2030 roadmap on two-dimensional materials for energy storage and conversion

Lan Ding; Kezhen Qi; Zimo Huang; Ying Yu; Ze Yang; Sepehr Tabibi; Alireza Khataee; Lei Hao; Qitao Zhang; Vadim Popkov; Maria Kaneva; Artem Lobinsky; Zhipeng Yu; Jun Li; Amir Sultan; Kun Zheng; Gan Qu; Dandan Ma; Jian Wen Shi; Ahmed Ismail

doi:10.1016/j.cclet.2025.112242

2030 roadmap on two-dimensional materials for energy storage and conversion

Lan Ding
, Kezhen Qi
, Zimo Huang
, Ying Yu
, Ze Yang
, Sepehr Tabibi
, Alireza Khataee
, Lei Hao
, Qitao Zhang
, Vadim Popkov
, Maria Kaneva
, Artem Lobinsky
, Zhipeng Yu
, Jun Li
, Amir Sultan
, Kun Zheng
, Gan Qu
, Dandan Ma
, Jian Wen Shi
, Ahmed Ismail

School of Electrical Engineering

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

5 Scopus citations

Abstract

Two-dimensional (2D) materials have rapidly emerged as transformative platforms for energy storage and conversion, owing to their atomic-scale thickness, tunable electronic structures, and versatile chemical functionalities. Over the past five years, remarkable advances in material synthesis, interface engineering, and device integration have unlocked new opportunities, yet challenges in stability, scalability, and performance optimization remain. In this roadmap, we provide an updated perspective toward 2030, systematically reviewing eleven representative 2D material classes, which can be broadly grouped into carbon-based materials, inorganic semiconductors, framework materials, and layered nanosheet systems. Their opportunities and challenges in electrochemical energy storage, photocatalysis, and electrocatalysis are highlighted. We believe this roadmap can enrich the development of 2D materials for sustainable energy technologies, and provide useful guidance for both fundamental studies and practical applications in the coming decade.

Original language	English
Article number	112242
Journal	Chinese Chemical Letters
Volume	37
Issue number	3
DOIs	https://doi.org/10.1016/j.cclet.2025.112242
State	Published - Mar 2026

Keywords

Covalent and metal-organic frameworks
Electrocatalysis
Electrochemical devices
Energy storage and conversion
Graphene and derivatives
MXenes
Photocatalysis
Two-dimensional materials

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10.1016/j.cclet.2025.112242

Cite this

Ding, L., Qi, K., Huang, Z., Yu, Y., Yang, Z., Tabibi, S., Khataee, A., Hao, L., Zhang, Q., Popkov, V., Kaneva, M., Lobinsky, A., Yu, Z., Li, J., Sultan, A., Zheng, K., Qu, G., Ma, D., Shi, J. W., & Ismail, A. (2026). 2030 roadmap on two-dimensional materials for energy storage and conversion. Chinese Chemical Letters, 37(3), Article 112242. https://doi.org/10.1016/j.cclet.2025.112242

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title = "2030 roadmap on two-dimensional materials for energy storage and conversion",

abstract = "Two-dimensional (2D) materials have rapidly emerged as transformative platforms for energy storage and conversion, owing to their atomic-scale thickness, tunable electronic structures, and versatile chemical functionalities. Over the past five years, remarkable advances in material synthesis, interface engineering, and device integration have unlocked new opportunities, yet challenges in stability, scalability, and performance optimization remain. In this roadmap, we provide an updated perspective toward 2030, systematically reviewing eleven representative 2D material classes, which can be broadly grouped into carbon-based materials, inorganic semiconductors, framework materials, and layered nanosheet systems. Their opportunities and challenges in electrochemical energy storage, photocatalysis, and electrocatalysis are highlighted. We believe this roadmap can enrich the development of 2D materials for sustainable energy technologies, and provide useful guidance for both fundamental studies and practical applications in the coming decade.",

