Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes

Shengda D. Pu; Chen Gong; Yuanbo T. Tang; Ziyang Ning; Junliang Liu; Shengming Zhang; Yi Yuan; Dominic Melvin; Sixie Yang; Liquan Pi; John‐Joseph Marie; Bingkun Hu; Max Jenkins; Zixuan Li; Boyang Liu; S. C. Edman Tsang; T. James Marrow; Roger C. Reed; Xiangwen Gao; Peter G. Bruce; Alex W. Robertson

doi:10.1002/adma.202202552

Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes

Shengda D. Pu, Chen Gong, Yuanbo T. Tang, Ziyang Ning, Junliang Liu, Shengming Zhang, Yi Yuan, Dominic Melvin, Sixie Yang, Liquan Pi, John‐Joseph Marie, Bingkun Hu, Max Jenkins, Zixuan Li, Boyang Liu, S. C. Edman Tsang, T. James Marrow, Roger C. Reed, Xiangwen Gao^*, Peter G. Bruce^*Alex W. Robertson^*

^*Corresponding author for this work

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

32 Downloads (Pure)

Abstract

Despite being one of the most promising candidates for grid-level energy storage, practical aqueous zinc batteries are limited by dendrite formation, which leads to significantly compromised safety and cycling performance. In this study, by using single-crystal Zn-metal anodes, reversible electrodeposition of planar Zn with a high capacity of 8 mAh cm⁻² can be achieved at an unprecedentedly high current density of 200 mA cm⁻². This dendrite-free electrode is well maintained even after prolonged cycling (>1200 cycles at 50 mA cm⁻²). Such excellent electrochemical performance is due to single-crystal Zn suppressing the major sources of defect generation during electroplating and heavily favoring planar deposition morphologies. As so few defect sites form, including those that would normally be found along grain boundaries or to accommodate lattice mismatch, there is little opportunity for dendritic structures to nucleate, even under extreme plating rates. This scarcity of defects is in part due to perfect atomic-stitching between merging Zn islands, ensuring no defective shallow-angle grain boundaries are formed and thus removing a significant source of non-planar Zn nucleation. It is demonstrated that an ideal high-rate Zn anode should offer perfect lattice matching as this facilitates planar epitaxial Zn growth and minimizes the formation of any defective regions.

Original language	English
Article number	2202552
Number of pages	9
Journal	Advanced Materials
Volume	34
Issue number	28
Early online date	12 May 2022
DOIs	https://doi.org/10.1002/adma.202202552
Publication status	Published - 14 Jul 2022

Bibliographical note

Acknowledgments:
A.W.R. thanks the support of the Royal Society. P.G.B. is indebted to the Engineering and Physical Sciences Research Council (EPSRC), including Henry Royce Institute for Advanced Materials and the Faraday Institution for financial support. The X.C.T. was facilitated by EPSRC grant EP/M02833X/1. The Zeiss Crossbeam FIB/SEM was supported by EPSRC grant EP/N010868/1. The authors thank the support and acknowledge the use of the facilities of the DCCEM, at the Materials Department, Oxford (EP/R010145/1).

Keywords

electroplating
zinc-metal anodes
zinc rechargeable batteries

Access to Document

10.1002/adma.202202552Licence: Creative Commons: Attribution (CC BY)

PuS2022AchievingFinal published version, 2.15 MBLicence: Creative Commons: Attribution (CC BY)

Cite this

Pu, S. D., Gong, C., Tang, Y. T., Ning, Z., Liu, J., Zhang, S., Yuan, Y., Melvin, D., Yang, S., Pi, L., Marie, JJ., Hu, B., Jenkins, M., Li, Z., Liu, B., Tsang, S. C. E., Marrow, T. J., Reed, R. C., Gao, X., ... Robertson, A. W. (2022). Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes. Advanced Materials, 34(28), Article 2202552. https://doi.org/10.1002/adma.202202552

@article{1ddab449246743daa2a9aa00f57a2e92,

title = "Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes",

abstract = "Despite being one of the most promising candidates for grid-level energy storage, practical aqueous zinc batteries are limited by dendrite formation, which leads to significantly compromised safety and cycling performance. In this study, by using single-crystal Zn-metal anodes, reversible electrodeposition of planar Zn with a high capacity of 8 mAh cm−2 can be achieved at an unprecedentedly high current density of 200 mA cm−2. This dendrite-free electrode is well maintained even after prolonged cycling (>1200 cycles at 50 mA cm−2). Such excellent electrochemical performance is due to single-crystal Zn suppressing the major sources of defect generation during electroplating and heavily favoring planar deposition morphologies. As so few defect sites form, including those that would normally be found along grain boundaries or to accommodate lattice mismatch, there is little opportunity for dendritic structures to nucleate, even under extreme plating rates. This scarcity of defects is in part due to perfect atomic-stitching between merging Zn islands, ensuring no defective shallow-angle grain boundaries are formed and thus removing a significant source of non-planar Zn nucleation. It is demonstrated that an ideal high-rate Zn anode should offer perfect lattice matching as this facilitates planar epitaxial Zn growth and minimizes the formation of any defective regions.",

keywords = "electroplating, zinc-metal anodes, zinc rechargeable batteries",

author = "Pu, {Shengda D.} and Chen Gong and Tang, {Yuanbo T.} and Ziyang Ning and Junliang Liu and Shengming Zhang and Yi Yuan and Dominic Melvin and Sixie Yang and Liquan Pi and John‐Joseph Marie and Bingkun Hu and Max Jenkins and Zixuan Li and Boyang Liu and Tsang, {S. C. Edman} and Marrow, {T. James} and Reed, {Roger C.} and Xiangwen Gao and Bruce, {Peter G.} and Robertson, {Alex W.}",

