Near-Field Induced Reaction Yields from Nanoparticle Clusters

Rosenberger, Philipp; Rupp, Philipp; Ali, R.; Alghabra, M. Said; Sun, Shoujin; Mitra, Sambit; Khan, Sharjeel; Dagar, Ritika; Kim, Vyacheslav V.; Iqbal, Mazhar; Schötz, Johannes; Liu, Qingcao; Sundaram, S. K.; Kredel, Julia; Gallei, Markus; Vera, César Costa; Bergues, Boris; Alnaser, A. S.; Kling, Matthias F.

doi:10.1021/acsphotonics.0c00823

Cited by 21 publications

(47 citation statements)

References 28 publications

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“…Their nal energy mainly arises from long-range electrostatic repulsion 22,34 , which occurs over the time scale of picoseconds. It is also worth mentioning that the Coulomb attraction between the fast escaping electrons and the slow ions created on the nanosphere is negligible and has no signi cant effect on the nal ion momenta 22 .…”

Section: Plasma Imaging Resultsmentioning

confidence: 99%

“…It is also worth mentioning that the Coulomb attraction between the fast escaping electrons and the slow ions created on the nanosphere is negligible and has no signi cant effect on the nal ion momenta 22 . Since the trajectories of the ions are also hardly affected by the laser electric eld, a relatively simple and straightforward static electrostatic model 34 is then applicable to correlate the ion momentum distribution with the charge distribution on the surface of the nanosphere.…”

Section: Plasma Imaging Resultsmentioning

confidence: 99%

“…At very low radiation intensities, much progress has been made experimentally in understanding how the nanostructure affects localized plasmons [15][16][17] , owing to the development of detection solutions for the plasmonic spatial distribution from two-dimensional (2D) planar (such as photoemission electron microscopy and near-eld scanning optical microscopy) to three-dimensional (3D) planes [18][19][20][21][22][23] . However, we cannot apply these technologies to image nanoplasmas generated at high radiation intensities because the underlying physics for plasmons is different from that for plasma generated at high radiation intensities as discussed here.…”

Section: Introductionmentioning

confidence: 99%

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Three-dimensional Imaging of Nanoplasma by Ion Nanoscopy

Huang

Zhang

et al. 2021

Preprint

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The remarkable abilities of laser-irradiated nanostructures to emit X-ray photons, accelerate charged particles, and launch shock waves for multiple applications are primarily governed by a localized plasma near the surface. However, the full-spatially resolving the localized plasma is still challenging due to the difficulty of measuring the three-dimensional (3D) momentum of ions generated from partially or fully ablated nanostructures in high-intensity laser fields. Here, we bridge this gap by introducing ion nanoscopy based on the tomographic reconstruction of the 3D momentum of ions emitted from constantly refreshed aerosolized TiO2 nanospheres. The measured 3D ion momenta map the localized plasma charge well through an electrostatic repulsion model. A pronounced variation in localized plasma charge across the nanosphere surface is obtained, which also extends the idea of the combined action of external and internal fields on plasma formation. This work represents an advance in understanding plasma generation from nanostructures and in the probing, visualization, and manipulation of localized nanoplasmas.

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Section: Plasma Imaging Resultsmentioning

confidence: 99%

Section: Plasma Imaging Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Three-dimensional Imaging of Nanoplasma by Ion Nanoscopy

Huang

Zhang

et al. 2021

Preprint

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“…As an example, interesting recent fundamental works dealing with the directional emission of electrons and ions from isolated nanoparticles induced by femto-and attosecond laser impulses can be mentioned. 597,598 The combination of nm-scale sampling on sub-fs time scales could open new analytical possibilities for the monitoring of near-eld induced reaction yields on the surface of nanoparticles ("reaction nanoscopy") 599 or for the differentiation of single particles and their dimers based on their plasmonic characteristics, 600 to name just a couple of options.…”

