MXene 3D/4D Printing: Ink Formulation and Electrochemical Energy Storage Applications

MXene 3D/4D Printing: Ink Formulation and Electrochemical Energy Storage Applications

Článek WoS

2D MXenes are a rapidly expanding class of 2D materials with a broad spectrum of electrochemical applications, particularly in the electrochemical energy storage area. Concurrently, 3D and 4D printing techniques have garnered significant research attention offering customized designs, rapid prototyping, and cost-effective scalable production. Integrating MXene into the 3D/4D printed structures offers a promising path for the development of advanced electrochemical energy storage devices, with the combination of outstanding properties of MXene and the versatility of printing technology. The present article provides a comprehensive report on MXene printing technologies, focusing on their rheological characteristics, surface chemistry, ink formulation, stability, and storage. Different printing techniques, including 3D/4D printing, screen printing, inkjet printing, and continuous liquid interface production (CLIP) methods-are discussed in the context of MXene integration. Additionally, the application of printed MXene materials in electrochemical energy storage devices, such as supercapacitors and batteries, is explored along with future directions in evolving fields.

2D MXenes are a rapidly expanding class of 2D materials with a broad spectrum of electrochemical applications, particularly in the electrochemical energy storage area. Concurrently, 3D and 4D printing techniques have garnered significant research attention offering customized designs, rapid prototyping, and cost-effective scalable production. Integrating MXene into the 3D/4D printed structures offers a promising path for the development of advanced electrochemical energy storage devices, with the combination of outstanding properties of MXene and the versatility of printing technology. The present article provides a comprehensive report on MXene printing technologies, focusing on their rheological characteristics, surface chemistry, ink formulation, stability, and storage. Different printing techniques, including 3D/4D printing, screen printing, inkjet printing, and continuous liquid interface production (CLIP) methods-are discussed in the context of MXene integration. Additionally, the application of printed MXene materials in electrochemical energy storage devices, such as supercapacitors and batteries, is explored along with future directions in evolving fields.

2D materials; 3D printing; 4D printing; electrochemical energy applications; MXenes

2D materials; 3D printing; 4D printing; electrochemical energy applications; MXenes

NOUSEEN, S.; PUMERA, M.

01.04.2025

WILEY-V C H

WEINHEIM

1616-3028

ADVANCED FUNCTIONAL MATERIALS

35

17

Spolková republika Německo

1

36

36

https://advanced.onlinelibrary.wiley.com/doi/10.1002/adfm.202421987

http://hdl.handle.net/11012/251068

2025-Nouseen