note = "Acknowledgments: A.W.R. thanks the support of the Royal Society. P.G.B. is indebted to the Engineering and Physical Sciences Research Council (EPSRC), including Henry Royce Institute for Advanced Materials and the Faraday Institution for financial support. The X.C.T. was facilitated by EPSRC grant EP/M02833X/1. The Zeiss Crossbeam FIB/SEM was supported by EPSRC grant EP/N010868/1. The authors thank the support and acknowledge the use of the facilities of the DCCEM, at the Materials Department, Oxford (EP/R010145/1).",

year = "2022",

month = jul,

day = "14",

doi = "10.1002/adma.202202552",

language = "English",

volume = "34",

journal = "Advanced Materials",

issn = "0935-9648",

publisher = "Wiley-VCH Verlag",

number = "28",

}

Pu, SD, Gong, C, Tang, YT, Ning, Z, Liu, J, Zhang, S, Yuan, Y, Melvin, D, Yang, S, Pi, L, Marie, JJ, Hu, B, Jenkins, M, Li, Z, Liu, B, Tsang, SCE, Marrow, TJ, Reed, RC, Gao, X, Bruce, PG & Robertson, AW 2022, 'Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes', Advanced Materials, vol. 34, no. 28, 2202552. https://doi.org/10.1002/adma.202202552

TY - JOUR

T1 - Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes

AU - Pu, Shengda D.

AU - Gong, Chen

AU - Tang, Yuanbo T.

AU - Ning, Ziyang

AU - Liu, Junliang

AU - Zhang, Shengming

AU - Yuan, Yi

AU - Melvin, Dominic

AU - Yang, Sixie

AU - Pi, Liquan

AU - Marie, John‐Joseph

AU - Hu, Bingkun

AU - Jenkins, Max

AU - Li, Zixuan

AU - Liu, Boyang

AU - Tsang, S. C. Edman

AU - Marrow, T. James

AU - Reed, Roger C.

AU - Gao, Xiangwen

AU - Bruce, Peter G.

AU - Robertson, Alex W.

N1 - Acknowledgments: A.W.R. thanks the support of the Royal Society. P.G.B. is indebted to the Engineering and Physical Sciences Research Council (EPSRC), including Henry Royce Institute for Advanced Materials and the Faraday Institution for financial support. The X.C.T. was facilitated by EPSRC grant EP/M02833X/1. The Zeiss Crossbeam FIB/SEM was supported by EPSRC grant EP/N010868/1. The authors thank the support and acknowledge the use of the facilities of the DCCEM, at the Materials Department, Oxford (EP/R010145/1).

PY - 2022/7/14

Y1 - 2022/7/14

N2 - Despite being one of the most promising candidates for grid-level energy storage, practical aqueous zinc batteries are limited by dendrite formation, which leads to significantly compromised safety and cycling performance. In this study, by using single-crystal Zn-metal anodes, reversible electrodeposition of planar Zn with a high capacity of 8 mAh cm−2 can be achieved at an unprecedentedly high current density of 200 mA cm−2. This dendrite-free electrode is well maintained even after prolonged cycling (>1200 cycles at 50 mA cm−2). Such excellent electrochemical performance is due to single-crystal Zn suppressing the major sources of defect generation during electroplating and heavily favoring planar deposition morphologies. As so few defect sites form, including those that would normally be found along grain boundaries or to accommodate lattice mismatch, there is little opportunity for dendritic structures to nucleate, even under extreme plating rates. This scarcity of defects is in part due to perfect atomic-stitching between merging Zn islands, ensuring no defective shallow-angle grain boundaries are formed and thus removing a significant source of non-planar Zn nucleation. It is demonstrated that an ideal high-rate Zn anode should offer perfect lattice matching as this facilitates planar epitaxial Zn growth and minimizes the formation of any defective regions.

AB - Despite being one of the most promising candidates for grid-level energy storage, practical aqueous zinc batteries are limited by dendrite formation, which leads to significantly compromised safety and cycling performance. In this study, by using single-crystal Zn-metal anodes, reversible electrodeposition of planar Zn with a high capacity of 8 mAh cm−2 can be achieved at an unprecedentedly high current density of 200 mA cm−2. This dendrite-free electrode is well maintained even after prolonged cycling (>1200 cycles at 50 mA cm−2). Such excellent electrochemical performance is due to single-crystal Zn suppressing the major sources of defect generation during electroplating and heavily favoring planar deposition morphologies. As so few defect sites form, including those that would normally be found along grain boundaries or to accommodate lattice mismatch, there is little opportunity for dendritic structures to nucleate, even under extreme plating rates. This scarcity of defects is in part due to perfect atomic-stitching between merging Zn islands, ensuring no defective shallow-angle grain boundaries are formed and thus removing a significant source of non-planar Zn nucleation. It is demonstrated that an ideal high-rate Zn anode should offer perfect lattice matching as this facilitates planar epitaxial Zn growth and minimizes the formation of any defective regions.

KW - electroplating

KW - zinc-metal anodes

KW - zinc rechargeable batteries

U2 - 10.1002/adma.202202552

DO - 10.1002/adma.202202552

M3 - Article

SN - 0935-9648

VL - 34

JO - Advanced Materials

JF - Advanced Materials

IS - 28

M1 - 2202552

ER -

Achieving Ultrahigh‐Rate Planar and Dendrite‐Free Zinc Electroplating for Aqueous Zinc Battery Anodes

Abstract

Bibliographical note

Keywords

Access to Document

Fingerprint

Cite this