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Surface Plasmons in Metallic Structures INSTITUTE OF PHYSICS PUBLISHING JOURNAL OF OPTICS A: PURE AND APPLIED OPTICS J. Opt. A: Pure Appl. Opt. 7 (2005) S73–S84 doi:10.1088/1464-4258/7/2/010 Surface plasmons in metallic structures JMPitarke1,2,VMSilkin2,EVChulkov2,3 and P M Echenique2,3 1 Materia Kondentsatuaren Fisika Saila, Zientzi Fakultatea, Euskal Herriko Unibertsitatea, 644 Posta kutxatila, E-48080 Bilbo, Basque Country, Spain 2 Donostia International Physics Centre (DIPC) and Centro Mixto CSIC-UPV/EHU, Manuel de Lardizabal Pasealekua, E-20018 Donostia, Basque Country, Spain 3 Materialen Fisika Saila, Kimika Fakultatea, Euskal Herriko Unibertsitatea, 1072 Posta kutxatila, E-20080 Donostia, Basque Country, Spain Received 22 June 2004, accepted for publication 5 August 2004 Published 20 January 2005 Online at stacks.iop.org/JOptA/7/S73 Abstract Since the concept of a surface collective excitation was first introduced by Ritchie, surface plasmons have played a significant role in a variety of areas of fundamental and applied research, from surface dynamics to surface-plasmon microscopy, surface-plasmon resonance technology, and a wide range of photonic applications. Here we review the basic concepts underlying the existence of surface plasmons in metallic structures, and introduce a new low-energy surface collective excitation that has been recently predicted to exist. Keywords: electrons, surfaces, collective effects, polaritons, optical absorption, many-body, particle–solid interactions 1. Introduction experiments carried out by Powell and Swan [6], who observed inelastic losses experienced by electrons scattered The long-range nature of the Coulomb interaction between from newly evaporated layers of Al and Mg. Since then, valence electrons in metals is known to yield collective there has been a significant advance in both theoretical behaviour,manifesting itself in the form of plasma oscillations. and experimental investigations of collective modes in the Pines and Bohm [1] were the first to suggest that the discrete vacuum–solid interface. energy losses experienced by fast electrons in passing through The concept of the surface plasmon has played a key metals are due to the excitation of these plasma oscillations, role in the understanding of fundamental properties of solids the basic unit of energy being termed the plasmon [2]:h ¯ ωp = and in the interpretation of a large variety of experiments. 2 1/2 h¯ (4πne /me) ,wheren is the valence electron density and For example,theclassical image potential acting between a 4 me is the free-electron mass . point classical charge and a metal surface was shown to be Gabor [3] investigated the excitation of plasma oscillations originated in the shifted zero-point energy of the surface- in thin foils, but assumed that the electric field is always zero plasmon field [7–10], the impact of the surface plasmon on at the surface. As a result, he did not find surface modes in surface energies was addressed [11], the energy loss of charged the bounded plasma and reached the erroneous conclusion that particles moving outside a metal surface was shown to be the probability for plasma loss should decrease strongly with due to the excitation of surface plasmons [12, 13], and the decreasing foil thickness. Ritchie [4] was the first to find that centroid of the electron density induced by external potentials theeffect of the film boundaries is to√ cause the appearance of a acting on a metal surface was demonstrated to be dictated new ‘lowered’ loss ath ¯ ωs = h¯ ωp/ 2 due to the excitation of by the wavevector dependence of surface plasmons [14]. surface collective oscillations, the quanta of which Stern and Explicit expressions for the surface-plasmon dispersion relied Ferrell called the surface plasmons [5]. originally on simple models, such as the hydrodynamic [15], Ritchie’s prediction of surface polarization causing low- specular-reflection [16], and infinite-barrier [17] models. energy losses in metals was confirmed in a series of Accurate numerical calculations have also been performed from the knowledge of the eigenfunctions and eigenvalues 4 The valence electron density n is usually characterized by the density 1/3 of the Kohn–Sham Hamiltonian of density-functional theory parameter rs = (3/4πn) /a0 (a0 is the Bohr radius, a0 = 0.529 Å). In metals (2 < rs < 6), plasmons have energies in the range 5 eV <ωp < 20 eV (DFT) [18], showing nice agreement with the experiments that and frequencies that lie, therefore, in the optical regime. have been carried out on clean, well-characterized surfaces of 1464-4258/05/020073+12$30.00 © 2005 IOP Publishing Ltd Printed in the UK S73 JMPitarke et al the alkali metals [19, 20]. These experiments also showed interaction leading to the formation of Cooper pairs in