Assembly of Coupled Redox Fuel Cells Using Copper As Electron Acceptors to Generate Power and Its In-situ Retrieval

Overview

Journal Sci Rep

Specialty Science

Date 2016 Feb 16

PMID 26877144

Citations 1

Authors

Hui-Min Zhang

Wei Xu

Gang Li

Zhan-Meng Liu

Zu-Cheng Wu

Bo-Geng Li

Affiliations

Soon will be listed here.

Abstract

Energy extraction from waste has attracted much interest nowadays. Herein, a coupled redox fuel cell (CRFC) device using heavy metals, such as copper, as an electron acceptor is assembled to testify the recoveries of both electricity and the precious metal without energy consumption. In this study, a NaBH4-Cu(II) CRFC was employed as an example to retrieve copper from a dilute solution with self-electricity production. The properties of the CRFC have been characterized, and the open circuit voltage was 1.65 V with a maximum power density of 7.2 W m(-2) at an initial Cu(2+) concentration of 1,600 mg L(-1) in the catholyte. 99.9% of the 400 mg L(-1) copper was harvested after operation for 24 h, and the product formed on the cathode was identified as elemental copper. The CRFC demonstrated that useful chemicals were recovered and the electricity contained in the chemicals was produced in a self-powered retrieval process.

Citing Articles

Electrochemistry and microbiology of microbial fuel cells treating marine sediments polluted with heavy metals.

Abbas S, Rafatullah M, Ismail N, Shakoori F RSC Adv. 2022; 8(34):18800-18813.

PMID: 35539672 PMC: 9080629. DOI: 10.1039/c8ra01711e.

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