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26 KiB
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364 lines
26 KiB
Plaintext
Rotational Doppler shift of the phase-conjugated photon.
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A.Yu.Okulov∗ Russian Academy of Sciences, Moscow, Russia
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(Dated: April 12, 2011)
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The rotational Doppler shift of a photon with orbital angular momentum ±ℓ is shown to be an even multiple of the angular frequency Ω of the reference frame rotation when photon is reflected from the phase-conjugating mirror. The one-arm phase-conjugating interferometer is considered. It contains N Dove prisms or other angular momentum altering elements rotating in opposite directions. When such interferometer is placed in the rotating vehicle the δω = 4(N + 1/2)ℓ · Ω rotational Doppler shift appears and rotation of the helical interference pattern with angular frequency δω/2ℓ occurs. The accumulation of angular Doppler shift via successive passages through the N image-inverting prisms is due to the phase conjugation, for conventional parabolic retroreflector the accumulation is absent. The features of such a vortex phase conjugating interferometry at the single photon level are discussed.
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PACS numbers: 42.50.Tx 42.65.Hw 06.30.Gv 42.50.Dv
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arXiv:1104.1529v7 [quant-ph] 23 Sep 2011
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I. INTRODUCTION.
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Single photon interferometry utilizes the superposition of a mutually coherent (phase-locked) quantum states Ψj [1] to whom photon belongs simultaneously. The interference pattern depends on a method of Ψj preparation. The double-slit Young interferometer creates two free-space wavefunctions Ψ1,Ψ2, whose interference pattern produced by detection of the individual photons is recorded by an array of detectors or a photographic plate located in the near or far field. In Mach-Zehnder configuration [2, 3] two wavefunctions separated by entrance beamsplitter recombine at the output beamsplitter. The Michelson interferometer recombines at the input beamsplitter two retrof lected quantum states provided these states are phase-locked and their path difference δL is smaller than the coherence length Lc. Thus interference pattern is simply ∼ [1+V (δL)·cos(2k·δL)], where V (δL) is a visibility or second-order correlation function and k = 2π/λ. When retroflection is accompanied by wavefront reversal (PC) realized with phase-conjugating mirrors (PCM) [4] based upon Stimulated Brillouin scattering [5, 6], photorefractivity [7, 8] or holographic PCM’s, the optical path δL difference is almost entirely compensated due to PC. Noteworthy the small phase lag due to the relatively small frequency shift δω = ωf − ωb arising due to the excitation of internal waves inside PCM volume [9], where ωf and ωb are the carrier frequencies of incident and PC-reflected photon respectively. This leads to the interference term 1 + V (δL) · cos(δk · δL), where δk = δω/c [6].
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We study the photon in the optical vortex quantum state [2, 3] with topological charge ℓ, where the angular momentum Lz = ±ℓ · is due to the phase singularity located at propagation axis Z (hereafter the spin com-
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∗Electronic
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address:
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alexey.okulov@gmail.com;
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URL: http://okulov-official.narod.ru
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ponent of angular momentum [10] is supposed to be zero due to the linear polarization). It is convinient to use the single-photon wavefunctions which coincide with the positive freq√uency component of the electric field envelope |Ψ >= 2ǫ0 · E(t, r) [11]. The square modulus of Ψ is proportional to the energy density of the continuous wave laser beams (CW) and to the photons count rate in a different fringes of the interference pattern for the single-photon experiments [12]. We will assume Ψ to have the form of the Laguerre-Gaussian beam (LG) with ℓ orbital angular momentum (OAM) per photon [9] but any other isolated vortex solutions, e.g. Bessel vortices [13, 14] will demonstrate the same final results:
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Ψ(f,b)(z,
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r,
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θ,
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t)
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∼
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√ 2ǫ0
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·
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exp[i(−ω(f,b)t ± k(f,b)z) (1+iz/zR)
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±
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iℓθ]
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E(f,b)(r/D0
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)|ℓ|
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exp[−
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r2 D02(1+iz/zR)
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],
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zR
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=
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k(f,b)D02
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(1)
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where the cylindrical coordinates (z, r, θ) are used, D0 is the vortex radius, zR is Rayleigh range, Ψf , Ef stands for the forward wave, propagating in positive Z-direction, Ψb, Eb stands for the wave, propagating in the negative one. Of special interest is the sub-Hz - order angular frequency splitting δω = c(kf − kb) which appears due to the slow mechanical rotation of the setup [3, 15]. It was already shown that rotation of the λ/2 waveplate with angular frequency Ω ∼ 2π(1 − 100)rad/s in a one arm of the Mach-Zehnder interferometer induces the rotational Doppler shift (RDS) δω = 2Ωℓ for circularily polarized broadband CW with linewidth ∆ω/2π ≃ 1010Hz. In this configuration the broadband spectrum was shifted as a whole via mechanical rotation (by angular Doppler effect) at δω/2π = ±2 · 7Hz and the beats at the output mirror induced an appropriate rotation of the interference pattern [16].
