A full voltage-controlled nanoelectrospray system and its steady characteristic analysed by empirically equivalent circuit method
A full voltage-controlled nanoelectrospray system and its steady characteristic analysed by empirically equivalent circuit method
Nanoelectrospray technique, or electrohydrodynamic spraying, has been utilised in wide applications including mass spectrometry, microcolloid thrusters and micro/nano-fabrication areas. In this article, a nanoelectrospray system was developed in a pure voltage-controlled fashion with low flow rates of nL/min. Electrospray occurs by applying a voltage to overcome surface tension of the liquid without auxiliary backpressure. Pronounced increase of current with applied voltage was revealed during the pressure-free spray. In the steady spray regime a linear correlation between current and voltage was clearly identified; this can be attributed directly to the unforced electrospray where the spray properties are uniquely dictated by the voltage. This behaviour may be captured by an equivalent circuit method based upon empirical results. The equivalent circuit resistance, derived from the best-fit model, represents an electrical equivalence of the gap between the nozzle and the collector; this resistance strongly depends on both the nozzle size and the spray distance. The suitability of an electrical equivalent is further confirmed by incorporating a series resistor. No obvious difference can be distinguished electrically between a resistor and the resistance of the gap, suggesting that unforced spray can be adjusted and stabilised externally by using the series resistor method
nanoelectrospray system, voltage-controlled form, I–V characteristic, equivalent circuit model
618-621
Wang, Ke
60aeff7b-b4c0-4b9d-8803-4578fd7ddef3
Tan, Zhikai
7c2a4bd9-3b7d-4ff8-96b0-d71b61d60f43
Ryan, Charles
3627e47b-01b8-4ddb-b248-4243aad1f872
Smith, Katherine
9093b9f6-16a3-4d4d-8361-a8be37e4fe2d
Paine, Mark
98cb74f5-14de-4f5b-8b85-8ce42f606bd2
Stark, John
cf8da964-ba02-4d93-b9d6-096fba5a31ab
27 March 2010
Wang, Ke
60aeff7b-b4c0-4b9d-8803-4578fd7ddef3
Tan, Zhikai
7c2a4bd9-3b7d-4ff8-96b0-d71b61d60f43
Ryan, Charles
3627e47b-01b8-4ddb-b248-4243aad1f872
Smith, Katherine
9093b9f6-16a3-4d4d-8361-a8be37e4fe2d
Paine, Mark
98cb74f5-14de-4f5b-8b85-8ce42f606bd2
Stark, John
cf8da964-ba02-4d93-b9d6-096fba5a31ab
Wang, Ke, Tan, Zhikai, Ryan, Charles, Smith, Katherine, Paine, Mark and Stark, John
(2010)
A full voltage-controlled nanoelectrospray system and its steady characteristic analysed by empirically equivalent circuit method.
Sensors and Actuators B: Chemical, 147 (2), .
(doi:10.1016/j.snb.2010.03.070).
Abstract
Nanoelectrospray technique, or electrohydrodynamic spraying, has been utilised in wide applications including mass spectrometry, microcolloid thrusters and micro/nano-fabrication areas. In this article, a nanoelectrospray system was developed in a pure voltage-controlled fashion with low flow rates of nL/min. Electrospray occurs by applying a voltage to overcome surface tension of the liquid without auxiliary backpressure. Pronounced increase of current with applied voltage was revealed during the pressure-free spray. In the steady spray regime a linear correlation between current and voltage was clearly identified; this can be attributed directly to the unforced electrospray where the spray properties are uniquely dictated by the voltage. This behaviour may be captured by an equivalent circuit method based upon empirical results. The equivalent circuit resistance, derived from the best-fit model, represents an electrical equivalence of the gap between the nozzle and the collector; this resistance strongly depends on both the nozzle size and the spray distance. The suitability of an electrical equivalent is further confirmed by incorporating a series resistor. No obvious difference can be distinguished electrically between a resistor and the resistance of the gap, suggesting that unforced spray can be adjusted and stabilised externally by using the series resistor method
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Published date: 27 March 2010
Keywords:
nanoelectrospray system, voltage-controlled form, I–V characteristic, equivalent circuit model
Organisations:
Astronautics Group
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Local EPrints ID: 384331
URI: http://eprints.soton.ac.uk/id/eprint/384331
ISSN: 0925-4005
PURE UUID: 82b0cc13-8d07-43bc-a1fc-f267ef0684a2
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Date deposited: 11 Dec 2015 14:54
Last modified: 14 Mar 2024 21:57
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Author:
Ke Wang
Author:
Zhikai Tan
Author:
Katherine Smith
Author:
Mark Paine
Author:
John Stark
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