Polycrystallinity of Lithographically Fabricated Plasmonic Nanostructures Dominates Their Acoustic Vibrational Damping

Yi, Chongyue; Su, Man-Nung; Dongare, Pratiksha D.; Chakraborty, Debadi; Cai, Yiyu; Marolf, David M.; Kress, Rachael N.; Ostovar, Behnaz; Tauzin, Lawrence J.; Wen, Fangfang; Jones, Matthew R.; Sader, John E.; Halas, Naomi J.; Link, Stephan

doi:10.1021/acs.nanolett.8b00559

Cited by 39 publications

(92 citation statements)

References 65 publications

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“…Although acoustic damping of particles on a substrate seems to be dominated by internal crystalline defects, as recently reported [25], in this letter we report that vibrational modes in single nanostructures can significantly couple to SAWs on the underlying substrate and thereby probed in the acoustic far-field. These SAW excitations induce coherent vibrations in a second nanoantenna at distances much larger than the characteristic amplitude of modes of the source, which are estimated to be on the order of sub-nanometric and even sub-atomic scales [26,27].…”

supporting

confidence: 63%

“…However, the use of periodic arrays has limitations such as the generation of pseudo-SAWs due to scattering into the substrate [21, 23] and inhomogeneous damping caused by the size dispersion of nanostructures. Thus, measurements in single nanostructures are required to further elucidate the acoustic wave damping of the generated coherent phonons [24].Although acoustic damping of particles on a substrate seems to be dominated by internal crystalline defects, as recently reported [25], in this letter we report that vibrational modes in single nanostructures can significantly couple to SAWs on the underlying substrate and thereby probed in the acoustic far-field. These SAW excitations induce coherent vibrations in a second nanoantenna at distances much larger than the characteristic amplitude of modes of the source, which are estimated to be on the order of sub-nanometric and even sub-atomic scales [26,27].…”

supporting

confidence: 54%

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Acoustic Far-Field Hypersonic Surface Wave Detection with Single Plasmonic Nanoantennas

et al. 2018

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2The ability of metallic nanostructures to confine light at sub-diffraction volumes in their near-field allows the local enhancement of inherently weak phenomena such as Raman scattering [1], infrared absorption [2] and higher harmonic generation [3]. The decay of these optical excitations, given the large absorption cross-sections and fast electronic relaxation processes, make nanostructured conducting materials efficient local transducers of far-field electromagnetic radiation into mechanical energy. In addition, the strong optical modulation provided by the launched coherent acoustic modes in these nanostructures allow their exploitation as exquisitely sensitive mechanical probes of their near environment. The efficient generation of acoustic waves by nanostructured transducers and the strong self-modulation provided by the launched coherent phononic modes have enabled their application as, for instance, light-source modulators [4], photoacoustic amplifiers [5] and mass sensors [6] [7].The spectrally narrow acoustic modes obtained in these nanostructures are defined by the resonator's constitution and multiple boundary conditions such as size, shape, composition, their substrate and embedding media. This parameter space has been systematically explored where resonances were tuned by changes in adhesion layer thickness [8], mechanical constraints [9], by positioning resonators over trenches [10] and even by mode-interference from a delayed two-pump excitation scheme [11]. Equally importantly, the damping of acoustic vibrations, which defines the spectral linewidth of modes, is a prominent aspect in the application of these systems, and has also received considerable attention, being successfully modelled for infinite isotropic environments [10,[12][13][14][15][16]. However the multiple decay mechanisms in environments without spherical or cylindrical symmetry, such as when particles lie on a substrate, remain poorly understood [17]. In these cases, to determine the damping and quality factors of resonances current practice, [18], is to use empirical fitting of the decaying modulated time-domain signals.Among different contributions to the measured effective damping of a particular phononic mode, the radiation of acoustic waves to the embedding matrix or the substrate, is qualitatively assessed via the mismatch in acoustic impedance (Z) between the vibrating object and its environment. In the longitudinal plane wave limit the impedance is given by Z = ρ j c Lj (being ρ j the j medium density and c Lj the corresponding longitudinal wave speed). However, such a qualitative analysis may be misleading as Z is a mode-dependent parameter, and for which low-damping can be obtained even for perfect impedance match [16]. Accordingly, theoretical calculations have systematically predicted shorter acoustic damping times for particles in solid matrixes and longer damping times for liquid environments when compared to experimental values [18]. Nevertheless, the damping through the coupling of nanostructures to the substrate ...