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2
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FIG. 1: (Color online)Additivity of RDS for the PCMreflected photon in the rest f rame. Rotation of the Dove prism (positive Ω) decreases frequency to −2ℓ · Ω of the corotating incident photon with Lz = +ℓ . Reflection from PCM alters Lz projection to the opposite one and clockwise rotation of Dove prism (as seen to backward photon) again decreases the frequency of co-rotating photon to −2ℓ · Ω. Helical interference pattern is static between prism and PCM (where δω = 0) and rotates bef ore prism with angular velocity δω = −2Ω.
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II. PHASE-CONJUGATING MIRROR IN A REST FRAME.
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Let us consider first the single-arm phase-conjugating vortex interferometer (PCVI) when PC-mirror is in the rest frame. Due to the reflection from PCM the helical photon with a linear polarization proves to be in a superposition of the two counter propagating quantum states Ψf,b (fig.1). Currently the best candidate for the ideal single-photon PCM is a thick hologram written with sufficiently high diffraction efficiency (R ∼ 0.9) for the ℓ charged optical vortex [3, 17, 18]. In such a case the amplitudes of forward and backward fields are close to each other and visibility of the interference pattern V (δL) is close to 1, provided that coherence length Lc ∼ 2πc/∆ω is bigger than the doubled length of PCVI.
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The ideal PCM ensures the perfect coincidence of the helical phase surfaces of the counter propagating optical vortices Ψf,b and zeros of their electric field amplitudes on Z axis. In contrast to the speckle fields whose interference pattern is composed of intertwined Archimedean screws [21] in PCVI the isolated Archimedean screw pattern appears both for the single photon with LG wavefunction and for CW resulting in the intensity profile Itw composed of 2ℓ twisted f ringes [7, 19, 20]:
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z′ = z − zpc, |Ψ|2 = |Ψf + Ψb|2 ∼ Itw (z′, r, θ, t) =
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2ǫ0 c|E(f,b)|22(|ℓ|+1)(r/D0)2|ℓ| πℓ!D02(1 + z′2/zR2)
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· exp[− D02(1
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2r2 + z′2/zR
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2)
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]
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[1 + R2 + 2R · cos[δω · t − (kf + kb)z′ + 2ℓ θ]], (2)
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where zpc is location of PCM entrance window. The angular speed of pattern rotation θ˙ = δω/2ℓ is given by the
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differentiation of the self similar argument 2θ(t)·ℓ+δω·t− (kf + kb)z′ [16] vs time t. Consider the origin of RDS δω
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[3, 22–24] for the photon with topological charge ℓ after
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the double passage through a Dove prism rotating with
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FIG. 2: (Color online)Mutual cancellation of RDS for retroreflected photon. Rotation of the Dove prism again decreases frequency of the co-rotating forward photon with Lz = +ℓ by −2ℓ·Ω. In backward propagation the Dove prism is counter rotating with respect to photon. Backward RDS is positive thus resulting δω is zero hence toroidal interference pattern is static for all Z.
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angular velocity Ω and reflection from PCM. OAM projection on propagation axis Z is < Ψf,b|Lˆz|Ψf,b >= ±ℓ , where Lˆz = −i · ∂/∂θ.
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The RDS occurs because the optical torque on a slowly rotating element changes the angular momentum of the prism [9, 10]. In its turn this changes the prism’s angular velocity Ω and such a change requires the energy supply. Because typical optical elements including prisms are macroscopic classical objects having the continuous spectrum of energies, in such case the energy ωf,b hence the frequency of the photon may be changed continuously [16].
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Noteworthy that without PCM the rotation of Dove prism with respect to the other components of the optical setup would be highly sensitive to misalignments and this would require a very accurate tuning [3]. The phase conjugation facilitates the adjustments and provides interference pattern with good visibility [6].
