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This presentation discusses the properties of twisted photons, which have a large angular momentum projection on the direction of propagation. It explores the generation, formalism, and absorption of twisted photons, as well as their potential for atomic excitations. The presentation also covers the transfer of orbital angular momentum and the use of twisted photon states.
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The Angular Momentum of Gauge Fields:The Case of Twisted Photons Andrei Afanasev The George Washington University Washington, DC QCD Evolution Workshop Jefferson Lab, Newport News, VA May 9, 2012
Objectives • Consider Abelian gauge fields (QED) • Discuss the properties of of photon beams with a large angular momentum (>ħ) projection on the direction of propagation • Generation • Formalism • Absorption by atoms
Introduction • Photons carry linear momentum p=ħk(k=wave vector) • Photons carry both spin angular momentum (SAM) and orbital angular angular momentum (OAM) – may be separated in paraxial approximation • Circularly polarized plane-wave photons carry Jz=±ħalong the propagation direction z(Beth’s experiment, 1936) • Heitler, Quantum Theory of Radiation (1954): larger Jz possible if the EM wave is constrained in the transverse plane (cylindrical waves) • Spherical waves: expansion in terms of angular momentum eigenfunctions, position dependence of vector potential Aμ(x) contains OAM information • Beams of light with azimuthal beam dependence exp(ilϕ) (e.g, Laguerre-Gaussian modes) can carry large values of OAM (Allen et al, 1992). Review: Yao, Padgett, Advances in Optics and Photonics3, 161–204 (2011) and references therein
Twisted Photons • Quantization of light beams having azimuthal phase dependence exp(ilϕ) lead to a concept of twisted photons G. Molina-Terriza, J.Torres, L. Torner, “Twisted Photons”, Nature Physics,May 2007. The typical transverse intensity pattern of a light beam with orbital angular momentum, (a) theory (b) experiment. The light beam exhibits a dark spot in the center, and a ring-like intensity profile. (c) Azimuthal dependence of beam phase results in a helical wavefront. (d) Orientation of the local momentum of the beam has a vortex pattern (hence another name, an optical vortex).
Generation of Light Beams with Orbital Angular Momentum • A diffraction grating with fork dislocation centered on the beam axis, could convert the fundamental Gaussian mode from any laser into a helically phased mode [V. Bazhenov, M. V. Vasnetsov, and M. S. Soskin, “Laser-beams with screw dislocations in their wave-fronts,” JETP. Lett. 52, 429–431 (1990).] Commonly accepted method for producing helically phased beams. • Spiral Phase Plates: Gaussian beam is passed through optical media, with azimuthal dependence in thickness
Generation of Twisted Photons with Helical Undulators • E. Hemsing, A. Marinelli, and J. B. Rosenzweig, “Generating Optical Orbital Angular Momentum in a High-Gain Free-Electron Laser at the First Harmonic,”Phys. Rev. Lett. 106, 164803 (2011). • AA, Mikhailichenko, On Generation of Photons Carrying Orbital Angular Momentum in the Helical Undulator, E-print: arXiv 1109.1603 • Considered properties of synchrotron radiation by charged particles passing through a helical undulator. Shown that all harmonics higher than the first one radiated in a helical undulator carry OAM. Large K-factors favor large values of OAM for generated radiation.
Helical Undulators (cont) • AA, Mikhailichenko, On Generation of Photons Carrying Orbital Angular Momentum in the Helical Undulator, E-print: arXiv 1109.1603
Transfer of Angular Momentum • For optical wavelengths, transfer of Orbital AM differs from Spin AM. • Important: wavelength vs the target size • Wavelength >> target size: OAM transfer results in linear momentum of the target as a whole • Wavelength < target size: OAM results in target rotation
Absorption of Twisted Photons • Translation or rotation? • Mechanism depends on the dimensions of target vswavefront cross section S • Depending on a topological number and pitch angle, wavefront cross section may be from a few to a few hundred wavelengths • If the target size is of the order S or larger, an essential fraction of photon energy is transferred to rotation of the target. • For smaller targets, rotation is more likely is the target is next the center of the optical vortex
Atomic Excitations with High-L Photons • Twisted photons may enhance (relatively) atomic transitions with large transfer of angular momentum (Picon et al, 2010; AA, Carlson, Mukherjee, arXiv:1304.0115). • An atom must be close (relative to wavelength) to the beam axis, but there is a dip in intensity there. Result: the probability to excite high-L atomic levels is suppressed • Reason: optical wavelength >> atomic size, atomic transitions are caused by long-wavelength photons because the bound electrons are non-relativistic • Situation will change in hadronic physics: need photons with wavelength < fm to excite a nucleon.
