Effect of Temperature and Voltage on the Preparation of Solid Carbon by Electrolysis of a Molten CaCO3-Li2CO3-LiCl Electrolyte

The present study investigated the preparation of solid carbon through the electrolysis of a newly formulated molten salt electrolyte containing CaCO3–Li2CO3–LiCl with a continuous cell voltage of 4 – 6V, and temperatures of 550 and 650°C. The process was carried out in a two-electrode cell using AI...

Full description

Saved in:
Bibliographic Details
Published in:International journal of electrochemical science 2018-10, Vol.13 (10), p.9771-9783
Main Authors: Jin, Karen Wong Min, Gakim, Miron, Janaun, Jidon A., Willey Liew, Y.H., Siambun, Nancy J.
Format: Article
Language:English
Subjects:
Carbon
effect
electro-deposition
electrolysis
molten salts
temperature
voltage
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The present study investigated the preparation of solid carbon through the electrolysis of a newly formulated molten salt electrolyte containing CaCO3–Li2CO3–LiCl with a continuous cell voltage of 4 – 6V, and temperatures of 550 and 650°C. The process was carried out in a two-electrode cell using AISI 304 stainless steel electrodes in CO2 gas environment. CO2 gas was captured and electro-converted to solid carbon, and deposited on the cathode surface. SEM images revealed five dominant microstructures: grape-like, tubes, thread-like, spheres, and flakes. These materials consist of 69 – 80% carbon content based on EA analysis. Single wall nanotube structures of 13 – 90nm outer diameter was also detected under TEM analysis. The result revealed that electrolysis voltage and temperature changes affected the microstructures, quantity of the deposited carbon, and the efficiency of electro-conversion process. The size of the carbon microstructures declined, and carbon deposition rate increased as both voltage and temperature were increased. However, it reduced the efficiency of the process, thus using more energy per g of carbon produced.
ISSN:1452-3981
1452-3981
DOI:10.20964/2018.10.43