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In the following phase-conjugating optical interferometer the photon’s OAM direction is altered as well [9, 26] (fig.1). Let the optical vortex Ef (t, r) of charge ℓ to pass through a rotating Dove prism and to be reflected with Eb(t, r) from a some ideal (PCM). The non-rotating PCM is supposed to produce no frequency shift as it happens in some cases in photorefractive crystals [7, 8], degenerate four-wave mixing [5, 26], and holographic PC couplers [3, 17]. Noteworthy that a small 10−1 − 10Hz frequency shifts in BaT iO3 photorefractive PCM may mask the RDS. These additional frequency shifts due to slow internal charge waves and filamentation effects were reported in early 1980’s yet [27, 28].
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Because space is homogeneous and isotropic the conservation of energy, momentum and angular momentum is expected [29]. Reproducing the Dholakia’s symmetry arguments [16] adapted to the current case we have the following conservation laws for the angular momenta Lz with respect to z − axis and the energies of the incident photons and those transmitted through the Dove prism,
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3
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when the latter rotates with the angular velocity Ω:
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Izz · Ω + Lz = Izz · Ω′ + L′z
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ωf
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+
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Izz Ω2 2
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=
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ω′
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+
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Izz Ω′ 2
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2
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,
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(3)
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where Izz is the moment of inertia around Z-axis, left hand sides of this system correspond to the incident pho-
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ton and the right hand sides correspond to the transmit-
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ted one. The co-rotation of the prism and the photon corresponds to the same sign of projections (Ω, Ω′) of Ω
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and Lz on z-axis before and after the photon’s passage. For the incident Lz = +ℓ and passed L′z = −ℓ the eq. (3) gives the difference of the angular velocities of the
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prism before and after the photon passage:
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Ω
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−
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Ω′
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=
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−
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2ℓ · Izz
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.
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(4)
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This means that co-rotation increases the angular velocity of prism, because the energy is transmitted to
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prism by a virtue of the optical torque |T | = 2ℓ · P/ωf , where P is total power carried by LG [3] hence Doppler frequency shift for the photon ω′ − ωf is negative:
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δω
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=
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ω′
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−
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ωf
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=
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Izz 2
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(Ω
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−
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Ω′ )(Ω′
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+ Ω)
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=
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−2ℓ
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·
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Ω
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−
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2ℓ · Izz
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.
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(5)
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Obviously in the counter rotating case, when projections
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of Ω and Lz are in the opposite directions, the rotational Doppler shift is positive. The net RDS during total forward-backward passage is additive due to PCM and this results in the net OAM change δω = ±4ℓ · Ω. The interference pattern and RDS will be the same for all PC-mirrors close to an ideal one, including just proposed linear loop PCM, which uses flat optical surfaces without any holographic element [20]. The frequency shift δω is zero in between Dove prism and PCM and helical pattern is static there. In the region before Dove prism, the frequency shift causes the clockwise (δω = −4ℓ ·Ω) or counterclockwise (δω = +4ℓ · Ω) rotation of optical helix pattern [9]. As stated before (2) the angular speed of the optical helix rotation θ˙ = ±2Ω is smaller than δω.
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Because of the angular momentum conservation the PCM feels the rotational recoil which is proportional to topological charge ℓ: |Tpc| = ℓ · P (ωf−1 + ωb−1). The Dove prism feels doubled torque : |TDove| = 2ℓ · P (ωf−1 + ωb−1). Note that Lebedev radiation pressure force is always di-
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rected in positive Z direction and |Fpc| = 2 · P/c is independent of ℓ [30].
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In the absence of the truly phase-conjugating mirror when the forward beam is retroreflected by spherical mirror (fig.2) without altering the angular momentum the interference pattern is a toroidal one Itor [7, 9, 13, 31]:
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|Ψ|2 = |Ψf + Ψb|2 ∼ Itor (z′, r, θ, t) =
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2ǫ0 c|E(f,b)|22(|ℓ|+1)(r/D0)2|ℓ| πℓ!D02(1 + z′2/zR2)
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· exp[− D02(1
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2r2 + z′2/zR
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2)
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]
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[1 + R2 + 2R · cos[δω · t − (kf + kb)z′]] . (6)
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FIG. 3: (Color online)Additivity of RDS in PCVI inside rotating vehicle. PC-mirror counter rotating around Z-axis changes the carrier frequency of reflected photon to δω = ±2ℓ · Ω. The sign of δω is positive when optical torque T produced by a bunch of the rotating photons upon mirror has the opposite direction compared to the rotation frequency of PCM Ω. When Dove prism rotates in opposite direction vs PCM the net RDS reaches six-fold value δω = ±6ℓ · Ω due to the additional OAM alternation. The sequence of N counter rotating OAM altering elements (including helical waveplates and cylindrical lenses) will produce net RDS of δω = 4ℓ · Ω(N + 1/2) value. |Ψ1,2,3,4 > designates antibunching of photons, which belongs to the two (for ℓ = 1) helical wavefunctions, separated by λ/2 interval, deflected by entrance beamsplitter BS [7].