high-Tc evidence for the existenceoftheso-called multipole surface superconductors [40, 41]. plasmons that had been predicted by Benett [21]. Recently, it has been shown that metal surfaces where a 5 The long-wavelength surface-plasmon energyh ¯ ωs was partially occupied quasi-two-dimensional (2D) surface-state derived by Ritchie in the nonrelativistic approximation, by band coexists in the same region of space as the underlying assuming that the Coulomb interaction is instantaneous. three-dimensional (3D) continuum support a well-defined However, if one is to describe the interaction of either acoustic surface plasmon [42]. This new low-energy collective relativistic electrons or light with solid surfaces, it is necessary excitation exhibits linear dispersion at low wavevectors, to take into account the time needed for the propagation of the andmight therefore affect electron–hole (e–h) and phonon true retarded interaction. As a result of retardation, surface dynamics near the Fermi level6.Ithasbeen demonstrated plasmons couple at wavelengths larger than ∼2πc/ωs with that it is a combination of the nonlocality of the 3D dynamical the free electromagnetic field and yield what is now called a screening and the spill out of the 3D electron density into the surface-plasmon polariton [22]. At these large wavelengths, vacuum which allows the formation of 2D electron-density the surface-plasmon polariton exists over the entire frequency acoustic oscillations at metal surfaces, since these oscillations range from zero to an asymptotic value determined by the would otherwise be completely screened by the surrounding 3D substrate [43]. surface-plasmon frequency ωs.However,the corresponding dispersion curve never crosses the dispersion curve of free- In this paper, we first present an overview of the space electromagnetic radiation. Hence, there is always a basic concepts underlying the existence of surface collective momentum mismatch between light and surface plasmons of excitations in metallic structures, and we then introduce thesame frequency, so light incident on an ideal surface cannot the new concept of acoustic surface plasmons. We begin excite surface plasmons and, conversely, the surface plasmon in section 2 with a brief discussion of therolethat cannot decay by emitting a photon. surface-plasmon excitation plays in the interaction of fast charged particles with solid surfaces, since it is precisely the Teng and Stern [23] were the first to point out that investigationofelectron energy loss in thin foils which brought anysurface roughness permits the surface to impart some Ritchie to the realization that surface collective excitations additional momentum to the surface-plasma oscillation, with exist attheloweredfrequency ω [4]. The detection of surface theresult that it can couple to electromagnetic radiation. s plasmons and their dispersion is discussed in section 3, in Alternatively, prism coupling can be used to enhance the the framework of angle-resolved inelastic electron scattering momentum of incident light, as demonstrated by Otto [24] experiments. Localized surface plasmons and the use of sum and by Kretchmann and Raether [25]. Hence, surface rules that provide insight into surface-plasmon energies in plasmons have been employed in a wide spectrum of metallic structures of arbitrary geometry are introduced in studies from electrochemistry, catalysis, wetting, thin organic section 4. Section 5 is devoted to the retarded region, where condensates, and biosensing [26], to scanning tunnelling surface plasmons couple with the free electromagnetic field. microscopy [27], the ejection of ions from surfaces [28], Acoustic surface plasmons are introduced in section 6. surface dynamics [29], surface-plasmon microscopy [30], Unless stated otherwise, atomic units are used throughout, and surface-plasmon resonance technology [31]. Moreover, 2 i.e., e = h¯ = me = 1. recent advances that allow metals to be structured and characterized on the nanometre scale have rekindled the long-standing interest in surface plasmons, one of the most 2. Plasma losses by fast charged particles in solids attractive aspects of these collective excitations now being Let us consider a recoilless fast point particle of charge Z their use to concentrate light in subwavelength structures [32] 1 moving in an arbitrary inhomogeneous many-electron system andtoenhance transmission through periodic arrays of with nonrelativistic velocity v,forwhichretardation effects subwavelength holes in optically thick metallic films [33, 34], and radiation losses can be neglected7.Thecharge density of as well as the possible fabrication of nanoscale photonic the probe particle is simply a delta function of the form circuits operating at optical frequencies [35]. ext Since the typical energy
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