Understanding and Reducing Photothermal Forces for the Fabrication of Au Nanoparticle Dimers by Optical Printing

Gargiulo, Julián; Brick, Thomas; Violi, Ianina L.; Herrera, Facundo C.; Shibanuma, Toshihiko; Albella, Pablo; Requejo, Félix G.; Cortés, Emiliano; Maier, Stefan A.; Stefani, Fernando D.

doi:10.1021/acs.nanolett.7b02713

Cited by 100 publications

(126 citation statements)

References 68 publications

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“…The fixation process can rely on different mechanisms: hydrophobic or van der Waals interactions between the nanoparticle and the substrate, laser‐induced adhesion (transient melting) or laser‐induced photopolymerization . Other techniques exploiting similar approaches include optical printing of nanostructures onto a substrate from colloidal nanoparticles, and multiphoton polymerization of 3D patterns (e.g., waveguides) in colloidal crystals . Working electronic devices have been fabricated from nanowires tweezed and fused together (Figure c) or fused onto other structures (Figure d) …”

Section: Fields Of Applicationmentioning

confidence: 99%

Nanoscale Optical Trapping: A Review

Bradac

2018

Advanced Optical Materials

118

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The First TrapIn 1969, a "back-of-the-envelope" calculation inspired Ashkin to conduct a simple experiment and determine whether it was feasible to use light radiation pressure to accelerate objects to practical speeds. Photons carry momentum hν/c (with h, ν and c being the Planck's constant, the frequency of the photon and the speed of light, respectively). If light from a source with power P shines on a mirror, P/hν photons hit the surface every second and transfer a total momentum of (2P/hν)(hν/c) = 2P/c onto it. A perfectly reflecting mirror should therefore-due to conservation-acquire an equal momentum in the same direction light propagates.Based on this crude calculation, Ashkin predicted that a light source of power P = 1 W, would produce a force (on an ideally reflecting mirror) of ≈10 nN-indeed small in absolute terms. [3] Nevertheless, if a laser beam is used as the light source and is focused on a spot of ≈1 µm 2 to hit a particle ≈1 µm in diame ter, the resulting force does become relevant. Assuming the particle is perfectly reflective and has a density of 1 g cm −3 , the calculated acceleration is ≈10 9 cm s −2 , i.e., roughly 10 6 times the acceleration of gravity. In the experiment, Ashkin conducted to test his hypotheses, [2] a cw argon laser (wavelength λ = 514.5 nm, waist radius w 0 = 6.2 µm at the focal point) was employed to accelerate latex spheres (diameter 0.59, 1.31, and 2.68 µm), which were freely suspended in water, in a glass chamber. With just milliwatts of laser power, Ashkin observed that the particles were pushed in the direction of the mildly focused Gaussian laser beam, with values for the acceleration consistent with his rough predictions. Interestingly, he also observed an unanticipated phenomenon. Particles located in the fringes of the beam were drawn toward the beam axiswhere the light intensity is the highest-before being accelerated and pushed with ≈µm s −1 speeds toward the back of the chamber. They would disperse by Brownian motion away from the beam axis once the laser was switched off, yet they would be drawn again toward the center of the beam upon turning the laser back on-as the radiation pressure had a transverse component to the force, as well as the predicted longitudinal one.The origin of both the transversal and longitudinal force is usually understood by considering two distinct regimes, depending on the relative size of the particles to the wavelength of the laser beam: the geometrical (ray optics) regime and the Rayleigh (dipole approximation) regime.Optical trapping is the craft of manipulating objects with light. Decades after its first inception in 1970, the technique has become a powerful tool for ultracold-atom physics and manipulation of micron-sized particles. Yet, optical trapping of objects at the intermediate-nanoscale-range is still beyond full grasp. This matters because the nanometric realm is where several promising advances, from mastering single-molecule experiments in biology, to fabricating hybrid devices for nanoelectronics and photonics, a...

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Section: Fields Of Applicationmentioning

confidence: 99%

Nanoscale Optical Trapping: A Review

Bradac

2018

Advanced Optical Materials

118

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“…However, previous work has reported that Rayleigh–Benard convection is negligible in micrometer length scale. [ 46–48 ] To verify the existence of the Rayleigh–Benard convection, a dimensionless number, Rayleigh number ( R ), is calculated as

R = \frac{ρ_{m} g α_{m} Δ T h^{3}}{η_{m} κ_{m}}

where g is the acceleration due to gravity, ρ m , α m , η m , and κ m are the density, thermal volume expansion coefficient, dynamic viscosity, and thermal diffusivity of the mixed suspension, respectively, Δ T is the vertical temperature difference between the bottom (substrate temperature, T s ) and the top (room temperature, 20 °C) of the suspension, and h is the thickness of the suspension. The thermal diffusivity κ m can be obtained as

κ_{m} = \frac{λ_{m}}{ρ_{m} C p_{m}}

where λ m and Cp m are the thermal conductivity and heat capacity of the mixed suspension.…”

Section: Figurementioning

confidence: 99%

“…The thermal Marangoni convection is reported to be prominent in micrometer length scale. [ 47 ] To validate this conclusion, another dimensionless number, thermal Marangoni number ( Ma T ), is calculated as

