Rezonanse typu spin-orbit w meta-materiałowych elementach nanofotoniki Spin-orbit resonances in meta-material elements of nanophotonics

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Rezonanse typu spin-orbit w meta-materiałowych elementach nanofotoniki Spin-orbit resonances in meta-material elements of nanophotonics Wojciech Nasalski Zespół Badawczy Nanofotoniki Instytut Podstawowych Problemów Techniki Polskiej Akademii Nauk

Vectorial description of optical 3D beams References 1. W. Nasalski, Three-dimensional beam reflection at dielectric interfaces, Opt. Commun. 197, 217-233 (2001). 2. W. Nasalski, Amplitude-polarization representation of three-dimensional beams at a dielectric interface, J. Opt. A: Pure Appl. Opt. 5, 128-136 (2003). 3. W. Nasalski, Optical beams at dielectric interfaces - fundamentals, in Series: Trends in Mechanics of materials (IPPT PAN, Warsaw 2007). Cross-polarization (XPC) spin-orbit conversion of optical vortices nested in optical beams 4. W. Nasalski, Polarization versus spatial characteristics of optical beams at a planar isotropic interface, Phys. Rev. E 74, 056613-1-16 (2006). 5. W. Nasalski and Y. Pagani, Excitation and cancellation of higher-order beam modes at isotropic interfaces, J. Opt. A: Pure Appl. Opt. 8, 21-29 (2006). 6. W. Szabelak and W. Nasalski, "Transmission of Elegant Laguerre-Gaussian beams at a dielectric interface - numerical simulations", Bull. Pol. Ac. Tech. 57, 181-188 (2009). 7. W. Nasalski, "Cross-polarized normal mode patterns at a dielectric interface", Bull. Pol. Ac. Tech. 58, 141-154 (2010). Application of planar and resonant meta-material structures enhancement of the XPC 8. W. Szabelak and W. Nasalski, "Enhancement of cross-polarized beam components at a metamaterial surface", Appl. Phys. B - Lasers and Optics 103, 369-375 (2011). 9. W. Szabelak and W. Nasalski, "Cross-polarization coupling and switching in an open nano-meta-resonator", J. Phys. B. At. Mol. Opt. Phys. 44, 215403 (2011); featured by Institute of Physics, UK.

Optical field intensity in the beam transverse plane Elegant Hermite-Gaussian beam Elegant Laguerre-Gaussian beam EHG 1,1 pattern ELG 2,1 pattern topological charge l = 0 topological charge l = 1 transverse Cartesian symmetry transverse cylindrical symmetry WN, Phys. Rev. E (2006)

Optical field intensity and phase in the beam transverse plane ELG 1,3 ELG 0,3 ELG 2,1 topological charge l = 3 topological charge l = 5 topological charge l = 1 WN, Phys. Rev. E (2006)

Optical field polarization and phase in the beam transverse plane J. Courtial, et al., (2006)

Paraxial monochromatic complex argument ( elegant ) beams Hermite-Gaussian EHG beams in Cartesian coordinates X Y Z and polarization frames X Y : E ( EH ) m ( EH ) ( X, Y, Z) ( X Y ) G, ( X, Y, Z), n m n exp( i t ikz) vector polarization scalar spatial distribution plane-wave phase factor Fock Schrödinger equation: 1 2 2 ( EH ) ik ( ) G ( X, Y, Z) 0 Z 2 X Y m, n solutions in terms of Hermite polynomials H and Gaussian function G 0, 0 (A.E.Siegman (1973)): m ( EH ) m n 1 2 1 2 ( EH ) Gm, n ( X, Y, Z) ( ww ) H m(2 X v( Z)) H n (2 Y v( Z)) G0,0 ( X, Y, Z) no vortex, topological charge q = 0 Laguerre-Gaussian ELG beams in cylindrical coordinates Z and polarization frames CR CL : E ( EL) p, l ( r,, Z) ( CR Fock Schrödinger equation: CL ) G ( EL) ik G (,, Z') 0 Z ( EL) p, l (,, Z) exp( i t ikz) 1 2 1 2 p, l, 2 ( X iy) 2 exp( i ) l solution in terms of Laguerre polynomials L p and Gaussian function 0, 0 ( EL) p l l (2 p l) l 2 2 ( EL) Gp, l (,, Z' ) ( 1) ( v) ( v ww ) p! Lp ( v ) G0,0 (,, Z)exp( il ) with vortex, topological charge q = l G : WN, Phys. Rev. E (2006); Bull. Pol. Ac.: Tech. (2010)

Transmission matrix for beams at dielectric interfaces and multilayers with (known) Fresnel transmission coefficients t p of TM (E E x ) and t s of TE (E E y ) polarization in Cartesian transverse coordinates X Y (for HG beams of TM or TE polarization) for plane waves: T = t p 0 0 t s for beams: T = 1 2 t p + t s 1 0 0 1 + 1 2 t p t s +cos 2φ sin 2φ sin 2φ cos 2φ XPC in cylindrical transverse coordinates r φ (for LG beams of CR or CL polarization) for plane waves: T = 1 2 t p + t s t p t s t p t s t p + t for beams: T = 1 t s 2 p + t 1 0 s 0 1 + 1 t 2 p t s 0 exp( 2i ) exp(+2i ) 0 XPC non-diagonals exp( 2i ) induce the spin-orbit XPC conversion leading to vortex excitation or annihilation for incidence of the CR polarization of ELG beam G p l of radial index p and topological charge l l+2 it is excited the CL polarization of ELG beam G p 1 of radial index p-1 and topological charge l + 2 for incidence of the CL polarization of ELG beam G p l of radial index p and topological charge l l 2 it is excited the CR polarization of ELG beam G p+1 of radial index p+1 and topological charge l - 2 thus, the process is controlled by polarization CR or CL of the incident beam WN, Phys. Rev. E (2006); Bull. Pol. Ac.: Tech. (2010)