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The RDS is not accumulated here (the Doppler shifts for the forward and backward photons cancel each other δω = 0) because the truly phase-conjugation is absent hence toroidal interference pattern is static. The me-
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chanical torques on prism T induced by OAM alternation will cancel each other too: |T | = 2ℓ · P (ωf−1 − ωb−1) ∼= 0.
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III. PHASE-CONJUGATING MIRROR IN A ROTATING FRAME.
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The more fundamental case is a rotation of the all setup as a whole around a some axis and this general case is relevant to the detection of the slow rotations of the reference frame [1]. In contrast to Sagnac interferometer where frequency splitting and running interference pattern appears in active loop only the PCVI produces frequency splitting δω even in the passive configuration (fig.3). Apparently the RDS δω will be the same when CW laser is placed in both inertial (rest) frame and in the noninertial frame associated with rotating vehicle. For the simplest case when the sole PCM rotates around propagation axis Z of a twisted photon with charge ℓ the RDS appears due to the alternation of the photon’s OAM. The eqs. (3) give again the frequency shift δω = ωb − ωf due to the reflection from rotating PCM:
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δω
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=
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ωb
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− ωf
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=
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±2ℓ · Ω +
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2ℓ · (Izz )P CM
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.
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(7)
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The second term in the right-hand side of (7) is negligible for typical masses (m ∼ g) and sizes (r ∼ cm) of a prisms
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and mirrors /Izz ∼ /(m·r−2) ∼= 10−27Hz. as in Beth’s [10] and Dholakia’s [16] experiments for the interaction of circularily polarized photons with the macroscopic object (half-wavelength plate).
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The angular speed of rotation of the interference pattern proves to be θ˙ = δω/2ℓ = Ω thus the pattern rotates synchronously with the reference frame. Consequently the sole PCM cannot detect frame rotation. The helical interference pattern outside PCM will be dragged by helical diffraction grating [9] within the phase-conjugating mirror. No atomic coherence [32] is required in our case.
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Nevertheless there exists a possibility to accumulate the RDS by means of a chain of OAM alternating elements. To achieve the accumulation of RDS the adjacent components of PCVI must rotate in opposite directions Ωn = (−1)nΩ, where n = 0 stands for PCM, n = 1 for the adjacent Dove prism to PCM, n = N for the last Dove prism(DP) near BS. This is necessary because OAM is altered after the passage of the Dove prism and the mutual orientation of the angular momenta of the photon and the next prism should be maintained throughout the chain. When even elements (the PCM
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itself and N/2 Dove prisms) of PCVI are fixed in Ω rotating frame and the rest N/2 odd elements ought to rotate
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there with angular velocity −2Ω. The chain of the N rotating OAM-alternating elements will produce the net rotational Doppler shift amounting to δω = 4ℓ·Ω(N +1/2). Thus PCVI interference pattern (fig.3) will revolve with enhanced angular speed θ˙ of the frame rotation by the factor θ˙ = ±2 · (N + 1/2) · Ω.
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For example PCVI (fig.3) may be used for demonstration of the possibility of detection of the sub-Hertzian rotation of the reference frame with the Earth (Ω⊕ ∼ 2π/86400). The helical interference pattern will rotate much faster than Earth itself. Namely the equation 4ℓ · (N + 1/2) = 24 [16] have the only one solution for integer ℓ, N (ℓ = 4, N = 1). Hence the optical vortex with charge ℓ = 4 passed through single Dove prism rotating
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with Ω⊕ and PCM rotating in opposite direction −Ω⊕ will produce the 2 · ℓ spots of interference pattern. The reflection from entrance beamsplitter BS will cause one pass per hour of the spot of interference pattern across the detector window, despite the Earth rotates once in 24 hours only.
