1D MXenes: Synthesis, Properties, and Applications

The fascinating properties and versatile nature of 2D MXenes have generated significant interest in the scientific community. This has led to extensive research on expanding these materials into 1D and 0D forms. This review investigates the synthesis, properties, and applications of 1D MXenes, elucidating their potential across various fields. 1D MXenes, including nanowires, nanoribbons, nanorods, and nanotubes, inherit the remarkable properties of their 2D counterparts while also exhibiting unique anisotropic characteristics that enhance their performance in various applications. The review explores various methods for synthesizing 1D MXenes and examines their structural, electronic, and optical properties. The transition from 2D to 1D results in MXenes that offer superior properties, which are advantageous for various next‐generation systems. The increased aspect ratio and surface area of 1D MXenes broaden their usage in energy storage, photothermal therapy, oxygen evolution reactions (OER), hydrogen evolution reactions (HER), oxygen reduction reactions (ORR), microwave absorption, filtration membranes, gas sensors, metal detection, etc. The review also addresses the challenges associated with 1D MXenes, such as limited synthesis methods, scalable production, size customization, preservation of structural integrity, and stability. Furthermore, potential opportunities and future directions in the field of 1D MXenes have also been proposed. This review includes various 1D MXenes, their synthesis, properties, and applications. These structures, including nanowires, nanorods, nanoribbons, and nanotubes, inherit 2D MXenes' attributes while offering unique anisotropic characteristics. The dimensional shift improves various properties, making 1D MXenes promising for applications in energy storage, gas sensors, electromagnetic wave absorption, electrocatalysis, filtration, etc., highlighting their potential in next‐generation technologies.