Modulation of a surface plasmon-polariton resonance by subterahertz diffracted coherent phonons

Brüggemann, Christian; Акимов, А. В.; Glavin, B. A.; Belotelov, V. I.; Акимов, И. А.; Jäger, J. V.; Kasture, Sachin; Gopal, Achanta Venu; Vengurlekar, A. S.; Yakovlev, D. R.; Kent, A. J.; Bayer, М.

doi:10.1103/physrevb.86.121401

Cited by 20 publications

(14 citation statements)

References 35 publications

(36 reference statements)

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“…Based on these principles, surface plasmon resonant sensors for the detection of chemical and biological species are developed [3]. In addition, one can use an external stimulus such as optical excitation [4][5][6][7][8], acoustic waves [9][10][11][12] and external magnetic fields [13][14][15][16] in order to influence the dielectric function of metal and/or dielectric and subsequently to control the SPP propagation constant. Therefore, SPPs are well suited for applications in optoelectronic devices where high sensitivities * lars.kreilkamp@tu-dortmund.de and efficient optical excitation at the nanoscale are essential [8].…”

Section: Introductionmentioning

confidence: 99%

Terahertz dynamics of lattice vibrations in Au/CdTe plasmonic crystals: Photoinduced segregation of Te and enhancement of optical response

et al. 2016

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Excitation of coherent optical phonons in solids provides a pathway for ultrafast modulation of light on a sub-ps timescale. Here, we report on efficient 3.6 THz modulation of light reflected from hybrid metal/semiconductor plasmonic crystals caused by lattice vibrations in a few nm thick layer of elemental tellurium. We observe that surface plasmon polaritons contribute significantly to photoinduced formation of this thin layer at the interface between a telluride-based II-VI semiconductor, such as (Cd,Mg)Te or (Cd,Mn)Te, and a one-dimensional gold grating. The change in interface composition is monitored via the excitation and detection of coherent optical tellurium phonons of A1 symmetry by femtosecond laser pulses in a pump-probe experiment. The patterning of a plasmonic grating onto the semiconductor enhances the transient signal which originates from the interface region. This allows monitoring the layer formation and observing the shift of the phonon frequency caused by confinement of the lattice vibrations in the nm-thick segregated layer. Efficient excitation and detection of coherent optical phonons by means of surface plasmon polaritons are evidenced by the dependence of the signal strength on polarization of pump and probe pulses and its spectral distribution.

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Section: Introductionmentioning

confidence: 99%

Terahertz dynamics of lattice vibrations in Au/CdTe plasmonic crystals: Photoinduced segregation of Te and enhancement of optical response

et al. 2016

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“…This method can be used with magneto-optical materials [134]. Light pulses can induce phase transitions in materials, such as vanadium dioxide, which are accompanied by large refractive index changes [135], or light can induce mechanical strain to change the periodicity of a grating, thereby modulating the propagating plasmon [136]. A variant on this method was to use a light pulse to induce scattering centers by the local decomposition of silver oxide [137].…”

Section: Modulation By External Lightmentioning

confidence: 99%

Plasmonic circuits for manipulating optical information

2016

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Surface plasmons excited by light in metal structures provide a means for manipulating optical energy at the nanoscale. Plasmons are associated with the collective oscillations of conduction electrons in metals and play a role intermediate between photonics and electronics. As such, plasmonic devices have been created that mimic photonic waveguides as well as electrical circuits operating at optical frequencies. We review the plasmon technologies and circuits proposed, modeled, and demonstrated over the past decade that have potential applications in optical computing and optical information processing.

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“…Most of these works with coherent phonons targeted specific properties of the nanostructures by probing the electromagnetic field inside the studied nanostructure. Thus, the interaction of the vibrational phonon modes and light was studied experimentally by picosecond acoustic techniques in periodic structures which possess both photonic and phononic band gaps (i.e., photonic-phononic crystals), 9,10 hole arrays, 11 metallic gratings, [12][13][14] and complex periodic plasmonic nanostructures. 15 Less attention was paid to the elasto-optical effects that occur in bulk solid media at a distance from the nanostructure larger than the optical wavelength, where light has a well-defined wavevector and a corresponding propagation direction.…”

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confidence: 99%

Studying periodic nanostructures by probing the in-sample optical far-field using coherent phonons

Brüggemann

Jäger

Glavin

et al. 2012

Applied Physics Letters

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Optical femtosecond laser pulses diffracted into a crystalline substrate by a gold grating on top interact with gigahertz coherent phonons propagating towards the grating from the opposite side. As a result, Brillouin oscillations are detected for diffracted light. The experiment and theoretical analysis show that the amplitude of the oscillations for the first order diffracted light exceeds that of the zero order signal by more than ten times. The results provide a method for internal probing of the optical far-field inside materials containing periodic nanostructures.

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Modulation of a surface plasmon-polariton resonance by subterahertz diffracted coherent phonons

Cited by 20 publications

References 35 publications

Terahertz dynamics of lattice vibrations in Au/CdTe plasmonic crystals: Photoinduced segregation of Te and enhancement of optical response

Terahertz dynamics of lattice vibrations in Au/CdTe plasmonic crystals: Photoinduced segregation of Te and enhancement of optical response

Plasmonic circuits for manipulating optical information

Studying periodic nanostructures by probing the in-sample optical far-field using coherent phonons

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