Helical Nanomachines as Mobile Viscometers

Arijit Ghosh; Debayan Dasgupta; Malay Pal; Konstantin I. Morozov; Alexander M. Leshansky; Ambarish Ghosh

doi:https://doi.org/10.1002/adfm.201705687

Helical Nanomachines as Mobile Viscometers

Arijit Ghosh, Debayan Dasgupta, Malay Pal, Konstantin I. Morozov, Alexander M. Leshansky, Ambarish Ghosh

Chemical Engineering

Technion - Israel Institute of Technology

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

Abstract

A wide variety of applications are envisioned and demonstrated with artificial micro- and nanomachines, ranging from targeted drug or gene delivery, microsurgery, environmental sensing, and many more. Here, it is demonstrated how helical nanomachines can be used to measure and map the local mechanical properties of a complex heterogeneous environment. The positions of the nanomachines are precisely controlled using externally applied magnetic fields, while their instantaneous orientations provide estimation of the viscosity of the surrounding medium with high spatial and temporal accuracy. The measurement technique can be applied to both Newtonian as well as shear thinning media, and all experimental results are in good agreement with the theoretical analysis. It is believed that this novel application of helical nanomachines can be particularly relevant to biophysical studies and microfluidic technologies.

Original language	English
Article number	1705687
Journal	Advanced Functional Materials
Volume	28
Issue number	25
DOIs	https://doi.org/10.1002/adfm.201705687
State	Published - 20 Jun 2018

Keywords

helical propulsion
heterogeneous fluids
micro/nanomachines
shear-thinning fluids
viscometry

All Science Journal Classification (ASJC) codes

General Chemistry
Condensed Matter Physics
General Materials Science

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https://doi.org/10.1002/adfm.201705687

Cite this

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title = "Helical Nanomachines as Mobile Viscometers",

abstract = "A wide variety of applications are envisioned and demonstrated with artificial micro- and nanomachines, ranging from targeted drug or gene delivery, microsurgery, environmental sensing, and many more. Here, it is demonstrated how helical nanomachines can be used to measure and map the local mechanical properties of a complex heterogeneous environment. The positions of the nanomachines are precisely controlled using externally applied magnetic fields, while their instantaneous orientations provide estimation of the viscosity of the surrounding medium with high spatial and temporal accuracy. The measurement technique can be applied to both Newtonian as well as shear thinning media, and all experimental results are in good agreement with the theoretical analysis. It is believed that this novel application of helical nanomachines can be particularly relevant to biophysical studies and microfluidic technologies.",

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AU - Ghosh, Arijit

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AU - Pal, Malay

AU - Morozov, Konstantin I.

AU - Leshansky, Alexander M.

AU - Ghosh, Ambarish

PY - 2018/6/20

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N2 - A wide variety of applications are envisioned and demonstrated with artificial micro- and nanomachines, ranging from targeted drug or gene delivery, microsurgery, environmental sensing, and many more. Here, it is demonstrated how helical nanomachines can be used to measure and map the local mechanical properties of a complex heterogeneous environment. The positions of the nanomachines are precisely controlled using externally applied magnetic fields, while their instantaneous orientations provide estimation of the viscosity of the surrounding medium with high spatial and temporal accuracy. The measurement technique can be applied to both Newtonian as well as shear thinning media, and all experimental results are in good agreement with the theoretical analysis. It is believed that this novel application of helical nanomachines can be particularly relevant to biophysical studies and microfluidic technologies.

AB - A wide variety of applications are envisioned and demonstrated with artificial micro- and nanomachines, ranging from targeted drug or gene delivery, microsurgery, environmental sensing, and many more. Here, it is demonstrated how helical nanomachines can be used to measure and map the local mechanical properties of a complex heterogeneous environment. The positions of the nanomachines are precisely controlled using externally applied magnetic fields, while their instantaneous orientations provide estimation of the viscosity of the surrounding medium with high spatial and temporal accuracy. The measurement technique can be applied to both Newtonian as well as shear thinning media, and all experimental results are in good agreement with the theoretical analysis. It is believed that this novel application of helical nanomachines can be particularly relevant to biophysical studies and microfluidic technologies.

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Helical Nanomachines as Mobile Viscometers

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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