Optical trapping and integration of semiconductor nanowire assemblies in water

Pauzauskie, Peter J.; Radenović, Aleksandra; Trepagnier, Eliane; Shroff, Hari; Yang, Peidong; Liphardt, Jan

doi:10.1038/nmat1563

Cited by 395 publications

(326 citation statements)

References 30 publications

(31 reference statements)

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“…screen charge | atomic force microscopy | piezoresponse | charge scraping F erroelectric and piezoelectric materials have attracted great attention due to their applications in commercial markets such as a medical imaging (1-3), next generation inkjet printer heads (4), precision-positioning stages (5,6), fuel injectors in diesel engines (7,8), and memory devices (9,10). The macroscopic properties of ferroelectric and piezoelectric materials that make them appealing for current and future technologies can be more fully understood and improved through detailed knowledge of their domain structures at the nanoscale and mesoscale (11)(12)(13)(14)(15).…”

mentioning

confidence: 99%

Charge gradient microscopy

Hong

Tong

Park

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Here we present a simple and fast method to reliably image polarization charges using charge gradient microscopy (CGM). We collected the current from the grounded CGM probe while scanning a periodically poled lithium niobate single crystal and single-crystal LiTaO 3 thin film on the Cr electrode. We observed current signals at the domains and domain walls originating from the displacement current and the relocation or removal of surface charges, which enabled us to visualize the ferroelectric domains at a scan frequency above 78 Hz over 10 μm. We envision that CGM can be used in high-speed ferroelectric domain imaging and piezoelectric energyharvesting devices.screen charge | atomic force microscopy | piezoresponse | charge scraping

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confidence: 99%

Charge gradient microscopy

Hong

Tong

Park

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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“…In addition, the latest experiments 10 demonstrated that these nanostructures can be used as local mechano-optical probes. 11,12 Although many groups report on the synthesis and structural characterization of different types of alkaline niobate nanowires, there are no comparative studies that address their nonlinear optical response. In this work, we compare SHG signal and waveguiding properties for three types of perovskite alkaline niobate nanowires such as NaNbO 3 , KNbO 3 , and LiNbO 3 (XNbO 3 ).…”

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confidence: 99%

“…One fraction of the wires is usually already stuck to the glass coverslip, while the rest of the nanowires and nanowire clusters undergo Brownian motion allowing us to easily test both geometries using the same setup and same sample cell (details regarding the setup can be found in Supporting Information). When the laser is brought close to a nanowire, it is pulled into the trap, 11 trapped tridimensionally perpendicular to the surface and the SHG signal can be detected by the EMCCD camera. Varying the polarization of the impinging light, by moving a half wave plate the reliance of the SHG signal on light polarization is studied.…”

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confidence: 99%

Nonlinear Optical Response in Single Alkaline Niobate Nanowires

et al. 2011

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We have synthesized and characterized three types of perovskite alkaline niobate nanowires: NaNbO 3 , KNbO 3 , and LiNbO 3 (XNbO 3 ). All three types of nanowires exhibit strong nonlinear response. Confocal imaging has been employed to quantitatively compare the efficiency of synthesized nanowires to generate second harmonic signal and to show that LiNbO 3 nanowires exhibit the strongest nonlinear response. We also investigated the polarization response of the second harmonic generation (SHG) signal in all three types of alkaline nanowires for the two geometries tractable by our optical trapping setup. The SHG signal is highly influenced by the nanowire crystallinity and experimental geometry. We also demonstrate for the first time wave-guiding of SHG signal in all three types of alkaline niobate nanowires. By carefully examining nonlinear properties of (XNbO 3 ) nanowires we suggest which type of wires are best suited for the given application.

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“…single molecule ͉ subnanometer resolution ͉ signal-to-noise ratio S ince the discovery that optical gradients could stably trap micrometer-sized dielectric particles (1), gradient optical traps, or optical tweezers, have been used in a large variety of applications ranging from microfabrication (2,3) to the study of colloidal hydrodynamics (4-6) and nonequilibrium thermodynamics (7)(8)(9)(10). In particular, the use of calibrated optical springs has provided unprecedented new insight on the mechanical properties of single biological molecules and the molecular motors that manipulate them in the cell (11)(12)(13)(14).…”

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confidence: 99%

Differential detection of dual traps improves the spatial resolution of optical tweezers

Moffitt¹,

Chemla²,

Izhaky

et al. 2006

Proc. Natl. Acad. Sci. U.S.A.

274

283

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The drive toward more sensitive single-molecule manipulation techniques has led to the recent development of optical tweezers capable of resolving the motions of biological systems at the subnanometer level, approaching the fundamental limit set by Brownian fluctuations. One successful approach has been the dual-trap optical tweezers, in which the system of study is held at both ends by microspheres in two separate optical traps. We present here a theoretical description of the Brownian limit on the spatial resolution of such systems and verify these predictions by direct measurement in a Brownian noise-limited dual-trap optical tweezers. We find that by detecting the positions of both trapped microspheres, correlations in their motions can be exploited to maximize the resolving power of the instrument. Remarkably, we show that the spatial resolution of dual optical traps with dual-trap detection is always superior to that of more traditional, single-trap designs, despite the added Brownian noise of the second trapped microsphere.single molecule ͉ subnanometer resolution ͉ signal-to-noise ratio S ince the discovery that optical gradients could stably trap micrometer-sized dielectric particles (1), gradient optical traps, or optical tweezers, have been used in a large variety of applications ranging from microfabrication (2, 3) to the study of colloidal hydrodynamics (4-6) and nonequilibrium thermodynamics (7-10). In particular, the use of calibrated optical springs has provided unprecedented new insight on the mechanical properties of single biological molecules and the molecular motors that manipulate them in the cell (11)(12)(13)(14). In a typical single-molecule experiment, a biopolymer is linked to a single, optically trapped dielectric microsphere at one end and to a fixed surface at the other. The length of this molecule is inferred from the force applied by the optical trap and the position of the microsphere relative to the fixed end of the polymer. In an ideal system with no measurement error, the ability to resolve changes in the length of the polymer, the spatial resolution of the optical tweezers, is limited only by the stochastic Brownian force induced on the microsphere by the surrounding solvent. This limit has been estimated previously (15,16) and implies that it should be possible to resolve length changes on the angstrom scale with reasonable values of the experimental parameters, i.e., microsphere size, polymer stiffness, and averaging bandwidth. However, it has proven difficult to sufficiently isolate single-trap optical tweezers from environmental and instrumental sources of noise to reach this Brownian noise limit. Drift and low frequency fluctuations of the fixed surface relative to the optical trap typically obscure these small movements.One method to increase the stability of optical tweezers is to introduce a second optical trap to hold the other end of the system, thereby decoupling it from movements of the fixed surface. Although such dual-trap optical tweezers were first envisioned m...

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Optical trapping and integration of semiconductor nanowire assemblies in water

Cited by 395 publications

References 30 publications

Charge gradient microscopy

Charge gradient microscopy

Nonlinear Optical Response in Single Alkaline Niobate Nanowires

Differential detection of dual traps improves the spatial resolution of optical tweezers

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