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The further accumulation of RDS in PCVI might be achieved due to installing the N = 60 counter rotating image-inverting elements and ℓ = 6 optical vortex. In such configuration the 2 · ℓ helices of interference pattern eq.(2) will produce 2ℓ spots at the PCVI output (entrance beamsplitter BS) with a one pass through detector window within approximately each 60 seconds. For this purpose the even components (PCM and N/2 Dove prisms)
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may be fixed at setup rotating with velocity Ω⊕ while the others N/2 prism should rotate with ”bias” angular
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velocity −2Ω⊕ with respect to rotating setup (rotating table). This enhancement will model the detection Earth rotation, and this will alter the ℓ OAM of the each pho-
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4
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ton 121 times during one passage through PCVI. Noteworthy the Dove prism is not the sole element capable to alter the photon’s OAM. This can be done as well with helical waveplates and cylindrical lenses [17, 33]. The helical interference pattern within PCVI might also be written by means of atomic coherence effects in a solidstate resonant medium [32].
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IV. SINGLE-PHOTON OPERATION OF THE PHASE-CONJUGATING VORTEX INTERFEROMETER.
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The single-photon operation [12] is based upon the superposition of the forward and backward quantum states with ℓ OAM:
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|Ψ
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>helix =
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√1 2
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(|Ψ±ℓ
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>f +|Ψ∓ℓ
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>b)
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=
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√1 2ℓ
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jh
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|Ψjh
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>.
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(8)
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The detection of this superposition is not a trivial two-
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detector procedure, because the interference pattern is
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composed of 2ℓ twisted helices |Ψjh >. The entrance beamsplitter BS will reflect both upward and downward
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the interference pattern [7, 9] composed of the 2ℓ spots
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located on an ellipse, rather than independent forward
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|Ψ±ℓ >f and backward |Ψ∓ℓ >b photon states. For the simplest case ℓ = 1 the photon will be in the superposi-
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tion state of the two helical wavefunctions designated by
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appropriate colors at fig.(3):
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|Ψ
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>helix=
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√1 2
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(|ΨBlue
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>
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+|ΨY ellow
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>).
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(9)
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This means that two detectors (for |Ψ1 > and |Ψ2 >) placed above the entrance beamsplitter BS [7] and two detectors located below BS (for |Ψ3 > and |Ψ4 >) can indicate the antibunching of the photons [1], belonging to either of the two helices composing the interference pattern. As in a double-slit Young interference experiment the crude attempt of the eavesdropping the which way photon moves (the forward or backward one) will destroy the helical interference pattern. On the other hand when single-photon quantum state is prepared as a toroidal pattern (fig.2) the photon belongs to the sequence of the equidistantly spaced toroidal Wannier wavefunctions |Ψjtor > separated by λ/2 intervals:
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|Ψ
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>tor =
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√1 2
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(|Ψ±ℓ
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>f +|Ψ±ℓ
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>b)
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=
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√1 Ntor
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jtor
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Ψjtor
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.
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(10)
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V. CONCLUSION.
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In summary we analyzed the phase conjugating vortex interferometer for the both single photon [12] and the cw laser output. Because of the alignment of the all optical
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5
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components along photon Z propagation axis PCVI looks promising from the point of view of rotation sensing [1].
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In PCVI the RDS δω enhances the noninertial frame rotation Ω by a factor of the even multiple of the photon’s topological charge ℓ and of the number of angular momentum inverting elements N in PCVI chain. Noteworthy that in the proposed measurement of the Earth rotation δω = ±4ℓ · (N + 1/2)Ω⊕ cos(φ) will show dependence on geographical latitude φ as it known for the Foucault pendulum [34]: on the poles δω will be equal to the maximum value when the angle φ between nor-
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mal and PCVI axis is 0 or π, while at equator δω might reach maximum value when PCVI axis is parallel to the Earth rotation axis. The preliminary analysis have shown that the laser linewidth of the order ∆ω/2π ∼ 103Hz might be sufficient for Earth rotation detection by PCVI (fig.3). We hope to consider the above issues including entanglement of the helical photons in PCVI due to mixing counter propagating photon vortex states via entrance beamspliter in a more details in the subsequent work [35].
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[1] M.O.Scully, M.S.Zubairy,”Quantum optics”, Ch.4, (Cambridge University Press) (1997).
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[2] J.Leach,M.J.Padgett,S.M.Barnett,S.Franke-Arnold, and J.Courtial, ”Measuring the Orbital Angular Momentum of a Single Photon,” Phys.Rev.Lett. 88, 257901 (2002).
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[3] A. Bekshaev, M.Soskin and M. Vasnetsov, ”Paraxial Light Beams with Angular Momentum”, Nova Science(2008).
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[4] R.W.Boyd, ”Nonlinear Optics”, Academic Press (2003). [5] B.Y.Zeldovich, N.F.Pilipetsky and V.V.Shkunov,
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