Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective

Maximilian Fichtner; Kristina Edström; Elixabete Ayerbe; Maitane Berecibar; Arghya Bhowmik; Ivano E. Castelli; Simon Clark; Robert Dominko; Merve Erakca; Alejandro A. Franco; Alexis Grimaud; Birger Horstmann; Arnulf Latz; Henning Lorrmann; Marcel Meeus; Rekha Narayan; Frank Pammer; Janna Ruhland; Helge Stein; Tejs Vegge; Marcel Weil

doi:10.1002/aenm.202102904

Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective

Maximilian Fichtner, Kristina Edström, Elixabete Ayerbe, Maitane Berecibar, Arghya Bhowmik, Ivano E. Castelli, Simon Clark, Robert Dominko, Merve Erakca, Alejandro A. Franco, Alexis Grimaud, Birger Horstmann, Arnulf Latz, Henning Lorrmann, Marcel Meeus, Rekha Narayan, Frank Pammer, Janna Ruhland, Helge Stein, Tejs VeggeMarcel Weil

Research output: Contribution to journal › Review article › peer-review

240 Scopus citations

Abstract

The development of new batteries has historically been achieved through discovery and development cycles based on the intuition of the researcher, followed by experimental trial and error—often helped along by serendipitous breakthroughs. Meanwhile, it is evident that new strategies are needed to master the ever-growing complexity in the development of battery systems, and to fast-track the transfer of findings from the laboratory into commercially viable products. This review gives an overview over the future needs and the current state-of-the art of five research pillars of the European Large-Scale Research Initiative BATTERY 2030+, namely 1) Battery Interface Genome in combination with a Materials Acceleration Platform (BIG-MAP), progress toward the development of 2) self-healing battery materials, and methods for operando, 3) sensing to monitor battery health. These subjects are complemented by an overview over current and up-coming strategies to optimize 4) manufacturability of batteries and efforts toward development of a circular battery economy through implementation of 5) recyclability aspects in the design of the battery.

Original language	English
Article number	2102904
Journal	Advanced Energy Materials
Volume	12
Issue number	17
DOIs	https://doi.org/10.1002/aenm.202102904
State	Published - 5 May 2022
Externally published	Yes

Keywords

battery 2030
battery recycling
machine learning
operando sensing
self-healing batteries

UN SDGs

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

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10.1002/aenm.202102904

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Fichtner, M., Edström, K., Ayerbe, E., Berecibar, M., Bhowmik, A., Castelli, I. E., Clark, S., Dominko, R., Erakca, M., Franco, A. A., Grimaud, A., Horstmann, B., Latz, A., Lorrmann, H., Meeus, M., Narayan, R., Pammer, F., Ruhland, J., Stein, H., ... Weil, M. (2022). Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective. Advanced Energy Materials, 12(17), Article 2102904. https://doi.org/10.1002/aenm.202102904

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title = "Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective",

abstract = "The development of new batteries has historically been achieved through discovery and development cycles based on the intuition of the researcher, followed by experimental trial and error—often helped along by serendipitous breakthroughs. Meanwhile, it is evident that new strategies are needed to master the ever-growing complexity in the development of battery systems, and to fast-track the transfer of findings from the laboratory into commercially viable products. This review gives an overview over the future needs and the current state-of-the art of five research pillars of the European Large-Scale Research Initiative BATTERY 2030+, namely 1) Battery Interface Genome in combination with a Materials Acceleration Platform (BIG-MAP), progress toward the development of 2) self-healing battery materials, and methods for operando, 3) sensing to monitor battery health. These subjects are complemented by an overview over current and up-coming strategies to optimize 4) manufacturability of batteries and efforts toward development of a circular battery economy through implementation of 5) recyclability aspects in the design of the battery.",

keywords = "battery 2030, battery recycling, machine learning, operando sensing, self-healing batteries",

author = "Maximilian Fichtner and Kristina Edstr{\"o}m and Elixabete Ayerbe and Maitane Berecibar and Arghya Bhowmik and Castelli, {Ivano E.} and Simon Clark and Robert Dominko and Merve Erakca and Franco, {Alejandro A.} and Alexis Grimaud and Birger Horstmann and Arnulf Latz and Henning Lorrmann and Marcel Meeus and Rekha Narayan and Frank Pammer and Janna Ruhland and Helge Stein and Tejs Vegge and Marcel Weil",

