Optimization of Ni−Co−Fe-Based Catalysts for Oxygen Evolution Reaction by Surface and Relaxation Phenomena Analysis

Rinat Attias; Kalimuthu Vijaya Sankar; Kapil Dhaka; Wenjamin Moschkowitsch; Lior Elbaz; Maytal Caspary Toroker; Yoed Tsur

doi:10.1002/cssc.202002946

Optimization of Ni−Co−Fe-Based Catalysts for Oxygen Evolution Reaction by Surface and Relaxation Phenomena Analysis

Rinat Attias, Kalimuthu Vijaya Sankar, Kapil Dhaka, Wenjamin Moschkowitsch, Lior Elbaz, Maytal Caspary Toroker, Yoed Tsur

Technion - Israel Institute of Technology, Bar-Ilan University

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

Abstract

Trimetallic double hydroxide NiFeCo−OH is prepared by coprecipitation, from which three different catalysts are fabricated by different heat treatments, all at 350 °C maximum temperature. Among the prepared catalysts, the one prepared at a heating and cooling rate of 2 °C min⁻¹ in N₂ atmosphere (designated NiFeCo−N₂-2 °C) displays the best catalytic properties after stability testing, exhibiting a high current density (9.06 mA cm⁻² at 320 mV), low Tafel slope (72.9 mV dec⁻¹), good stability (over 20 h), high turnover frequency (0.304 s⁻¹), and high mass activity (46.52 A g⁻¹ at 320 mV). Stability tests reveal that the hydroxide phase is less suitable for long-term use than catalysts with an oxide phase. Two causes are identified for the loss of stability in the hydroxide phase: a) Modeling of the distribution function of relaxation times (DFRT) reveals the increase in resistance contributed by various relaxation processes; b) density functional theory (DFT) surface energy calculations reveal that the higher surface energy of the hydroxide-phase catalyst impairs the stability. These findings represent a new strategy to optimize catalysts for water splitting.

Original language	English
Pages (from-to)	1737-1746
Number of pages	10
Journal	ChemSusChem
Volume	14
Issue number	7
DOIs	https://doi.org/10.1002/cssc.202002946
State	Published - 9 Apr 2021

Keywords

density functional calculations
electrocatalysis
hydroxides
porous materials
relaxation processes

All Science Journal Classification (ASJC) codes

Environmental Chemistry
General Chemical Engineering
General Materials Science
General Energy

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1002/cssc.202002946

Cite this

@article{6f546dabba8440fdb42653076d798fd6,

title = "Optimization of Ni−Co−Fe-Based Catalysts for Oxygen Evolution Reaction by Surface and Relaxation Phenomena Analysis",

abstract = "Trimetallic double hydroxide NiFeCo−OH is prepared by coprecipitation, from which three different catalysts are fabricated by different heat treatments, all at 350 °C maximum temperature. Among the prepared catalysts, the one prepared at a heating and cooling rate of 2 °C min−1 in N2 atmosphere (designated NiFeCo−N2-2 °C) displays the best catalytic properties after stability testing, exhibiting a high current density (9.06 mA cm−2 at 320 mV), low Tafel slope (72.9 mV dec−1), good stability (over 20 h), high turnover frequency (0.304 s−1), and high mass activity (46.52 A g−1 at 320 mV). Stability tests reveal that the hydroxide phase is less suitable for long-term use than catalysts with an oxide phase. Two causes are identified for the loss of stability in the hydroxide phase: a) Modeling of the distribution function of relaxation times (DFRT) reveals the increase in resistance contributed by various relaxation processes; b) density functional theory (DFT) surface energy calculations reveal that the higher surface energy of the hydroxide-phase catalyst impairs the stability. These findings represent a new strategy to optimize catalysts for water splitting.",

keywords = "density functional calculations, electrocatalysis, hydroxides, porous materials, relaxation processes",

author = "Rinat Attias and \{Vijaya Sankar\}, Kalimuthu and Kapil Dhaka and Wenjamin Moschkowitsch and Lior Elbaz and \{Caspary Toroker\}, Maytal and Yoed Tsur",

