Electrochemical Ammonia Synthesis: The Energy Efficiency Challenge

Yuanyuan Zhou; Xianbiao Fu; Ib Chorkendorff; Jens K. Nørskov

doi:10.1021/acsenergylett.4c02954

Electrochemical Ammonia Synthesis: The Energy Efficiency Challenge

Yuanyuan Zhou, Xianbiao Fu, Ib Chorkendorff^*, Jens K. Nørskov^*

^*Corresponding author for this work

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Abstract

We discuss the challenges associated with achieving high energy efficiency in electrochemical ammonia synthesis at near-ambient conditions. The current Li-mediated process has a theoretical maximum energy efficiency of ∼28%, since Li deposition gives rise to a very large effective overpotential. As a starting point toward finding electrocatalysts with lower effective overpotentials, we show that one reason why Li and alkaline earth metals work as N₂ reduction electrocatalysts at ambient conditions is that the thermal elemental processes, N₂ dissociation and NH₃ desorption, are both facile at room temperature for these metals. Many transition metals, which have less negative reduction potentials and thus lower effective overpotentials, can dissociate N₂ at these conditions but they all bind NH₃ too strongly. Strategies to circumvent this problem are discussed, as are the other requirements for a good N₂ reduction electrocatalyst.

Original language	English
Journal	ACS Energy Letters
Volume	10
Pages (from-to)	128-132
ISSN	2380-8195
DOIs	https://doi.org/10.1021/acsenergylett.4c02954
Publication status	Published - 2025

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© 2024 The Authors. Published by American Chemical Society.

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title = "Electrochemical Ammonia Synthesis: The Energy Efficiency Challenge",

abstract = "We discuss the challenges associated with achieving high energy efficiency in electrochemical ammonia synthesis at near-ambient conditions. The current Li-mediated process has a theoretical maximum energy efficiency of ∼28%, since Li deposition gives rise to a very large effective overpotential. As a starting point toward finding electrocatalysts with lower effective overpotentials, we show that one reason why Li and alkaline earth metals work as N2 reduction electrocatalysts at ambient conditions is that the thermal elemental processes, N2 dissociation and NH3 desorption, are both facile at room temperature for these metals. Many transition metals, which have less negative reduction potentials and thus lower effective overpotentials, can dissociate N2 at these conditions but they all bind NH3 too strongly. Strategies to circumvent this problem are discussed, as are the other requirements for a good N2 reduction electrocatalyst.",

author = "Yuanyuan Zhou and Xianbiao Fu and Ib Chorkendorff and N{\o}rskov, {Jens K.}",

note = "Publisher Copyright: {\textcopyright} 2024 The Authors. Published by American Chemical Society.",

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doi = "10.1021/acsenergylett.4c02954",

language = "English",

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pages = "128--132",

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T1 - Electrochemical Ammonia Synthesis

T2 - The Energy Efficiency Challenge

AU - Zhou, Yuanyuan

AU - Fu, Xianbiao

AU - Chorkendorff, Ib

AU - Nørskov, Jens K.

PY - 2025

Y1 - 2025

N2 - We discuss the challenges associated with achieving high energy efficiency in electrochemical ammonia synthesis at near-ambient conditions. The current Li-mediated process has a theoretical maximum energy efficiency of ∼28%, since Li deposition gives rise to a very large effective overpotential. As a starting point toward finding electrocatalysts with lower effective overpotentials, we show that one reason why Li and alkaline earth metals work as N2 reduction electrocatalysts at ambient conditions is that the thermal elemental processes, N2 dissociation and NH3 desorption, are both facile at room temperature for these metals. Many transition metals, which have less negative reduction potentials and thus lower effective overpotentials, can dissociate N2 at these conditions but they all bind NH3 too strongly. Strategies to circumvent this problem are discussed, as are the other requirements for a good N2 reduction electrocatalyst.

AB - We discuss the challenges associated with achieving high energy efficiency in electrochemical ammonia synthesis at near-ambient conditions. The current Li-mediated process has a theoretical maximum energy efficiency of ∼28%, since Li deposition gives rise to a very large effective overpotential. As a starting point toward finding electrocatalysts with lower effective overpotentials, we show that one reason why Li and alkaline earth metals work as N2 reduction electrocatalysts at ambient conditions is that the thermal elemental processes, N2 dissociation and NH3 desorption, are both facile at room temperature for these metals. Many transition metals, which have less negative reduction potentials and thus lower effective overpotentials, can dissociate N2 at these conditions but they all bind NH3 too strongly. Strategies to circumvent this problem are discussed, as are the other requirements for a good N2 reduction electrocatalyst.

U2 - 10.1021/acsenergylett.4c02954

DO - 10.1021/acsenergylett.4c02954

M3 - Letter

AN - SCOPUS:85212223750

SN - 2380-8195

VL - 10

SP - 128

EP - 132

JO - ACS Energy Letters

JF - ACS Energy Letters

ER -

Electrochemical Ammonia Synthesis: The Energy Efficiency Challenge

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