Control of nanomaterial self-assembly in ultrasonically levitated droplets

A. Seddon; Sam  Richardson; Kunal Rastogi; Tomas Plivelic; Adam  Squires; Christian Pfrang

doi:10.1021/acs.jpclett.6b00449

Control of nanomaterial self-assembly in ultrasonically levitated droplets

A. Seddon, Sam Richardson, Kunal Rastogi, Tomas Plivelic, Adam Squires, Christian Pfrang

Geography, Earth and Environmental Sciences

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

22 Citations (Scopus)

Abstract

We demonstrate that acoustic trapping can be used to levitate and manipulate droplets of soft matter, in particular, lyotropic mesophases formed from self-assembly of different surfactants and lipids, which can be analyzed in a contact-less manner by X-ray scattering in a controlled gas-phase environment. On the macroscopic length scale, the dimensions and the orientation of the particle are shaped by the ultrasonic field, while on the microscopic length scale the nanostructure can be controlled by varying the humidity of the atmosphere around the droplet. We demonstrate levitation and in situ phase transitions of micellar, hexagonal, bicontinuous cubic, and lamellar phases. The technique opens up a wide range of new experimental approaches of fundamental importance for environmental, biological, and chemical research.

Original language	English
Pages (from-to)	1341-1345
Number of pages	5
Journal	Journal of Physical Chemistry Letters
Volume	7
Issue number	7
Early online date	15 Mar 2016
DOIs	https://doi.org/10.1021/acs.jpclett.6b00449
Publication status	Published - 7 Apr 2016

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title = "Control of nanomaterial self-assembly in ultrasonically levitated droplets",

abstract = "We demonstrate that acoustic trapping can be used to levitate and manipulate droplets of soft matter, in particular, lyotropic mesophases formed from self-assembly of different surfactants and lipids, which can be analyzed in a contact-less manner by X-ray scattering in a controlled gas-phase environment. On the macroscopic length scale, the dimensions and the orientation of the particle are shaped by the ultrasonic field, while on the microscopic length scale the nanostructure can be controlled by varying the humidity of the atmosphere around the droplet. We demonstrate levitation and in situ phase transitions of micellar, hexagonal, bicontinuous cubic, and lamellar phases. The technique opens up a wide range of new experimental approaches of fundamental importance for environmental, biological, and chemical research.",

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T1 - Control of nanomaterial self-assembly in ultrasonically levitated droplets

AU - Seddon, A.

AU - Richardson, Sam

AU - Rastogi, Kunal

AU - Plivelic, Tomas

AU - Squires, Adam

AU - Pfrang, Christian

PY - 2016/4/7

Y1 - 2016/4/7

N2 - We demonstrate that acoustic trapping can be used to levitate and manipulate droplets of soft matter, in particular, lyotropic mesophases formed from self-assembly of different surfactants and lipids, which can be analyzed in a contact-less manner by X-ray scattering in a controlled gas-phase environment. On the macroscopic length scale, the dimensions and the orientation of the particle are shaped by the ultrasonic field, while on the microscopic length scale the nanostructure can be controlled by varying the humidity of the atmosphere around the droplet. We demonstrate levitation and in situ phase transitions of micellar, hexagonal, bicontinuous cubic, and lamellar phases. The technique opens up a wide range of new experimental approaches of fundamental importance for environmental, biological, and chemical research.

AB - We demonstrate that acoustic trapping can be used to levitate and manipulate droplets of soft matter, in particular, lyotropic mesophases formed from self-assembly of different surfactants and lipids, which can be analyzed in a contact-less manner by X-ray scattering in a controlled gas-phase environment. On the macroscopic length scale, the dimensions and the orientation of the particle are shaped by the ultrasonic field, while on the microscopic length scale the nanostructure can be controlled by varying the humidity of the atmosphere around the droplet. We demonstrate levitation and in situ phase transitions of micellar, hexagonal, bicontinuous cubic, and lamellar phases. The technique opens up a wide range of new experimental approaches of fundamental importance for environmental, biological, and chemical research.

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EP - 1345

JO - Journal of Physical Chemistry Letters

JF - Journal of Physical Chemistry Letters

IS - 7

ER -

Control of nanomaterial self-assembly in ultrasonically levitated droplets

Abstract

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