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Dispersion relation for SPP is used to obtain phasematching and efficient coupling is obtained at the intersection point with the SPP dispersion

Dispersion relation for SPs. The arrow indicates the change of a dispersion relation of LSPR relative to conventional SPR

Dispersion relation for the linear chain of

Dispersion relation for the uppermost energy levels for the Ex. The energy surface has fourfold symmetry about the origin. The result is compared with the photoemission data of Shen et al also shown in the lower part of die figure.

Dispersion relation for uppermost energy levels for the EJ, bands discussed in the text for a given k k k. The energy surface has fourfold symmetry about the origin. The result is compared with the photoemission data of Shen et al also shown in the lower part of the figure.

Dispersion relation for uppermost energy levels for the isx. The energy surface has fourfold symmetry about the origin. The result is compared with the photoemission data of Shen et al also shown in the lower part of the figure.

Dispersion relation o for the one-dimensional crystal in

Dispersion relation obtained if solid is characterized by linear elastic constitutive model.

Dispersion relation of MIM structure with the insulator region is air and is 0.5Ap thiek and two metal layers are semi-infinitely thick. The fi-equency and the wave vector are normalized with respect to rap and kp where kp op c c is the speed of light in air and top is the plasma frequency. Inset shows the MIM structure, eoo and cap are chosen as 9.6 and 3.76 for Ag, respectively.

Dispersion relation of MIM structure with the insulator region is air and is O.SAp thick and two metal layers are both 0.25Xp thick. Inset shows the MIM structure.

Dispersion relation of orientation fluctuation in nematic phase

Dispersion relation of single gold nanorods . Closed circles

Dispersion relation of the deposition of a thin dielectric layer.

Dispersion relation of the fast relaxation rate measured in VIS sample at room temperature, Solid line is a fit to . Vertical arrows indicate starting points of the increasing relaxation rate according to the size of the droplets as deduced from the SEM study. The dashed lines are guide to the eye. Reprinted with permission from . Copyright by the American Physical Society

Dispersion relation of the Fourier transformation of the orbital interaction in the honeycomb lattice orbital

Dispersion relation of the half-filled valence band of a 1-D conductor. Upon dimerization, the Brillouin zone is halved, and a gap A opens at the new zone boundary

Dispersion relation of the orbital interaction in represented in the Brillouin zone for a simple cubic lattice

Dispersion relation of the orbital interaction of the two-dimensional orbital compass model in represented in the BriUouin zone for the square lattice

Dispersion relation of the soft mode in K2Se04-

Dispersion relation, to versus k, is plotted for a cluster of 950 water molecules. A linear fit is plotted with a slope of 14 A ps 1.

Dispersion relation, w vs for a linear chain of atoms.

Dispersion relations and densities of crystal directions, d and 62 are the directions state in the naphthalene crystal. Left

Dispersion relations for diamond along are based on a valence force model described in the text

Dispersion relations for magnetic excitations in PrjTI. The low temperature neutron measurements of Birgeneau, 1973 Birgeneau et al., 1972b, are to be compared with the average of the three broken lines obtained from the pseudo-boson model at 0 K. Above Tc at T 21.3 K, the solid lines indicate the predictions of the RPA-en-hanced dynamical susceptibility theory described in the text and show the strong mode-mode interaction with the excited state rj r4 transition .

Dispersion relations for magnetic excitations propagating on the hexagonal sites of dhcp Pr at 6.4 K. The circles represent acoustic-type modes and the squares optic-type modes .



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