A Molten Salt Electrochemical Process for the Preparation of Cost-Effective p-Block (Coating) Materials

Prabhat Kumar Tripathy; Kunal Mondal

doi:10.3390/cryst12030385

A Molten Salt Electrochemical Process for the Preparation of Cost-Effective p-Block (Coating) Materials

Prabhat Kumar Tripathy, Kunal Mondal

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

1 Scopus citations

Abstract

Solar energy applications rely heavily on p-block elements and transition metals. Silicon is, by far, the most commonly used material in photovoltaic cells and accounts for about 85% of modules sold presently. Of late, thin film photovoltaic cells have gained momentum because of their higher efficiencies. Most of these thin film devices are made out of just five elements, namely, cadmium, tellurium, selenium, indium, gallium and copper. The present manuscript describes an elegant and inexpensive molten salt-based electrolytic process for fabricating a tellurium-coated metallic substrate. A three-electrode set up was employed to coat iridium with tellurium from a molten bath containing lithium chloride, lithium oxide and tellurium tetrachloride (LiCl-Li₂O-TeCl₄ ) at 650^◦C for a duration ranging from 30 to 120 min under a galvanostatic mode. The tellurium coating was observed to be thick, uniform, smooth and homogeneous. Additionally, the deposited tellurium did not chemically react with the iridium substrate to form intermetallic compounds, which is a good feature from the standpoint of the device’s performance characteristics. The present process, being generic in nature, shows the potential for the manufacture of both the coated substates and high-purity elements not just for tellurium but also for other p-block elements.

Original language	English
Article number	385
Journal	Crystals
Volume	12
Issue number	3
DOIs	https://doi.org/10.3390/cryst12030385
State	Published - Mar 2022
Externally published	Yes

Funding

Acknowledgments: The work was supported by the Idaho National Laboratory Directed Research and Development Program under DOE Idaho Operations Office. The manuscript was authorized by Battelle Energy Alliances under the contract No. DE-AC07-05ID14517, with the US Department of Energy, for publication. The US government retains and the publisher, by accepting the manuscript for publication, acknowledges that the US government retains a non-exclusive, paid up irrevocable worldwide license to publish or reproduce the published form of this manuscript or allow others to do so for United States Government purposes. The work was supported by the Idaho National Laboratory Directed Research and Development Program under DOE Idaho Operations Office. The manuscript was authorized by Battelle Energy Alliances under the contract No. DE-AC07-05ID14517, with the US Department of Energy, for publication. The US government retains and the publisher, by accepting the manuscript for publication, acknowledges that the US government retains a non-exclusive, paid up irrevocable worldwide license to publish or reproduce the published form of this manuscript or allow others to do so for United States Government purposes.

Keywords

coated component
galvanostatic deposition
molten salt
p-block elements
three-electrode set up

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10.3390/cryst12030385

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title = "A Molten Salt Electrochemical Process for the Preparation of Cost-Effective p-Block (Coating) Materials",

abstract = "Solar energy applications rely heavily on p-block elements and transition metals. Silicon is, by far, the most commonly used material in photovoltaic cells and accounts for about 85\% of modules sold presently. Of late, thin film photovoltaic cells have gained momentum because of their higher efficiencies. Most of these thin film devices are made out of just five elements, namely, cadmium, tellurium, selenium, indium, gallium and copper. The present manuscript describes an elegant and inexpensive molten salt-based electrolytic process for fabricating a tellurium-coated metallic substrate. A three-electrode set up was employed to coat iridium with tellurium from a molten bath containing lithium chloride, lithium oxide and tellurium tetrachloride (LiCl-Li2O-TeCl4 ) at 650◦C for a duration ranging from 30 to 120 min under a galvanostatic mode. The tellurium coating was observed to be thick, uniform, smooth and homogeneous. Additionally, the deposited tellurium did not chemically react with the iridium substrate to form intermetallic compounds, which is a good feature from the standpoint of the device{\textquoteright}s performance characteristics. The present process, being generic in nature, shows the potential for the manufacture of both the coated substates and high-purity elements not just for tellurium but also for other p-block elements.",

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N2 - Solar energy applications rely heavily on p-block elements and transition metals. Silicon is, by far, the most commonly used material in photovoltaic cells and accounts for about 85% of modules sold presently. Of late, thin film photovoltaic cells have gained momentum because of their higher efficiencies. Most of these thin film devices are made out of just five elements, namely, cadmium, tellurium, selenium, indium, gallium and copper. The present manuscript describes an elegant and inexpensive molten salt-based electrolytic process for fabricating a tellurium-coated metallic substrate. A three-electrode set up was employed to coat iridium with tellurium from a molten bath containing lithium chloride, lithium oxide and tellurium tetrachloride (LiCl-Li2O-TeCl4 ) at 650◦C for a duration ranging from 30 to 120 min under a galvanostatic mode. The tellurium coating was observed to be thick, uniform, smooth and homogeneous. Additionally, the deposited tellurium did not chemically react with the iridium substrate to form intermetallic compounds, which is a good feature from the standpoint of the device’s performance characteristics. The present process, being generic in nature, shows the potential for the manufacture of both the coated substates and high-purity elements not just for tellurium but also for other p-block elements.

AB - Solar energy applications rely heavily on p-block elements and transition metals. Silicon is, by far, the most commonly used material in photovoltaic cells and accounts for about 85% of modules sold presently. Of late, thin film photovoltaic cells have gained momentum because of their higher efficiencies. Most of these thin film devices are made out of just five elements, namely, cadmium, tellurium, selenium, indium, gallium and copper. The present manuscript describes an elegant and inexpensive molten salt-based electrolytic process for fabricating a tellurium-coated metallic substrate. A three-electrode set up was employed to coat iridium with tellurium from a molten bath containing lithium chloride, lithium oxide and tellurium tetrachloride (LiCl-Li2O-TeCl4 ) at 650◦C for a duration ranging from 30 to 120 min under a galvanostatic mode. The tellurium coating was observed to be thick, uniform, smooth and homogeneous. Additionally, the deposited tellurium did not chemically react with the iridium substrate to form intermetallic compounds, which is a good feature from the standpoint of the device’s performance characteristics. The present process, being generic in nature, shows the potential for the manufacture of both the coated substates and high-purity elements not just for tellurium but also for other p-block elements.

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KW - galvanostatic deposition

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KW - p-block elements

KW - three-electrode set up

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DO - 10.3390/cryst12030385

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AN - SCOPUS:85127072980

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ER -

A Molten Salt Electrochemical Process for the Preparation of Cost-Effective p-Block (Coating) Materials

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