Kilohertz rotation of nanorods propelled by ultrasound, traced by microvortex advection of nanoparticles

Andrew L. Balk; Lamar O. Mair; Pramod P. Mathai; Paul N. Patrone; Wei Wang; Suzanne Ahmed; Thomas E. Mallouk; J. Alexander Liddle; Samuel M. Stavis

doi:10.1021/nn502753x

Kilohertz rotation of nanorods propelled by ultrasound, traced by microvortex advection of nanoparticles

Andrew L. Balk
, Lamar O. Mair
, Pramod P. Mathai
, Paul N. Patrone
, Wei Wang
, Suzanne Ahmed
, Thomas E. Mallouk
, J. Alexander Liddle
, Samuel M. Stavis^*

^*Corresponding author for this work

National Institute of Standards and Technology
University of Maryland, College Park
Weinberg Medical Physics LLC
University of Minnesota Twin Cities
Pennsylvania State University
Harbin Institute of Technology (Shenzhen)

Research output: Contribution to journal › Article › peer-review

94 Scopus citations

Abstract

We measure the microvortical flows around gold nanorods propelled by ultrasound in water using polystyrene nanoparticles as optical tracers. We infer the rotational frequencies of such nanomotors assuming a hydrodynamic model of this interaction. In this way, we find that nanomotors rotate around their longitudinal axes at frequencies of up to ≈ 2.5 kHz, or ≈ 150 000 rpm, in the planar pressure node of a half-wavelength layered acoustic resonator driven at ≈ 3 MHz with an acoustic energy density of <10 J·m^-3. The corresponding tangential speeds of up to ≈ 2.5 mm·s^-1 at a nanomotor radius of ≈ 160 nm are 2 orders of magnitude faster than the translational speeds of up to ≈ 20 μm·s^-1. We also find that rotation and translation are independent modes of motion within experimental uncertainty. Our study is an important step toward understanding the behavior and fulfilling the potential of this dynamic nanotechnology for hydrodynamically interacting with biological media, as well as other applications involving nanoscale transport, mixing, drilling, assembly, and rheology. Our results also establish the fastest reported rotation of a nanomotor in aqueous solution.

Original language	English
Pages (from-to)	8300-8309
Number of pages	10
Journal	ACS Nano
Volume	8
Issue number	8
DOIs	https://doi.org/10.1021/nn502753x
State	Published - 26 Aug 2014
Externally published	Yes

Keywords

acoustic
microvortex
nanomotor
nanoparticle
nanorod
rotation
ultrasonic
ultrasound

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10.1021/nn502753x

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@article{853c02d524cf49d5b2cbcac2607dcc11,

title = "Kilohertz rotation of nanorods propelled by ultrasound, traced by microvortex advection of nanoparticles",

abstract = "We measure the microvortical flows around gold nanorods propelled by ultrasound in water using polystyrene nanoparticles as optical tracers. We infer the rotational frequencies of such nanomotors assuming a hydrodynamic model of this interaction. In this way, we find that nanomotors rotate around their longitudinal axes at frequencies of up to ≈ 2.5 kHz, or ≈ 150 000 rpm, in the planar pressure node of a half-wavelength layered acoustic resonator driven at ≈ 3 MHz with an acoustic energy density of <10 J·m-3. The corresponding tangential speeds of up to ≈ 2.5 mm·s-1 at a nanomotor radius of ≈ 160 nm are 2 orders of magnitude faster than the translational speeds of up to ≈ 20 μm·s-1. We also find that rotation and translation are independent modes of motion within experimental uncertainty. Our study is an important step toward understanding the behavior and fulfilling the potential of this dynamic nanotechnology for hydrodynamically interacting with biological media, as well as other applications involving nanoscale transport, mixing, drilling, assembly, and rheology. Our results also establish the fastest reported rotation of a nanomotor in aqueous solution.",

