Bound-Electron-Lattice Coupling and Vibronic Spectra

Bron, W. E.

doi:10.1103/physrev.140.a2005

Cited by 43 publications

(17 citation statements)

References 33 publications

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“…The optical properties of rare earth ions in alkali halides have been found to agree fairly well with the predictions of MNT [3] and may be summarized as follows.…”

Section: Discussionmentioning

confidence: 72%

“…Therefore the main difference between the two types of transitions consists of short-range interaction (quadrupole) for the interconfigurational transitions and long-range interaction (dipole) for the intraconfigurational transitions. It has been recognized [3] that a remarkable consequence of these forces is a) the coupling of the electron transition with local (perturbed by the impurity) phonons in the case of short-range forces (interconfigurational transitions) and b) the coupling with crystal phonons (not perturbed) in the case of long-range forces (intraconfigurational transitions). Furthermore, the electron-phonon interaction is stronger in the interconfigurational case since the f $d change of orbital causes a set of forces stronger than those accompanying the f f transition.…”

Section: Theoretical Surveymentioning

confidence: 99%

“…I n the present analysis we shall confine ourselves to the rare earth ions, namely Eu++ and Sm++, in alkali halides and will discuss only those elements of the theory which are essential in order to understand the experimental results. The electron-phonon interaction has been discussed by Wagner and Bron [2], by Bron [3], and recently also by MNT [4], who have given a comprehensive treatment for impurities that are not loosely bound. This certainly applies to the tightly bound rare earth ions in alkali halides and therefore we shall follow the lines of the MNT work.…”

Section: Theoretical Surveymentioning

confidence: 99%

“…Generally the experimental results have been interpreted in terms of electron-phonon coupling theories which involve a Debye spectrum. Recently, however, the experiments have shown that the sidebands are directly connected with the actual density of phonons; therefore efforts have been made in order to describe the electronphonon interaction using the true density of states as shown by Bron and Wagner [2], Bron [3], and very recently by Mulazzi, Nardelli, and Terzi (MNT) Our investigation has been devoted mainly to the behaviour of the zerophonon line at low temperatures in order to derive the parameters involved in the electron-phonon interaction of Eu++ and Sm++ in alkali halides. The data have been compared with the theoretical analysis of Nardelli and co-workers [4] which we review and discuss in Section 2.…”

Section: Introductionmentioning

confidence: 99%

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Zero‐Phonon Transitions of Eu⁺⁺ ‐ and Sm⁺⁺ ‐Doped Alkali Halides

Baldini

Guzzi

1968

Physica Status Solidi (b)

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The theory of the electron-phonon coupling for impurity centres in ionic crystals is reviewed in order to point out the most significant parameters involved in the optical properties of the zero-phonon lines. The absorption and emission spectra of alkali halides doped with Eu++ and Sm++ have been measured for temperatures ranging from 15 up to 175 O K . In general the analysis of the experimental data agrees fairly well with the theory. The Huang-Rhys factor has been determined and also the effective frequencies which are responsible for the thermal behaviour of the spectra. However the electron-phonon interaction alone has been found not to be sufficient in order to explain the thermal dependence of the zero-phonon line strength and an additional mechanism for its thermal de-excitation has been proposed.Nous avons reexamine la theorie du couplage electron-phonon pour les centres localishs dans les cristaux ioniques pour mettre en evidence les parametres impliques dans les proprietes optiques des raies sans phonons. On a mesure les spectres d'absorption et d'emission des ions Eu++ et Sm++ dans les halogenures alcalins t i des temperatures comprises entre 15 et 175 OK. En general les resultata experimentaux sont en bon accord avec la thhorie. Nous avons determine le facteur de Huang et Rhys et les frequences effectives qui sont responsables de la variation des spectres avec la temperature. Le couplage electron-phonon n'est pas suffisant pour expliquer la variation avec la temperature de l'intensite de la raie sans phonons; nous avons propose un mecanisme additionnel pour la deexcitation thermique de la raie sans phonons.

