William Eom scite author profile

William Eom

5Publications

3Citation Statements Received

0Citation Statements Given

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Affiliations

Northwestern University

Publications

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Scanning force sensing at micrometer distances from a conductive surface with nanospheres in an optical lattice

et al. 2022

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The center-of-mass motion of optically trapped dielectric nanoparticles in a vacuum is extremely well decoupled from its environment, making a powerful tool for measurements of feeble subattonewton forces. We demonstrate a method to trap and maneuver nanoparticles in an optical standing wave potential formed by retroreflecting a laser beam from a metallic mirror surface. We can reliably position a ∼ 170 n m diameter silica nanoparticle at distances of a few hundred nanometers to tens of micrometers from the surface of a gold-coated silicon mirror by transferring it from a single-beam tweezer trap into the standing wave potential. We can further measure forces experienced by the particle while scanning the two-dimensional space parallel to the mirror surface, and we find no significant excess force noise in the vicinity of the surface. This method may enable three-dimensional scanning force sensing near surfaces using optically trapped nanoparticles, promising for high-sensitivity scanning force microscopy, tests of the Casimir effect, and tests of the gravitational inverse square law at micrometer scales.

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An apparatus for in-vacuum loading of nanoparticles into an optical trap

Weisman¹,

Galla²,

Montoya³

et al. 2022

Preprint

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An apparatus for in-vacuum loading of nanoparticles into an optical trap

Weisman

Galla

Montoya

et al. 2022

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We describe the design, construction, and operation of an apparatus that utilizes a piezoelectric transducer for in-vacuum loading of nanoparticles into an optical trap for use in levitated optomechanics experiments. In contrast to commonly used nebulizer-based trap-loading methods that generate aerosolized liquid droplets containing nanoparticles, the method produces dry aerosols of both spherical and high-aspect ratio particles ranging in size by approximately two orders of magnitude. The device has been shown to generate accelerations of order 107 g, which is sufficient to overcome stiction forces between glass nanoparticles and a glass substrate for particles as small as 170 nm in diameter. Particles with sizes ranging from 170 nm to [Formula: see text]m have been successfully loaded into optical traps at pressures ranging from 1 bar to 0.6 mbar. We report the velocity distribution of the particles launched from the substrate, and our results indicate promise for direct loading into ultra-high-vacuum with sufficient laser feedback cooling. This loading technique could be useful for the development of compact fieldable sensors based on optically levitated nanoparticles as well as matter–wave interference experiments with ultra-cold nano-objects, which rely on multiple repeated free-fall measurements and thus require rapid trap re-loading in high vacuum conditions.

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Precision scanning short-range force sensing with optically trapped nanoparticles

Geraci¹,

Eduardo²,

Montoya³

et al. 2022

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Optically-trapped nanoparticles as scanning force sensors for conductive surfaces at sub-micron distances

Eom¹,

Montoya²,

Eduardo³

et al. 2022

Preprint

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William Eom

Scanning force sensing at micrometer distances from a conductive surface with nanospheres in an optical lattice

An apparatus for in-vacuum loading of nanoparticles into an optical trap

An apparatus for in-vacuum loading of nanoparticles into an optical trap

Precision scanning short-range force sensing with optically trapped nanoparticles

Optically-trapped nanoparticles as scanning force sensors for conductive surfaces at sub-micron distances

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