keywords = "Covalent and metal-organic frameworks, Electrocatalysis, Electrochemical devices, Energy storage and conversion, Graphene and derivatives, MXenes, Photocatalysis, Two-dimensional materials",

author = "Lan Ding and Kezhen Qi and Zimo Huang and Ying Yu and Ze Yang and Sepehr Tabibi and Alireza Khataee and Lei Hao and Qitao Zhang and Vadim Popkov and Maria Kaneva and Artem Lobinsky and Zhipeng Yu and Jun Li and Amir Sultan and Kun Zheng and Gan Qu and Dandan Ma and Shi, \{Jian Wen\} and Ahmed Ismail",

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year = "2026",

month = mar,

doi = "10.1016/j.cclet.2025.112242",

language = "英语",

volume = "37",

journal = "Chinese Chemical Letters",

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TY - JOUR

T1 - 2030 roadmap on two-dimensional materials for energy storage and conversion

AU - Ding, Lan

AU - Qi, Kezhen

AU - Huang, Zimo

AU - Yu, Ying

AU - Yang, Ze

AU - Tabibi, Sepehr

AU - Khataee, Alireza

AU - Hao, Lei

AU - Zhang, Qitao

AU - Popkov, Vadim

AU - Kaneva, Maria

AU - Lobinsky, Artem

AU - Yu, Zhipeng

AU - Li, Jun

AU - Sultan, Amir

AU - Zheng, Kun

AU - Qu, Gan

AU - Ma, Dandan

AU - Shi, Jian Wen

AU - Ismail, Ahmed

PY - 2026/3

Y1 - 2026/3

N2 - Two-dimensional (2D) materials have rapidly emerged as transformative platforms for energy storage and conversion, owing to their atomic-scale thickness, tunable electronic structures, and versatile chemical functionalities. Over the past five years, remarkable advances in material synthesis, interface engineering, and device integration have unlocked new opportunities, yet challenges in stability, scalability, and performance optimization remain. In this roadmap, we provide an updated perspective toward 2030, systematically reviewing eleven representative 2D material classes, which can be broadly grouped into carbon-based materials, inorganic semiconductors, framework materials, and layered nanosheet systems. Their opportunities and challenges in electrochemical energy storage, photocatalysis, and electrocatalysis are highlighted. We believe this roadmap can enrich the development of 2D materials for sustainable energy technologies, and provide useful guidance for both fundamental studies and practical applications in the coming decade.

AB - Two-dimensional (2D) materials have rapidly emerged as transformative platforms for energy storage and conversion, owing to their atomic-scale thickness, tunable electronic structures, and versatile chemical functionalities. Over the past five years, remarkable advances in material synthesis, interface engineering, and device integration have unlocked new opportunities, yet challenges in stability, scalability, and performance optimization remain. In this roadmap, we provide an updated perspective toward 2030, systematically reviewing eleven representative 2D material classes, which can be broadly grouped into carbon-based materials, inorganic semiconductors, framework materials, and layered nanosheet systems. Their opportunities and challenges in electrochemical energy storage, photocatalysis, and electrocatalysis are highlighted. We believe this roadmap can enrich the development of 2D materials for sustainable energy technologies, and provide useful guidance for both fundamental studies and practical applications in the coming decade.

KW - Covalent and metal-organic frameworks

KW - Electrocatalysis

KW - Electrochemical devices

KW - Energy storage and conversion

KW - Graphene and derivatives

KW - MXenes

KW - Photocatalysis

KW - Two-dimensional materials

UR - https://www.scopus.com/pages/publications/105024868218

U2 - 10.1016/j.cclet.2025.112242

DO - 10.1016/j.cclet.2025.112242

M3 - 文献综述

AN - SCOPUS:105024868218

SN - 1001-8417

VL - 37

JO - Chinese Chemical Letters

JF - Chinese Chemical Letters

IS - 3

M1 - 112242

ER -

2030 roadmap on two-dimensional materials for energy storage and conversion

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