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confidence: 63%

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confidence: 54%

Acoustic Far-Field Hypersonic Surface Wave Detection with Single Plasmonic Nanoantennas

et al. 2018

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“…In general, the total quality factor for a given vibrational mode can be expressed as , where is the intrinsic damping quality factor, and corresponds to the environment damping. Normally intrinsic damping of chemically synthesized nanoparticles is relatively small 17,39 , although it may become dominant with lithographically fabricated plasmonic nanostructures where the crystal defects were abundant 18 . The measured quality factor for Au nanoplates on Lacey carbon films is remarkable, especially considering that molecular capping ligands were presented, as can be seen from the TEM measurements in Supplementary Fig.…”

Section: Discussionmentioning

confidence: 99%

“…However, these plasmonic nanoresonators suffer from both intrinsic and environmental energy dissipation mechanisms that reduce the vibrational quality factors. The intrinsic damping effect can be reduced by using single crystal nanoparticles created by chemical synthesis, rather than the polycrystalline particles produced by lithography 17,18 . Environmental damping for plasmonic nanoresonators predominantly occurs by radiation of acoustic waves into the surroundings 19 .…”

Section: Introductionmentioning

confidence: 99%

Strong vibrational coupling in room temperature plasmonic resonators

Wang

Yang

et al. 2019

Nat Commun

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Strong vibrational coupling has been realized in a variety of mechanical systems. However, there have been no experimental observations of strong coupling of the acoustic modes of plasmonic nanostructures, due to rapid energy dissipation in these systems. Here we realized strong vibrational coupling in ultra-high frequency plasmonic nanoresonators by increasing the vibrational quality factors by an order of magnitude. We achieved the highest frequency quality factor products of f × Q = 1.0 × 10 13 Hz for the fundamental mechanical modes, which exceeds the value of 0.6 × 10 13 Hz required for ground state cooling. Avoided crossing was observed between vibrational modes of two plasmonic nanoresonators with a coupling rate of g = 7.5 ± 1.2 GHz, an order of magnitude larger than the dissipation rates. The intermodal strong coupling was consistent with theoretical calculations using a coupled oscillator model. Our results enabled a platform for future observation and control of the quantum behavior of phonon modes in metallic nanoparticles.

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“…We note that while neither silicon nor gold are isotropic materials [42] (characterized by elastic anisotropic ratios A Si ≈ 1.6 and A Au ≈ 0.6), their simplified description does not incur significant shifts of resonant frequencies nor changes in Purcell factors. Additionally, we have verified by full numerical calculations that when viscous damping in gold is included through the complex Young's modulus [43] the quality factors and the Purcell factors characterizing higher-order elastic modes are significantly quenched. While further studies of viscous damping are required to understand its exact magnitude, this mechanism will likely promote the use of lowest-order elastic modes in nanostructures for enhancing radiative emission from localized emitters.…”

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confidence: 74%

Elastic Purcell Effect

et al. 2018

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In this work, we introduce an elastic analog of the Purcell effect and show theoretically that spherical nanoparticles can serve as tunable and robust antennas for modifying the emission from localized elastic sources. This effect can be qualitatively described by introducing elastic counterparts of the familiar electromagnetic parameters: local density of elastic states, elastic Purcell factor, and effective volume of elastic modes. To illustrate our framework, we consider the example of a submicron gold sphere as a generic elastic GHz antenna and find that shear and mixed modes of low orders in such systems offer considerable elastic Purcell factors. This formalism opens pathways towards extended control over dissipation of vibrations in various optomechanical systems and contributes to closing the gap between classical and quantum-mechanical treatments of phonons localized in elastic nanoresonators.

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Polycrystallinity of Lithographically Fabricated Plasmonic Nanostructures Dominates Their Acoustic Vibrational Damping

Cited by 39 publications

References 65 publications

Acoustic Far-Field Hypersonic Surface Wave Detection with Single Plasmonic Nanoantennas

Acoustic Far-Field Hypersonic Surface Wave Detection with Single Plasmonic Nanoantennas

Strong vibrational coupling in room temperature plasmonic resonators

Elastic Purcell Effect

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