M a_{T} = \frac{\partial γ_{m}}{\partial T} Δ T \frac{h}{η_{m} κ_{m}}

where γ m is the surface tension of the mixed suspension. [ 52,53 ] The thermal Marangoni number also increases with the substrate temperature and ranges between 540 and 6000 (Figure 2d).…”

Section: Figurementioning

confidence: 99%

High‐Rate Printing of Micro/Nanoscale Patterns Using Interfacial Convective Assembly

et al. 2020

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Electric-field-directed assembly [31,32] uses electrophoretic and dielectrophoretic forces to direct nanoelements. Although electric-field-directed assembly demonstrates high throughput, high scalability, and high resolution in assembling various nanomaterials, conductive substrates are required to generate electric field, which limits potential applications of printed structures in electronic devices. Fluidicflow-directed assembly such as convective [33][34][35] and capillary [36][37][38] assembly utilizes solvent evaporation-induced convective flow to guide and position nanoelements. Unlike electric-field-directed assembly, fluidic-flow-directed assembly is applicable to all kinds of substrates (both insulating and conductive). However, it takes hours to assemble over centimetersized substrates. Therefore, the scalability and throughput of this assembly process is a major challenge. Photothermally directed assembly uses photothermaleffect-induced Rayleigh-Benard [39] and/or Marangoni [40][41][42] convective flow to direct assembly. Similar to fluidic-flow-directed assembly, photothermally directed assembly suffers from scalability and throughput issues due to its serial processing nature. In addition, photothermally directed assembly has a limited resolution of micro or sub-micro scale. [43,44] Therefore, the development of a broadly applicable, highly scalable, high throughput, and high resolution printing technique is highly desirable.Here, we report a novel fluidic-flow-directed assembly technique, interfacial convective assembly, to rapidly assemble particles in pattern areas on any substrates. In the interfacial convective assembly, a patterned substrate is initially sonicated in isopropyl alcohol (IPA) using a bath type sonicator for a few seconds. With a low surface tension, IPA helps wet as well as remove trapped air in the patterned structures. After sonication, the substrate is removed from the IPA bath, leaving a thin IPA film on the substrate. Afterward, 50 µL aqueous particle suspension is drop casted on the IPA film. The particle suspension immediately mixes with the IPA film, resulting a suspension with ≈20 wt% IPA. Then, a glass slide is covered on the suspension, creating a confined environment with the substrate via a 300 µm thick spacer (Figure 1a). Finally, the setup is placed onto a hot plate with preheated temperatures between 40 and 75 °C. The substrate is heated up, inducing a convective flow. Due to the convective flow, particles are carried toward Printing of electronics has been receiving increasing attention from academia and industry over the recent years. However, commonly used printing techniques have limited resolution of micro-or sub-microscale. Here, a directed-assembly-based printing technique, interfacial convective assembly, is reported, which utilizes a substrate-heating-induced solutal Marangoni convective flow to drive particles toward patterned substrates and then uses van der Waals interactions as well as geometrical confinement to trap the particles in the pattern area...

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“…Thegeometric model for each structure was built based on the experimentally determined average edge length, inner NP size,i nterior nanogap size,a nd frame thickness of the Au PIAFs.F rom the calculated extinction spectra of the model structures and corresponding simulated charge distributions at the respective resonance wavelengths,i tc an be corroborated that the LSPR peaks of the Au PIAFs correspond to the collection of coupled plasmon modes between the dipole plasmon modes of the inner NPs and outer frames. [32,33] This technique allows to aid identifying unambiguously the plasmonic response of the Au PIAF avoiding interparticle coupling effects (that is,external hot spots). Single-particle spectroscopy is apowerful tool for interpreting the physicochemical phenomena precisely in nanoparticle systems.…”

Section: Angewandte Chemiementioning

confidence: 99%

Particle‐in‐a‐Frame Nanostructures with Interior Nanogaps

et al. 2019

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Designing plasmonic hollowc olloids with small interior nanogaps would allows tructural properties to be exploited that are normally linked to an ensemble of particles but within as ingle nanoparticle.N ow,asynthetic approach for constructing an ew class of frame nanostructures is presented. Fine control over the galvanic replacement reaction of Ag nanoprisms with Au precursors gave unprecedented Au particle-in-a-frame nanostructures with well-defined sub-2 nm interior nanogaps.T he prepared nanostructures exhibited superior performance in applications,such as plasmonic sensing and surface-enhanced Raman scattering, over their solid nanostructure and nanoframe counterparts.T his highlights the benefit of their interior hot spots,w hichc an highly promote and maximizet he electric field confinement within as ingle nanostructure.

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Understanding and Reducing Photothermal Forces for the Fabrication of Au Nanoparticle Dimers by Optical Printing

Cited by 100 publications

References 68 publications

Nanoscale Optical Trapping: A Review

Nanoscale Optical Trapping: A Review

High‐Rate Printing of Micro/Nanoscale Patterns Using Interfacial Convective Assembly

Particle‐in‐a‐Frame Nanostructures with Interior Nanogaps

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