Interaction of passivated clusters in solution with micro-patterned surfaces: guided flow versus defect pinning

Andrew Parker; Peter Childs; Richard Palmer; M Brust

doi:10.1088/0957-4484/12/1/302

Interaction of passivated clusters in solution with micro-patterned surfaces: guided flow versus defect pinning

Andrew Parker, Peter Childs, Richard Palmer, M Brust

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13 Citations (Scopus)

Abstract

Gold nanoclusters, chemically passivated with decanethiol and dissolved in toluene, have been deposited from solution onto selected regions of oxidized silicon (100) surfaces patterned either with photoresist or an etched step. When the perimeter of a droplet crosses the boundary between the resist and the silicon surface, we observe transport of cluster solution along such discontinuities, outside of the droplet. Such guided flow can extend for over 600 mum across the surface, producing cluster chains as narrow as similar to 120 nm, once the toluene has evaporated. The same experiment with an etched step produces no transport of clusters, but rather selective deposition and growth around the discontinuity. These different responses are attributed to the step/boundary material-principally its interaction with the toluene solvent during evaporation.

Original language	English
Pages (from-to)	6-10
Number of pages	5
Journal	Nanotechnology
Volume	12
Issue number	1
Early online date	16 Nov 2000
DOIs	https://doi.org/10.1088/0957-4484/12/1/302
Publication status	Published - 1 Mar 2001

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abstract = "Gold nanoclusters, chemically passivated with decanethiol and dissolved in toluene, have been deposited from solution onto selected regions of oxidized silicon (100) surfaces patterned either with photoresist or an etched step. When the perimeter of a droplet crosses the boundary between the resist and the silicon surface, we observe transport of cluster solution along such discontinuities, outside of the droplet. Such guided flow can extend for over 600 mum across the surface, producing cluster chains as narrow as similar to 120 nm, once the toluene has evaporated. The same experiment with an etched step produces no transport of clusters, but rather selective deposition and growth around the discontinuity. These different responses are attributed to the step/boundary material-principally its interaction with the toluene solvent during evaporation.",

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AB - Gold nanoclusters, chemically passivated with decanethiol and dissolved in toluene, have been deposited from solution onto selected regions of oxidized silicon (100) surfaces patterned either with photoresist or an etched step. When the perimeter of a droplet crosses the boundary between the resist and the silicon surface, we observe transport of cluster solution along such discontinuities, outside of the droplet. Such guided flow can extend for over 600 mum across the surface, producing cluster chains as narrow as similar to 120 nm, once the toluene has evaporated. The same experiment with an etched step produces no transport of clusters, but rather selective deposition and growth around the discontinuity. These different responses are attributed to the step/boundary material-principally its interaction with the toluene solvent during evaporation.

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Interaction of passivated clusters in solution with micro-patterned surfaces: guided flow versus defect pinning

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