Optical dielectric function of gold

Olmon, Robert L.; Slovick, Brian; Johnson, Timothy W.; Shelton, David; Oh, Sang Hyun; Boreman, Glenn D.; Raschke, Markus B.

doi:10.1103/physrevb.86.235147

Cited by 817 publications

(752 citation statements)

References 36 publications

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“…This detailed comparison was performed in the spirit of previous work on plasmonic materials that has noted considerable discrepancies between published dielectric functions. 26 While the full band structure of Ga is complex, the primary features of the solid phase Ga dielectric function can be attributed to Drude-like free electron oscillations in the blue-UV spectral regime, and to interband transitions in the green-red region of the spectrum. 2,4,5 These interband transitions damp plasmonic behavior beyond the visible (λ 0 > 700 nm) based on the well-known SPP resonance condition (ε r < À2) for spherical particles.…”

Section: Resultsmentioning

confidence: 99%

Gallium Plasmonics: Deep Subwavelength Spectroscopic Imaging of Single and Interacting Gallium Nanoparticles

et al. 2015

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Gallium has recently been demonstrated as a phasechange plasmonic material offering UV tunability, facile synthesis, and a remarkable stability due to its thin, self-terminating native oxide. However, the dense irregular nanoparticle (NP) ensembles fabricated by molecular-beam epitaxy make optical measurements of individual particles challenging. Here we employ hyperspectral cathodoluminescence (CL) microscopy to characterize the response of single Ga NPs of various sizes within an irregular ensemble by spatially and spectrally resolving both in-plane and out-of-plane plasmonic modes. These modes, which include hybridized dipolar and higher-order terms due to phase retardation and substrate interactions, are correlated with finite difference time domain (FDTD) electrodynamics calculations that consider the Ga NP contact angle, substrate, and native Ga/Si surface oxidation. This study experimentally confirms previous theoretical predictions of plasmonic size-tunability in single Ga NPs and demonstrates that the plasmonic modes of interacting Ga nanoparticles can hybridize to produce strong hot spots in the ultraviolet. The controlled, robust UV plasmonic resonances of gallium nanoparticles are applicable to energy-and phase-specific applications such as optical memory, environmental remediation, and simultaneous fluorescence and surface-enhanced Raman spectroscopies.

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Section: Resultsmentioning

confidence: 99%

Gallium Plasmonics: Deep Subwavelength Spectroscopic Imaging of Single and Interacting Gallium Nanoparticles

et al. 2015

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“…However, similar to the case of gold [16], large variations exist among historical measurements of the dielectric function of silver, especially for the imaginary part near the interband transition in the visible/ultraviolet (Vis/UV) region. [17] Most of these measurements only cover a narrow energy range, making a direct comparison between the different experiments difficult.…”

Section: Introductionmentioning

confidence: 99%

“…[18][19][20][21][22][23][24][25] Accurate values for the dielectric function of silver are needed in the visible and infrared (IR) spectral ranges, because many important parameters, such as surface plasmon propagation length, plasmon lifetime, non-radiative loss, and even the Casimir force, are sensitively linked to small variations of the dielectric function. [16] In this work, we provide a comprehensive measurement of the optical dielectric function (ω) of evaporated and template-stripped polycrystalline silver using spectroscopic ellipsometry, covering a broad spectral range throughout the mid-IR to Vis/UV of two orders of magnitude, from 0.05 eV to 4.14 eV (25 µm to 300 nm). We analyze the free electron behavior below the interband transition using the Drude model with plasma frequency ω p , dielectric function at infinite frequency ∞ , and relaxation time τ = 1/Γ.…”

Section: Introductionmentioning

confidence: 99%

Optical dielectric function of silver

et al. 2015

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The dielectric function of silver is a fundamental quantity related to its electronic structure and describes its optical properties. However, results published over the past six decades are in part inconsistent and exhibit significant discrepancies. The measurement is experimentally challenging with the values of dielectric function spanning over five orders of magnitude from the mid-infrared to the visible/ultraviolet spectral range. Using broadband spectroscopic ellipsometry, we determine the complex valued dielectric function of evaporated and template stripped polycrystalline silver films from 0.05 eV (λ = 25 µm) to 4.14 eV (λ = 300 nm) with a statistical uncertainty of less than 1%. From Drude analysis of the 0.1 -3 eV range, values of the plasma frequency ω p = 8.9 ± 0.2 eV, dielectric function at infinite frequency ∞ = 5 ± 2, and relaxation time τ = 1/Γ = 17 ± 3 fs are obtained, with the absolute uncertainties estimated from systematic errors and experimental repeatability. Further analysis based on the extended Drude model reveals an increase in τ with decreasing frequency in agreement with Fermi liquid theory, and extrapolates to τ 22 fs for zero frequency. A deviation from simple Fermi liquid behavior is suggested at energies below 0.1 eV (λ = 12 µm) with the onset of a further increase in τ connecting to the DC value from transport measurements of ∼ 40 fs. The results are consistent with a wide range of optical and plasmonic experiments throughout the infrared and visible/ultraviolet spectral range. The influence of grain boundaries, defect scattering, and surface oxidation is discussed. The results are compared with our previous measurements of the dielectric function of gold [Phys. Rev. B 86, 235147 (2012)].

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“…In physics, studying optical properties of materials is perhaps the most powerful tool for investigating their electronic and vibrational properties [1][2][3][4]. As such, in metals, the subject has been studied for some time, and continue to be studied actively to this day [5][6][7]. Properties of reflection are known to depend on the wavelength of light, temperature and the material [1][2][3][4]8], and can further depend on geometric aspects of the material, such as its size and thickness.…”

Section: Introductionmentioning

confidence: 99%

Observation of reflectance fluctuations in metals

Mitsui¹,

Aoki²

2017

Phys. Rev. A

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Through the study of the power spectra of a monochromatic light beam reflected by metallic mirrors, fluctuations in their reflectance is observed. The power spectra were obtained down to a factor 10 −6 below the Standard Quantum Limit, with a dynamic range of 10 5 in the frequency and power, using methods we developed. The properties of the spectra are investigated and their dependence on the material is analyzed. The physics underlying the phenomenon is also discussed. These fluctuations provide a new window into the degrees of freedom responsible for the reflection process in metals.

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Optical dielectric function of gold

Cited by 817 publications

References 36 publications

Gallium Plasmonics: Deep Subwavelength Spectroscopic Imaging of Single and Interacting Gallium Nanoparticles

Gallium Plasmonics: Deep Subwavelength Spectroscopic Imaging of Single and Interacting Gallium Nanoparticles

Optical dielectric function of silver

Observation of reflectance fluctuations in metals

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