d = 0.25 × π (pink-arrow) represents changes in the scattering matrix as one moves from its NHD-point () to its CPA-companion (), namely for a pseudo-Hermitian matrix (Δ_p = 0). Similarly, the case ϕ_d = 0.15 × π (blue-arrow) represents changes as one moves from the NHD-point () to its CPA-companion (), namely for the general non-Hermitian case. Actually, the case in which u_xv_y − v_xu_y = 0 cannot be excluded. Assuming that (u_y, v_y) ≠ (0, 0) and writing (u_x, v_x) = μ(u_y, v_y) with μ real, one then has

which implies that, while |r_L| = |Δr_L| can be varied, arg(r_L) = arg(Δr_L) is fixed because . In this case, we expect to find no CPA-point in the vicinity of a ORL-point when all other parameters are kept constant. Clearly, also when higher order terms in the above expansion of r_L become important as for instance in the peculiar case where all partial derivatives in Eq. (6) are vanishingly small, the occurrence of the CPA point is not granted.

Defining ρe^iθ ≡ −r_L/t, the scattering matrix eigenvector at the CPA-point, where the corresponding eigenvalue vanishes, can be eventually written as,

The complex quantity ρe^iθ is examined in Fig. 6 both for the pseudo-Hermitian and non-Hermitian cases. At the CPA-point, the eigenvector’s components scale as , with ρ ≪ 1 according to Eq. (5). Both modulus (ρ) and phase (θ) of the (small) incoming field from the right, with respect to the incoming field from the left (i.e, the nearly reflectionless side), should be properly chosen to observe the typical perfect absorption behavior. Since the CPA-point considered here is associated to a ORL point, in general, perfect absorption requires very unbalanced incoming fields. As a matter of fact, the characteristic destructive interference conditions leading to perfect absorption for light scattering in both directions occur here for very unbalanced right and left reflectivities |r_R| ≫ |r_L|. In turn, a tiny input field from the right is sufficient to ensure that the outgoing field to the left vanishes, while a large input field from the left is necessary to destructively interfere with the reflected field from the right side. This CPA configuration provides, in particular, a high-contrast reflectivity control of a test beam incident from the right via a pump beam incident from the left.

Conclusions

A new insight into the non-Hermitian optics of a familiar class of lossy photonic crystals is here discussed. Through continuous deformations of the scattering matrix S around a one-sided reflectionless (ORL) point, a CPA point can be typically attained. Nearby pairs of ORL and CPA “points” or even “lines” appear, respectively, through controlling the crystal 2D or 3D parameter space. In such cases, the CPA scattering states associated to ORL points turn out to be significantly unbalanced, indicating a dynamically reversible high-contrast reflectivity control of the input beams. Finally, while the results here presented refer to realistic atomic structures^44,45, our general discussion can be easily adapted to atomic-like multilevel centers⁴⁹ in solids, such as NV diamond or rare-earth-doped crystals, also allowing for EIT control of light scattering^50,51. Hence the optics of photonic crystals is poised to have a privileged place in assessing that not only standard Hermitian models but also a broad set of non-Hermitian ones are bound to have physical interpretations.