Ion transport and deposit growth in spatially coupled bipolar electrochemistry

In spatially coupled bipolar electrochemistry, electrodissolution and electrodeposition processes in an applied electric field are exploited to create directional growth of copper deposits between two copper discs, not physically linked to an external voltage source. Here, we study the electric fiel...

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Detalles Bibliográficos
Publicado:	1999
Materias:	Bipolar electrochemistry Contact formation Convection Directed wire growth Migration Simulation
Acceso en línea:	https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15726657_v478_n1-2_p128_Bradley http://hdl.handle.net/20.500.12110/paper_15726657_v478_n1-2_p128_Bradley
Aporte de:	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires

id	paper:paper_15726657_v478_n1-2_p128_Bradley
record_format	dspace
spelling	paper:paper_15726657_v478_n1-2_p128_Bradley2023-06-08T16:24:44Z Ion transport and deposit growth in spatially coupled bipolar electrochemistry Bipolar electrochemistry Contact formation Convection Directed wire growth Migration Simulation In spatially coupled bipolar electrochemistry, electrodissolution and electrodeposition processes in an applied electric field are exploited to create directional growth of copper deposits between two copper discs, not physically linked to an external voltage source. Here, we study the electric field in the whole cell through theoretical modeling, and ion transport in the interdisc region using optical and particle image velocimetry techniques. Their combined effect on incubation time and deposit morphology is assessed. Both the electric field and ion transport in the interdisc region are crucial factors in the characteristics of the interconnection. The model simulations reveal that the electric field is almost an order of magnitude larger in the region between discs as compared with the mean field value. Measurements and simulations show that the incubation time scales linearly with the inverse of the electric field, an indication that in this period, migration is the dominant transport mode. Experiments reveal that after branching develops, convection plays a relevant role as well, the contact growing linearly in time, with a change of the time/length slope at half the interdisc gap. © 1999 Elsevier Science S.A. All rights reserved. 1999 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15726657_v478_n1-2_p128_Bradley http://hdl.handle.net/20.500.12110/paper_15726657_v478_n1-2_p128_Bradley
institution	Universidad de Buenos Aires
institution_str	I-28
repository_str	R-134
collection	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic	Bipolar electrochemistry Contact formation Convection Directed wire growth Migration Simulation
spellingShingle	Bipolar electrochemistry Contact formation Convection Directed wire growth Migration Simulation Ion transport and deposit growth in spatially coupled bipolar electrochemistry
topic_facet	Bipolar electrochemistry Contact formation Convection Directed wire growth Migration Simulation
description	In spatially coupled bipolar electrochemistry, electrodissolution and electrodeposition processes in an applied electric field are exploited to create directional growth of copper deposits between two copper discs, not physically linked to an external voltage source. Here, we study the electric field in the whole cell through theoretical modeling, and ion transport in the interdisc region using optical and particle image velocimetry techniques. Their combined effect on incubation time and deposit morphology is assessed. Both the electric field and ion transport in the interdisc region are crucial factors in the characteristics of the interconnection. The model simulations reveal that the electric field is almost an order of magnitude larger in the region between discs as compared with the mean field value. Measurements and simulations show that the incubation time scales linearly with the inverse of the electric field, an indication that in this period, migration is the dominant transport mode. Experiments reveal that after branching develops, convection plays a relevant role as well, the contact growing linearly in time, with a change of the time/length slope at half the interdisc gap. © 1999 Elsevier Science S.A. All rights reserved.
title	Ion transport and deposit growth in spatially coupled bipolar electrochemistry
title_short	Ion transport and deposit growth in spatially coupled bipolar electrochemistry
title_full	Ion transport and deposit growth in spatially coupled bipolar electrochemistry
title_fullStr	Ion transport and deposit growth in spatially coupled bipolar electrochemistry
title_full_unstemmed	Ion transport and deposit growth in spatially coupled bipolar electrochemistry
title_sort	ion transport and deposit growth in spatially coupled bipolar electrochemistry
publishDate	1999
url	https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_15726657_v478_n1-2_p128_Bradley http://hdl.handle.net/20.500.12110/paper_15726657_v478_n1-2_p128_Bradley
_version_	1768543578675478528

Ion transport and deposit growth in spatially coupled bipolar electrochemistry

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