keywords = "acoustic, microvortex, nanomotor, nanoparticle, nanorod, rotation, ultrasonic, ultrasound",

author = "Balk, \{Andrew L.\} and Mair, \{Lamar O.\} and Mathai, \{Pramod P.\} and Patrone, \{Paul N.\} and Wei Wang and Suzanne Ahmed and Mallouk, \{Thomas E.\} and Liddle, \{J. Alexander\} and Stavis, \{Samuel M.\}",

year = "2014",

month = aug,

day = "26",

doi = "10.1021/nn502753x",

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journal = "ACS Nano",

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T1 - Kilohertz rotation of nanorods propelled by ultrasound, traced by microvortex advection of nanoparticles

AU - Balk, Andrew L.

AU - Mair, Lamar O.

AU - Mathai, Pramod P.

AU - Patrone, Paul N.

AU - Wang, Wei

AU - Ahmed, Suzanne

AU - Mallouk, Thomas E.

AU - Liddle, J. Alexander

AU - Stavis, Samuel M.

PY - 2014/8/26

Y1 - 2014/8/26

N2 - We measure the microvortical flows around gold nanorods propelled by ultrasound in water using polystyrene nanoparticles as optical tracers. We infer the rotational frequencies of such nanomotors assuming a hydrodynamic model of this interaction. In this way, we find that nanomotors rotate around their longitudinal axes at frequencies of up to ≈ 2.5 kHz, or ≈ 150 000 rpm, in the planar pressure node of a half-wavelength layered acoustic resonator driven at ≈ 3 MHz with an acoustic energy density of <10 J·m-3. The corresponding tangential speeds of up to ≈ 2.5 mm·s-1 at a nanomotor radius of ≈ 160 nm are 2 orders of magnitude faster than the translational speeds of up to ≈ 20 μm·s-1. We also find that rotation and translation are independent modes of motion within experimental uncertainty. Our study is an important step toward understanding the behavior and fulfilling the potential of this dynamic nanotechnology for hydrodynamically interacting with biological media, as well as other applications involving nanoscale transport, mixing, drilling, assembly, and rheology. Our results also establish the fastest reported rotation of a nanomotor in aqueous solution.

AB - We measure the microvortical flows around gold nanorods propelled by ultrasound in water using polystyrene nanoparticles as optical tracers. We infer the rotational frequencies of such nanomotors assuming a hydrodynamic model of this interaction. In this way, we find that nanomotors rotate around their longitudinal axes at frequencies of up to ≈ 2.5 kHz, or ≈ 150 000 rpm, in the planar pressure node of a half-wavelength layered acoustic resonator driven at ≈ 3 MHz with an acoustic energy density of <10 J·m-3. The corresponding tangential speeds of up to ≈ 2.5 mm·s-1 at a nanomotor radius of ≈ 160 nm are 2 orders of magnitude faster than the translational speeds of up to ≈ 20 μm·s-1. We also find that rotation and translation are independent modes of motion within experimental uncertainty. Our study is an important step toward understanding the behavior and fulfilling the potential of this dynamic nanotechnology for hydrodynamically interacting with biological media, as well as other applications involving nanoscale transport, mixing, drilling, assembly, and rheology. Our results also establish the fastest reported rotation of a nanomotor in aqueous solution.

KW - acoustic

KW - microvortex

KW - nanomotor

KW - nanoparticle

KW - nanorod

KW - rotation

KW - ultrasonic

KW - ultrasound

UR - https://www.scopus.com/pages/publications/84906689699

U2 - 10.1021/nn502753x

DO - 10.1021/nn502753x

M3 - 文章

AN - SCOPUS:84906689699

SN - 1936-0851

VL - 8

SP - 8300

EP - 8309

JO - ACS Nano

JF - ACS Nano

IS - 8

ER -

Kilohertz rotation of nanorods propelled by ultrasound, traced by microvortex advection of nanoparticles

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Keywords

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