note = "Publisher Copyright: {\textcopyright} 2021 The Authors. Advanced Energy Materials published by Wiley-VCH GmbH.",

year = "2022",

month = may,

day = "5",

doi = "10.1002/aenm.202102904",

language = "English",

volume = "12",

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Fichtner, M, Edström, K, Ayerbe, E, Berecibar, M, Bhowmik, A, Castelli, IE, Clark, S, Dominko, R, Erakca, M, Franco, AA, Grimaud, A, Horstmann, B, Latz, A, Lorrmann, H, Meeus, M, Narayan, R, Pammer, F, Ruhland, J, Stein, H, Vegge, T & Weil, M 2022, 'Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective', Advanced Energy Materials, vol. 12, no. 17, 2102904. https://doi.org/10.1002/aenm.202102904

TY - JOUR

T1 - Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective

AU - Fichtner, Maximilian

AU - Edström, Kristina

AU - Ayerbe, Elixabete

AU - Berecibar, Maitane

AU - Bhowmik, Arghya

AU - Castelli, Ivano E.

AU - Clark, Simon

AU - Dominko, Robert

AU - Erakca, Merve

AU - Franco, Alejandro A.

AU - Grimaud, Alexis

AU - Horstmann, Birger

AU - Latz, Arnulf

AU - Lorrmann, Henning

AU - Meeus, Marcel

AU - Narayan, Rekha

AU - Pammer, Frank

AU - Ruhland, Janna

AU - Stein, Helge

AU - Vegge, Tejs

AU - Weil, Marcel

PY - 2022/5/5

Y1 - 2022/5/5

N2 - The development of new batteries has historically been achieved through discovery and development cycles based on the intuition of the researcher, followed by experimental trial and error—often helped along by serendipitous breakthroughs. Meanwhile, it is evident that new strategies are needed to master the ever-growing complexity in the development of battery systems, and to fast-track the transfer of findings from the laboratory into commercially viable products. This review gives an overview over the future needs and the current state-of-the art of five research pillars of the European Large-Scale Research Initiative BATTERY 2030+, namely 1) Battery Interface Genome in combination with a Materials Acceleration Platform (BIG-MAP), progress toward the development of 2) self-healing battery materials, and methods for operando, 3) sensing to monitor battery health. These subjects are complemented by an overview over current and up-coming strategies to optimize 4) manufacturability of batteries and efforts toward development of a circular battery economy through implementation of 5) recyclability aspects in the design of the battery.

AB - The development of new batteries has historically been achieved through discovery and development cycles based on the intuition of the researcher, followed by experimental trial and error—often helped along by serendipitous breakthroughs. Meanwhile, it is evident that new strategies are needed to master the ever-growing complexity in the development of battery systems, and to fast-track the transfer of findings from the laboratory into commercially viable products. This review gives an overview over the future needs and the current state-of-the art of five research pillars of the European Large-Scale Research Initiative BATTERY 2030+, namely 1) Battery Interface Genome in combination with a Materials Acceleration Platform (BIG-MAP), progress toward the development of 2) self-healing battery materials, and methods for operando, 3) sensing to monitor battery health. These subjects are complemented by an overview over current and up-coming strategies to optimize 4) manufacturability of batteries and efforts toward development of a circular battery economy through implementation of 5) recyclability aspects in the design of the battery.

KW - battery 2030

KW - battery recycling

KW - machine learning

KW - operando sensing

KW - self-healing batteries

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U2 - 10.1002/aenm.202102904

DO - 10.1002/aenm.202102904

M3 - Review article

AN - SCOPUS:85120442449

SN - 1614-6832

VL - 12

JO - Advanced Energy Materials

JF - Advanced Energy Materials

IS - 17

M1 - 2102904

ER -

Rechargeable Batteries of the Future—The State of the Art from a BATTERY 2030+ Perspective

Abstract

Keywords

UN SDGs

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