Vortex excitation at a dielectric Interface first row circular right-handed (CR) polarization of the incident beam incident CR ELG1,3 beam transmitted CL ELG0,5 beam transmitted Z ELG1/2,4 beam incident CL ELG1,3 beam transmitted CR ELG2,1 beam transmitted Z ELG3/2,2 beam second row circular left-handed (CL) polarization of the incident beam

Spin-to-orbital angular momentum SAM-to-OAM conversion SAM is associated with optical polarization and OAM is associated with optical wavefront at conventional (dielectric and transparent) planar interfaces and multilayers total angular momentum is conserved exactly for each individual photon in the beam l ħ = ( l spin + l orbital ) ħ = const. and for the whole beam field of cylindrical symmetry L z = L spin + L orbital = const. what results in entanglement of spin and orbital parts of beam fields α CR + β CL ELG p,l (r,, Z) qubits qudits

Vortex excitation and splitting induced by XPC effects at interfaces and multilayers oblique incident beam of the ELG 2,4 shape with L orbit = + 4ħ (a) for CL polarization of the incident beam input: L spin = - ħ, L orbit = + 4ħ, L z = L spin + L orbit = 3ħ per photon output: L spin = + ħ, L orbit = + 2ħ, L z = L spin + L orbit = 3ħ per photon (b) for CR polarization of the incident beam input: L spin = + ħ, L orbit = + 4ħ, L z = L spin + L orbit = 5ħ per photon output: L spin = - ħ, L orbit = + 6ħ, L z = L spin + L orbit = 5ħ per photon WN, Bull. Pol. Ac.: Tech. (2010)

One example from another approaches to the same problem here by application of liquid crystals forming a q-plate Spin-to-orbital angular momentum conversion occurring for a single photon (a) CL input polarization. (b) CR input polarization. L. Marucci (2008)

Spin-to-orbit angular momentum XPC conversion at conventional (dielectric and transparent) interfaces and multilayers total angular momentum is conserved exactly L z = L spin + L orbital = const. for each photon in the beam and for the whole beam field of cylindrical symmetry however, the vortex excitation and annihilation induced at these structures are weak possible remedy may be based, for example, on application of: anisotropic media metamaterial media further, one example of the second possibility will be shortly presented

Superlens action of a Double Negative (DNG) metamaterial layer Metamaterials do not exist in nature and can only be fabricated artificially. In DNG ( <0, <0, n<0) metamaterials waves exhibit phase and energy velocities of opposite directions. A DNG medium bends light to a negative angle relative to the surface normal. Light formerly diverging from a point in the object plane is reversed and converges back exactly to a point. after: V. G. Veselago (1968), J. B. Pendry (2000), C. M. Soukoulis, et al (2006).

Resonator cavity build from lossless dielectrics and DNG metamaterials due to the dielectric-metamaterial interfaces the cavity works without any mirror n 1 1 n2 1 n 1 1.2 n2 1. 2 n 1 2 n2 5/ 2 n4 1 n 3 1 n4 1 n 3 1 n4 5/ 2 n 3 1 Three cavities provide ideal focusing of rays at least at one point in one space quadrant. The ideal foci are indicated by black dots. Impedance matching at the inter-media boundaries and a number of ideal focusing points differentiate the type of the cavity. the third case, without any impedance matching, is chosen for numerical simulations WS & WN, J. Phys. B. At. Mol. Opt. Phys. (2011)

3D view of the nano-meta-resonator cavity the beam polarization TE-TM and the beam spatial EHG shape switching occurs due to the crosspolarization coupling at the cavity interfaces under their collective resonant action the incident beam is of EHG 1,1 transverse field shape, the green line represents the coupling path of the beam of linear-vertical polarisation, the blue line represents the propagation in the cavity, the red line represents the decoupling path of the beam of linear-horizontal polarization. WS & WN, J. Phys. B. At. Mol. Opt. Phys. (2011)

Resonant enhancement of the cross-polarization coupling in the cavity switching from the EHG 1,1 beam of TE polarization to the EHG 1,2 beam of TM polarization N=0 N=10 N=35 N=70 N=140 a TE G ( EH ) 1,1 a TE G ( EH ) 1,3 a ( EH ) TM G 1,2 Beam amplitude decompositions in two orthogonal polarization components for the input TE beam polarization. Amplitudes of the TE polarization (the first row) and in the TM polarization (the second row) at the middle plane in medium 1 for N = 0, 10, 35, 70, 140 round trips. WS & WN, J. Phys. B. At. Mol. Opt. Phys. (2011)

TE TM cross-polarization switching in the resonator cavity the input beam of TE polarization switch to the output beam is of TM polarization TE / in TM / tot TM / in TE / tot Contribution of beam polarization components to the total beam power after Nth round trips in the resonator; scaled to the input beam power (a) and scaled to the propagating beam power (b). figure (b) clearly confirms the 100% switch from TE polarization to TM polarization of the beam WS & WN, J. Phys. B. At. Mol. Opt. Phys. (2011)

Applications qubit and qudit optical encoding entanglement and hyperentaglement of photons and biphotons quantum information - computing, cryptograghy and teleportation super-resolution imaging, optical cloaking and other sci-fi-like nano-meta-devices nano trapping, manipulation and self-assembling near-field nano-visualisation advances to mention a few other recent research topics conducted in the Research Group of Nanophotonics near-field nano-visualisation plasmonic applications in nano-photonics nano-manipulation and nano-assembling by light

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