Twisted Photon State • Use plane-wave expansion • Plane wave: • Twisted wave:
Fields of the Twisted Wave • Vector potential Magnetic field • Poynting vector
Transverse Beam Profile • OAM light beam is characterized with a special transverse profile (example from AA, Carlson, Mukherjee,) • Intensity dip on the beam axis, with transverse size > wavelength
Atomic Photoexcitation • Interaction Hamiltonian: • Matrix element of the transition: • b- an impact parameter w.r.t. the atomic center
Matrix Element of Photoexcitation • Photo-excite a hydrogen atom from the ground to the state with a principal quantum number nf, OAM lf, and OAM projection mf. Incoming twisted photon is defined by AM projection mγ, energy ω and a pitch angle θk(with κ=kperp) • Matrix element: • Atomic factors
Calculation Results • Matrix elements as a function of an impact parameter b
Helicity Asymmetry • Flip photon helicityΛ, keep the OAM projection the same => • Results a different twisted photon state with mγmγ-2Λ • Photoabsorption cross sections are different for a given impact parameter => (parity-conserving) helicity asymmetry • The largest asymmetry is near the center of optical vortex • Asymmetry is zero after averaging over the impact parameter b • May be observed for small-size targets or near-field geometry
Twisted Photons for Hadrons vs Atoms • For atomic transitions photon OAM is preferably transferred to internal degrees of freedom if the target is near the center of an optical vortex • OtherwiseOAM results in linear momentum of the entire atom • For excitation of a baryon with a twisted photon, γTN->N* OAM will be passed to internal degrees of freedom and will help to get insight into nucleon structure • Will need more helicity amplitudes to describe a baryon resonance excitation
How to Generate Twisted Photons in MeV-GeV? • Serboet al proposal (2010): Compton backscattering. U.D. Jentschura V.G. Serbo Generation of High-Energy Photons with Large Orbital Angular Momentum by Compton Backscattering. Phys.Rev.Lett. 103 (2011) 013001, e-Print: arXiv:1008.4788; Compton Upconversion of Twisted Photons: Backscattering of Particles with Non-Planar Wave Functions. Eur.Phys.J. C71 (2011) 1571, arXiv:1101.1206. • Theoreticallydemonstratedthat OAM properties of twistedphotonsarepreserved in Comptonbackscattering. • Ifholds, it provides a newtool in nuclear, hadronicandhigh-energyphysics, thatarephotonbeamswithpre-selected OAM alongtheirdirection of propagation.
Summary • Twisted photons carry large orbital angular momenta along the axis of propagation • Can be applied at widely different scales, from dust particles, to nanoparticles, molecules, (Rydberg) atoms, and nuclei • Atomic photoexcitation considered here • Results in excitation of states with a range of quantum numbers, different from plane waves • Predicted parity-conserving helicity asymmetry in the central region of an optical vortex: flipping the helicity results in a different photon state • Accelerator-based light source are most efficient for generating twisted X-rays and gamma-rays
Outlook • Is it possible to generate twisted photons with GeV energies to probe the structure of hadrons? • Are the cross sections or spin asymmetries of basic QED processes involving twisted photons affected by their additional angular momentum? • Can (inelastic) polarized electron scattering on a twisted photon provide an information on its angular momentum? (=polarization structure functions of a twisted photon, TMDs, GPDs, etc) • Extension to non-Abelian fields=> “twisted gluons”