Optical trapping and manipulation of nanostructures

Maragó, Onofrio M.; Jones, Philip H.; Gucciardi, P. G.; Volpe, Giovanni; Ferrari, Andrea C.

doi:10.1038/nnano.2013.208

Cited by 924 publications

(696 citation statements)

References 173 publications

(363 reference statements)

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“…Up to now, optical tweezing has been exploited as one of the most powerful tools for nanoparticle manipulation and hence gains insight into biology phenomena and fundamental physics from molecular motor to protein folding 8, 9, 10, 11, 12, 13, 14. However, optical tweezing still faces the limitations of shallow penetration, low scale manipulation, complex devices and high laser power, which requires new efforts to seek other alternative technologies.…”

Section: Introductionmentioning

confidence: 99%

Observation of Metal Nanoparticles for Acoustic Manipulation

et al. 2017

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Use of acoustic trapping for the manipulation of objects is invaluable to many applications from cellular subdivision to biological assays. Despite remarkable progress in a wide size range, the precise acoustic manipulation of 0D nanoparticles where all the structural dimensions are much smaller than the acoustic wavelength is still present challenges. This study reports on the observation of metal nanoparticles with different nanostructures for acoustic manipulation. Results for the first time exhibit that the hollow nanostructures play more important factor than size in the nanoscale acoustic manipulation. The acoustic levitation and swarm aggregations of the metal nanoparticles can be easily realized at low energy and clinically acceptable acoustic frequency by hollowing their nanostructures. In addition, the behaviors of swarm aggregations can be flexibly regulated by the applied voltage and frequency. This study anticipates that the strategy based on the unique properties of the metal hollow nanostructures and the manipulation method will be highly desirable for many applications.

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Section: Introductionmentioning

confidence: 99%

Observation of Metal Nanoparticles for Acoustic Manipulation

et al. 2017

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“…The interaction of chiral light with achiral objects has received much interest in the field of optical trapping and manipulation, leading to a high level of optomechanical control and detection at the micro and nanoscale [9][10][11][12][13] . The observation that light can transfer spin angular momentum (SAM) to matter dates back to the pioneering work by Beth 14 in 1936, who demonstrated that CP light exerts a torque on a birefringent wave plate.…”

mentioning

confidence: 99%

“…From quantum mechanics, CP light with angular frequency o carries both linear momentum (LM), :o/c, and SAM, s ± :, per photon with s þ ¼ þ 1 or s À ¼ À 1 for left-or right-handed CP, respectively 14 . The development of optical tweezers 15 (OT) stimulated the exploitation of optical forces and torques in several diverse areas such as biophysics 16 , nanotechnology 13 , complex fluids [17][18][19][20][21] , microrheology 10,11 and microfluidics 22,23 . In particular, several methods have been used to induce optically controlled rotations and alignment: anisotropic scattering due to particle shape 24,25 , form birefringence of anisotropic objects [26][27][28] , optical birefringence 9,12,29 and transfer of angular momentum (AM) from laser beams carrying SAM and/or orbital angular momentum 12,30,31 .…”

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confidence: 99%

Polarization-dependent optomechanics mediated by chiral microresonators

et al. 2014

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Chirality is one of the most prominent and intriguing aspects of nature, from spiral galaxies down to aminoacids. Despite the wide range of living and non-living, natural and artificial chiral systems at different scales, the origin of chirality-induced phenomena is often puzzling. Here we assess the onset of chiral optomechanics, exploiting the control of the interaction between chiral entities. We perform an experimental and theoretical investigation of the simultaneous optical trapping and rotation of spherulite-like chiral microparticles. Due to their shell structure (Bragg dielectric resonator), the microparticles function as omnidirectional chiral mirrors yielding highly polarization-dependent optomechanical effects. The coupling of linear and angular momentum, mediated by the optical polarization and the microparticles chiral reflectance, allows for fine tuning of chirality-induced optical forces and torques. This offers tools for optomechanics, optical sorting and sensing and optofluidics.

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“…There has been the use of spherical particles used as probes [Florin et al, 1997;Friese et al, 1999;Rohrbach et al, 2004;Volpe and Petrov, 2006;Volpe et al, 2007], as well as more bespoke devices [Carberry et al, 2010;Olof et al, 2012]. The use of bespoke probe particles for photonic force microscopy was reviewed in Maragò et al [2013]. Continuing the use of nonspherical shaped probe particles, led to the calibration of nonspherical probes in optical tweezers [Bui et al, 2013b;Grießhammer and Rohrbach, 2014].…”

Section: De Dtmentioning

confidence: 99%

“…The thermal statistics approach and related methods which involve thermal motion, have been explored for calibration in detail by Rohrbach's group (University of Freiburg, Germany) [Rohrbach et al, 2004], Ritsch-Marte's group (Innsbruck Medical University, Austria) [Singer et al, 2000], and also other groups who work with nonspherical probe particles, such as Marago's group (Istituto per i Processi Chimico-Fisici, Italy ) [Maragò et al, 2013] and the Bristol group (University of Bristol, United Kingdom) [Simpson and Hanna, 2012]. a b c Figure 2.3: Simulation of a spherical particle (polystyrene, 1 µm radius) undergoing a Brownian motion in a simulated Hookean trap, with κ = 0.025 N/m, and b a simulated optical trap, with wavelength 1064 nm, numerical aperture of 0.8, and power at the focus of 20 mW, and c free Brownian motion within the frame of the trapped particles.…”

Section: Boltzmann Statistics Analysismentioning

confidence: 99%

Calibration of optical tweezers for force microscopy

Bui¹

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Optical tweezers are an important tool in biophysics for their ability to noninvasively control microscopic particles, and measure forces in cellular environments. The trap must be calibrated for there to be a quantified force measurement. In this thesis, I use simulation to investigate the forces in optical tweezers and calibration of these forces.There are many methods which can be used to calibrate the forces. I first discuss the use of escape force calibration in detail. Using a combination of dynamic simulation and force calculations, I find that there is a zero axial force contour in the optical trap, which affects escape force measurements and explains behaviour which has been previously observed. I then use this escape force calibration for the calibration of the motility forces of isolated chromosomes, which provides information for the calculation of chromosome mitotic forces.I then introduce a new method of calibration which does not require any knowledge of the particle being optically trapped, or its environment. This is a method of absolute calibration. I require only the assumption that the force-position curve is monotonic, making no assumptions about the sphericity of the trapped particle or viscosity of the medium. Using dynamic simulation of an optically trapped particle, I find that the accuracy and tolerance of this new method of absolute calibration is comparable or an improvement on that of other calibration methods.I then use my absolute calibration method for the calibration of nonoptical forces. I first discuss the calibration of forces from surfaces, then forces from swimmers. Through dynamic simulations, I find that wall forces can be calibrated with the combination of my absolute calibration method and another position-only calibration method. I find that for an analogue of biological swimmers, swimming with uniform velocity, the calibration is straightforward and resembles that of the walls. For a more complex swimming model, the calibration is not as straightforward and other factors may need to be included. Publications included in this thesisNo publications included. Contributions by others to the thesis

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Optical trapping and manipulation of nanostructures

Cited by 924 publications

References 173 publications

Observation of Metal Nanoparticles for Acoustic Manipulation

Observation of Metal Nanoparticles for Acoustic Manipulation

Polarization-dependent optomechanics mediated by chiral microresonators

Calibration of optical tweezers for force microscopy

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