Presenter Information

Christopher Fetrow

Program

Nanoscience and Microsystems Engineering

College

Engineering

Student Level

Doctoral

Location

PAÍS Building

Start Date

10-11-2022 11:00 AM

End Date

10-11-2022 1:00 PM

Abstract

Metal-CO2 batteries have emerged as a promising strategy to improve energy storage technology while capturing/concentrating carbon dioxide. The Al-CO2 battery has been previously as a primary battery to have an excellent discharge capacity when a small amount of oxygen is introduced. Herein we demonstrate an Al-CO2 battery that uses a homogeneous iodine-based redox mediator to enable the reversible discharge and charge of the battery with an ultra-low overpotential of 0.05V. By replacing oxygen gas with aluminum iodide in the electrolyte of the previously primary-only configuration, the battery maintains a high discharge capacity and can be recharged for 12 cycles at 20 mA/gcarbon. Without any additive the battery shows a negligible discharge capacity of 0.03 mAh/g when discharged at 20 mA/g to 0.5V, which is increased to 3,557 mAh/g when aluminum iodide is introduced. The capacity enhancement is present at a very low aluminum iodide concentration of 0.05M and shows low concentration dependence, indicating that the enhancement is due to a catalytic mechanism. The aluminum iodide additive also reduces stripping/plating overpotentials by 40% across a range of current rates compared to an unmodified imidazolium-based ionic liquid electrolyte. Scanning electron microscopy imaging of battery cathodes with and without aluminum iodide after discharge and charge show that the control battery without aluminum iodide does not form significant discharge product after discharge, and the discharge product remains after recharge. In contrast, the battery with added aluminum iodide shows significant discharge product formation after discharge, and that discharge product almost entirely degrades after recharge. 27Al nuclear magnetic resonance spectra and thermogravimetric analysis of the discharge product confirm the discharge product to be aluminum oxalate. Our work has successfully demonstrated a proof-of-concept rechargeable Al-CO2 battery that can be applied to cost-effective energy storage while capturing and concentrating carbon dioxide.

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Nov 10th, 11:00 AM Nov 10th, 1:00 PM

Rechargeable Al-CO2 battery using a homogeneous catalyst

PAÍS Building

Metal-CO2 batteries have emerged as a promising strategy to improve energy storage technology while capturing/concentrating carbon dioxide. The Al-CO2 battery has been previously as a primary battery to have an excellent discharge capacity when a small amount of oxygen is introduced. Herein we demonstrate an Al-CO2 battery that uses a homogeneous iodine-based redox mediator to enable the reversible discharge and charge of the battery with an ultra-low overpotential of 0.05V. By replacing oxygen gas with aluminum iodide in the electrolyte of the previously primary-only configuration, the battery maintains a high discharge capacity and can be recharged for 12 cycles at 20 mA/gcarbon. Without any additive the battery shows a negligible discharge capacity of 0.03 mAh/g when discharged at 20 mA/g to 0.5V, which is increased to 3,557 mAh/g when aluminum iodide is introduced. The capacity enhancement is present at a very low aluminum iodide concentration of 0.05M and shows low concentration dependence, indicating that the enhancement is due to a catalytic mechanism. The aluminum iodide additive also reduces stripping/plating overpotentials by 40% across a range of current rates compared to an unmodified imidazolium-based ionic liquid electrolyte. Scanning electron microscopy imaging of battery cathodes with and without aluminum iodide after discharge and charge show that the control battery without aluminum iodide does not form significant discharge product after discharge, and the discharge product remains after recharge. In contrast, the battery with added aluminum iodide shows significant discharge product formation after discharge, and that discharge product almost entirely degrades after recharge. 27Al nuclear magnetic resonance spectra and thermogravimetric analysis of the discharge product confirm the discharge product to be aluminum oxalate. Our work has successfully demonstrated a proof-of-concept rechargeable Al-CO2 battery that can be applied to cost-effective energy storage while capturing and concentrating carbon dioxide.