note = "Publisher Copyright: {\textcopyright} 2021 Wiley-VCH GmbH",

year = "2021",

month = apr,

day = "9",

doi = "10.1002/cssc.202002946",

language = "الإنجليزيّة",

volume = "14",

pages = "1737--1746",

journal = "ChemSusChem",

issn = "1864-5631",

publisher = "Wiley-VCH Verlag",

number = "7",

}

TY - JOUR

T1 - Optimization of Ni−Co−Fe-Based Catalysts for Oxygen Evolution Reaction by Surface and Relaxation Phenomena Analysis

AU - Attias, Rinat

AU - Vijaya Sankar, Kalimuthu

AU - Dhaka, Kapil

AU - Moschkowitsch, Wenjamin

AU - Elbaz, Lior

AU - Caspary Toroker, Maytal

AU - Tsur, Yoed

PY - 2021/4/9

Y1 - 2021/4/9

N2 - Trimetallic double hydroxide NiFeCo−OH is prepared by coprecipitation, from which three different catalysts are fabricated by different heat treatments, all at 350 °C maximum temperature. Among the prepared catalysts, the one prepared at a heating and cooling rate of 2 °C min−1 in N2 atmosphere (designated NiFeCo−N2-2 °C) displays the best catalytic properties after stability testing, exhibiting a high current density (9.06 mA cm−2 at 320 mV), low Tafel slope (72.9 mV dec−1), good stability (over 20 h), high turnover frequency (0.304 s−1), and high mass activity (46.52 A g−1 at 320 mV). Stability tests reveal that the hydroxide phase is less suitable for long-term use than catalysts with an oxide phase. Two causes are identified for the loss of stability in the hydroxide phase: a) Modeling of the distribution function of relaxation times (DFRT) reveals the increase in resistance contributed by various relaxation processes; b) density functional theory (DFT) surface energy calculations reveal that the higher surface energy of the hydroxide-phase catalyst impairs the stability. These findings represent a new strategy to optimize catalysts for water splitting.

AB - Trimetallic double hydroxide NiFeCo−OH is prepared by coprecipitation, from which three different catalysts are fabricated by different heat treatments, all at 350 °C maximum temperature. Among the prepared catalysts, the one prepared at a heating and cooling rate of 2 °C min−1 in N2 atmosphere (designated NiFeCo−N2-2 °C) displays the best catalytic properties after stability testing, exhibiting a high current density (9.06 mA cm−2 at 320 mV), low Tafel slope (72.9 mV dec−1), good stability (over 20 h), high turnover frequency (0.304 s−1), and high mass activity (46.52 A g−1 at 320 mV). Stability tests reveal that the hydroxide phase is less suitable for long-term use than catalysts with an oxide phase. Two causes are identified for the loss of stability in the hydroxide phase: a) Modeling of the distribution function of relaxation times (DFRT) reveals the increase in resistance contributed by various relaxation processes; b) density functional theory (DFT) surface energy calculations reveal that the higher surface energy of the hydroxide-phase catalyst impairs the stability. These findings represent a new strategy to optimize catalysts for water splitting.

KW - density functional calculations

KW - electrocatalysis

KW - hydroxides

KW - porous materials

KW - relaxation processes

UR - http://www.scopus.com/inward/record.url?scp=85101399825&partnerID=8YFLogxK

U2 - 10.1002/cssc.202002946

DO - 10.1002/cssc.202002946

M3 - مقالة

C2 - 33561301

SN - 1864-5631

VL - 14

SP - 1737

EP - 1746

JO - ChemSusChem

JF - ChemSusChem

IS - 7

ER -

Optimization of Ni−Co−Fe-Based Catalysts for Oxygen Evolution Reaction by Surface and Relaxation Phenomena Analysis

Abstract

Keywords

All Science Journal Classification (ASJC) codes

UN SDGs

Access to Document

Other files and links

Fingerprint

Cite this