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“…The optical properties of rare earth ions in alkali halides have been found to agree fairly well with the predictions of MNT [3] and may be summarized as follows.…”

Section: Discussionmentioning

confidence: 72%

Section: Theoretical Surveymentioning

confidence: 99%

Section: Theoretical Surveymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Zero‐Phonon Transitions of Eu⁺⁺ ‐ and Sm⁺⁺ ‐Doped Alkali Halides

Baldini

Guzzi

1968

Physica Status Solidi (b)

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“…Experimental vibronic sidebands accompanying electronic transitions of Sm + + impurities in alkali halides and the theory of vibronics have been presented in a series of papers by BRON, WAGNER and coworkers (BRON and HELLER, 1964;BRON, 1965BRON, , 1969BRON and WAGNER, 1965WAGNER, 1964bWAGNER, , 1965WAGNER, , 1967bWAGNER, , 1968bWAGNER and BRON, 1965;KOHNER andWAGNER, 1970, 1972;KOHNER et aI., 1972;BRON, 1975), previously measured by KAPL YANSKII andFEOFILOV (1962, 1964) with later contributions by the McMASTER research group (TIMUSK and BUCHANAN, 1967;TIMUSK et aI., 1968;BUCHANAN and WOLL, 1969) and, e.g., IGNATEV and OVSYANSKIN (1977). A spectrum of CaF 2 :Eu 3 + has been observed by Ward and Whippey (1974).…”

Section: D)mentioning

confidence: 98%

Vibrational Infrared and Raman Spectra of Non-Metals

Bilz¹,

Strauch²,

Wehner³

1984

Light and Matter Id / Licht Und Materie Id

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The vibrational properties of crystals determine the photon infrared absorption, inelastic neutron scattering and, to a large extent, inelastic photon scattering by phonons, i.e., Raman scattering. The interpretation of infrared and Raman spectra requires, therefore, an understanding of the basic features of lattice dynamics. The quantum theory of solids describes the crystal properties in terms of elementary excitations and their mutual interactions. Dynamic properties are represented by phonons (lattice vibrations) and their interactions mainly with other phonons (anharmonicity), electrons (electron-phonon coupling), and photons (interaction with radiation). This characterizes the scope of the article. Its emphasis is on the interrelation between theory and experiment, i.e., on the microscopic or model interpretation of experimental spectra.Work on infrared absorption and Raman scattering of non-metallic solids was summarized twenty years ago in two review articles in this Encyclopedia by LECOMTE (1958) and by MIZUSHIMA (1958). Since then, many important new experimental data have become available, thanks to very refined techniques for measuring spectra of pure and imperfect single crystals. Furthermore, the theory of the interactions of phonons and photons has been much improved, stimulated by the remarkable development of the theory of lattice vibrations and the mathematical techniques of many-body physics.In this article we describe the dispersion and absorption of infrared radiation and Raman scattering in non-metallic crystals, both perfect and containing point defects. At present, quantitative calculations are usually restricted to diatomic crystals, especially those with simple structures such as the alkali halides or germanium and its homologues, since our knowledge of lattice vibrations is still rather poor for polyatomic and low-symmetry crystals. The theory of lattice vibrations, as reviewed by COCHRAN and COWLEY (1967) in Vol. XXV /2a of this Encyclopedia, constitutes the background and the natural starting point for our investigations. There are other recent reviews by LUDWIG (1967), COCHRAN (1971), MARADUDIN et al. (1971), SINHA (1973), and several articles in: HORTON and MARADUDIN (eds., 1974). A summary of the developments during the last few years is given in Chap. B.An important part of the theory of lattice vibrations is the construction of models. A good example is the so-called shell model for phonons (see Sect. 4) which describes the adiabatic linear electron-ion interaction in terms of localized charges and coupling constants. This provides a natural explanation of some long-range ion-ion forces in insulators in terms of induced dipole forces. Anharmonic extensions of this shell model and its modifications seem very desirable, and first attempts in this direction are discussed.Models can often give a qualitatively and sometimes quantitatively correct description of certain processes in terms of a few parameters. They provide, therefore, an orientation for microscopic approaches. Furthermo...

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