Section: Discussionmentioning

confidence: 99%

Nanoparticles in analytical laser and plasma spectroscopy – a review of recent developments in methodology and applications

Galbács

Kéri

Kohut

et al. 2021

J. Anal. At. Spectrom.

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“…The source aerosolizes a colloid of nanoparticles that are subsequently dried by a solid-state counter-flow membrane dryer to remove the solvent (water) from the carrier gas (N 2 ). Additional care was taken to minimize the probability of clusters in the nanoparticle beam to prevent an amalgamation of photoelectrons from monomers and clusters [2] by keeping the number density below 10 10 nanoparticles per mL. The in-vacuum beam density was increased using an aerodynamic lens system to focus the gas-phase nanoparticles while a three-stage differentially pumped arrangement removed excess carrier gas in vacuum.…”

mentioning

confidence: 99%

Strong-field control of plasmonic properties in core-shell nanoparticles

Powell¹,

Li²,

Summers³

et al. 2021

Preprint

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The strong-field control of plasmonic nanosystems opens up new perspectives for nonlinear plasmonic spectroscopy and petahertz electronics. Questions, however, remain regarding the nature of nonlinear light-matter interactions at sub-wavelength spatial and ultrafast temporal scales. Addressing this challenge, we investigated the strong-field control of the plasmonic response of Au nanoshells with a SiO2 core to an intense laser pulse. We show that the photoelectron energy spectrum from these core-shell nanoparticles displays a striking transition between the weak and strong-field regime. This observed transition agrees with the prediction of our modified Mie-theory simulation that incorporates the nonlinear dielectric nanoshell response. The demonstrated intensity-dependent optical control of the plasmonic response in prototypical core-shell nanoparticles paves the way towards ultrafast switching and opto-electronic signal modulation with more complex nanostructures.The ability to reversibly manipulate the electronic structure and optical response of nanometer-sized materials has recently attracted substantial attention [1-3]. A hallmark property of nanostructures is the capacity to design and fabricate systems to take advantage of the tunable, size-, shape-, frequency-, and materialdependent properties as a means of tailoring specific optical responses. This holds the promise to both further our understanding of the transient electronic response in solid matter as well as enable new applications such as novel opto-electronics [3], plasmonically enhanced light harvesting [4], and photocatalysis [5, 6]. Among different configurations, composite nanostructures, such as coreshell nanoparticles, consisting of a dielectric core and a thin metallic shell, are of special interest for their exceptionally large plasmonic field enhancements and high tunability of absorption spectra [7, 8], generating novel applications in optical imaging and photothermal cancer therapy [9, 10]. Precise control of the optical response, typically achieved by manipulating the geometric structures [8], is the key to utilizing their unique plasmonic properties. Investigations into such optical properties in nanostructures have been conducted by studying their plasmonic response, in particular, their plasmonic near-field * These authors contributed equally to this work. enhancement [7, 11-13]. Photoelectrons provide an excel-42 lent window into understanding the dynamics of these in-43 teractions due to their sensitivity on the sub-wavelength 44 spatial and ultrafast temporal scales. Photoelectron 45 spectroscopy utilize these photoelectrons emitted during 46 the interaction of a nanoparticle with an intense, fem-47 tosecond laser, allowing for the unraveling of the fun-48 damental contributions to their acceleration, including 49 enhanced near-fields, surface rescattering and charge in-50 teractions [14-16]. Experiments revealed the fundamen-51 tal light-matter interaction processes during the optical 52 response and associated electron dynamic...

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Near-Field Induced Reaction Yields from Nanoparticle Clusters

Cited by 21 publications

References 28 publications

Three-dimensional Imaging of Nanoplasma by Ion Nanoscopy

Three-dimensional Imaging of Nanoplasma by Ion Nanoscopy

Nanoparticles in analytical laser and plasma spectroscopy – a review of recent developments in methodology and applications

Strong-field control of plasmonic properties in core-shell nanoparticles

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