A Systematic Analysis of the Costs and Environmental Impacts of Critical Materials Recovery from Hybrid Electric Vehicle Batteries in the U.S

Overview

Journal iScience

Publisher Cell Press

Date 2022 Sep 2

PMID 36051186

Authors

Chukwunwike O Iloeje

Alinson Santos Xavier

Diane Graziano

John Atkins

Kyle Sun

Joe Cresko

Sarang D Supekar

Affiliations

Soon will be listed here.

Abstract

Critical materials such as rare earth underpin technologies needed for a decarbonized global economy. Recycling can mitigate the supply risks created by the increasing demand and net import dependence, and enable a circular economy for critical materials. In this study, we analyze the feasibility and life-cycle impacts of recovering critical materials from spent nickel metal hydride batteries from hybrid electric vehicles in the U.S., accounting for stocks, battery scrappage, and end-of-life reverse logistics, given uncertain future availability scenarios. Our results show that the total collection and recycling costs depend strongly on future battery availability, with marginal costs exceeding marginal revenues when the availability of spent batteries declines. We quantify the potential of recycling to reduce primary imports, as well as the accompanying climate change and resource impacts. We explore the underlying reverse logistics infrastructure required for battery recycling and evaluate strategies for reducing associated capital investment risk.

Citing Articles

Extension of the π-system of monoaryl-substituted norbornadienes with acetylene bridges: influence on the photochemical conversion and storage of light energy.

Schulte R, Schade D, Paululat T, Zahringer T, Kerzig C, Ihmels H Beilstein J Org Chem. 2024; 20:3061-3068.

PMID: 39600952 PMC: 11590010. DOI: 10.3762/bjoc.20.254.

Protocol for designing, optimizing, and analyzing reverse supply chains using RELOG.

Iloeje C, Santos Xavier A, Atkins J, Sun K, Gallier A STAR Protoc. 2022; 4(1):101913.

PMID: 36548130 PMC: 9795519. DOI: 10.1016/j.xpro.2022.101913.

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