Nanoscale Lamb wave–driven motors in nonliquid environments

Lu, Jinsheng; Li, Qiang; Qiu, Cheng‐Wei; Hónɡ, Yú; Ghosh, Pintu; Qiu, Min

doi:10.1126/sciadv.aau8271

Cited by 36 publications

(67 citation statements)

References 41 publications

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“…5 ). Under special environmental conditions such as high vacuum (less than 10 −4 Pa) and low temperature (down to 30 K), such phenomena were still observed, indicating that the photophoretic force 25 , 27 , 28 induced by the surrounding gas molecules can be excluded. In addition, no recrystallization phenomena in as-driven Au nanowires were observed by using a high-resolution atomic force microscope (AFM) and a transmission electron microscopy (Supplementary Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Currently, a common manipulation method in air environments is manually using 3D stage-actuated tungsten or silica probes to apply thrust on the nanowire sides 6,7,18,19 , but the nanowires can only be moved laterally with accuracy of ~1 μm. On the other hand, surface acoustic waves (SAWs) induced by the elastic expansion of metal lattices under transient heating of pulsed lasers [20][21][22] , have been used to drive microscale metal objects for surface cleaning, particle detaching, and microplate rotating [23][24][25] , thus providing the possibility of overcoming the strong surface adhesion to manipulate metal nanowires in non-liquid environments.…”

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confidence: 99%

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Plasmon-driven nanowire actuators for on-chip manipulation

Linghu

et al. 2021

Nat Commun

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Chemically synthesized metal nanowires are promising building blocks for next-generation photonic integrated circuits, but technological implementation in monolithic integration will be severely hampered by the lack of controllable and precise manipulation approaches, due to the strong adhesion of nanowires to substrates in non-liquid environments. Here, we demonstrate this obstacle can be removed by our proposed earthworm-like peristaltic crawling motion mechanism, based on the synergistic expansion, friction, and contraction in plasmon-driven metal nanowires in non-liquid environments. The evanescently excited surface plasmon greatly enhances the heating effect in metal nanowires, thereby generating surface acoustic waves to drive the nanowires crawling along silica microfibres. Advantages include sub-nanometer positioning accuracy, low actuation power, and self-parallel parking. We further demonstrate on-chip manipulations including transporting, positioning, orientation, and sorting, with on-situ operation, high selectivity, and great versatility. Our work paves the way to realize full co-integration of various functionalized photonic components on single chips.

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Plasmon-driven nanowire actuators for on-chip manipulation

Linghu

et al. 2021

Nat Commun

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“…When the characteristic length of a material is on the micro or nanoscale, particularly in micro/ nanoelectromechanical system (MEMS/NEMS), the scale effect becomes dominant and unavoidable in the analysis and design of materials and structural systems 1 . Therefore, a quantitative measurement of scale effects can help scientists comprehend the properties of micro/nanomaterials 2,3 and provide guidance for the topology design of various devices [4][5][6][7] . As a fundamental approach for smallscale material analytics 8 , the torsion test plays an indispensable role in promoting an understanding of the world at the micro/nanoscale.…”

Section: Introductionmentioning

confidence: 99%

Robot-aided fN∙m torque sensing within an ultrawide dynamic range

Wang

Wei

et al. 2021

Microsyst Nanoeng

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In situ scanning electron microscope (SEM) characterization have enabled the stretching, compression, and bending of micro/nanomaterials and have greatly expanded our understanding of small-scale phenomena. However, as one of the fundamental approaches for material analytics, torsion tests at a small scale remain a major challenge due to the lack of an ultrahigh precise torque sensor and the delicate sample assembly strategy. Herein, we present a microelectromechanical resonant torque sensor with an ultrahigh resolution of up to 4.78 fN∙m within an ultrawide dynamic range of 123 dB. Moreover, we propose a nanorobotic system to realize the precise assembly of microscale specimens with nanoscale positioning accuracy and to conduct repeatable in situ pure torsion tests for the first time. As a demonstration, we characterized the mechanical properties of Si microbeams through torsion tests and found that these microbeams were five-fold stronger than their bulk counterparts. The proposed torsion characterization system pushes the limit of mechanical torsion tests, overcomes the deficiencies in current in situ characterization techniques, and expands our knowledge regarding the behavior of micro/nanomaterials at various loads, which is expected to have significant implications for the eventual development and implementation of materials science.

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“…It is comprehensible that the photon-to-phonon energy transfer predominates at the illuminated side of light-absorbing objects. The key to pulling an object using photophoresis is to flip the thermal energy distribution, which requires a rigorous design for both the heating optics and the structures of the light-absorbing objects [11][12][13] . To date, pulling an object in free space using simple optics is still elusive, which hinders the development of the optical pulling force as a general manipulation technology.…”

Section: Introductionmentioning

confidence: 99%

Opto-thermoelectric pulling of light-absorbing particles

et al. 2020

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Optomechanics arises from the photon momentum and its exchange with low-dimensional objects. It is well known that optical radiation exerts pressure on objects, pushing them along the light path. However, optical pulling of an object against the light path is still a counter-intuitive phenomenon. Herein, we present a general concept of optical pulling-opto-thermoelectric pulling (OTEP)-where the optical heating of a light-absorbing particle using a simple plane wave can pull the particle itself against the light path. This irradiation orientation-directed pulling force imparts self-restoring behaviour to the particles, and three-dimensional (3D) trapping of single particles is achieved at an extremely low optical intensity of 10 −2 mW μm −2 . Moreover, the OTEP force can overcome the short trapping range of conventional optical tweezers and optically drive the particle flow up to a macroscopic distance. The concept of selfinduced opto-thermomechanical coupling is paving the way towards freeform optofluidic technology and lab-on-achip devices.

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Nanoscale Lamb wave–driven motors in nonliquid environments

Cited by 36 publications

References 41 publications

Plasmon-driven nanowire actuators for on-chip manipulation

Plasmon-driven nanowire actuators for on-chip manipulation

Robot-aided fN∙m torque sensing within an ultrawide dynamic range

Opto-thermoelectric pulling of light-absorbing particles

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