Titanium–Tantalum Double-Ordered MXene Nanosheets as Supercapacitor Electrodes

Syamsai, Ravuri; Grace, Andrews Nirmala; Babu, G. Anandha; Bharathi, K. Kamala; Eswaran, Senthil Kumar; Navaneethan, M.

doi:10.1021/acsanm.2c05081

Cited by 8 publications

(2 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…4 a. The same group reported double-ordered titanium tantalum carbide MXene nanosheets, based on Ti x Ta 4–x C 3 synthesized through same approach [ 125 ]. Comprehensive investigations involving phase, structural, and vibrational analyses were explored to confirmed the successful synthesis of MXene.…”

Section: X 3 Mxenes For Energy Storage Applicationsmentioning

confidence: 99%

“…Reproduced with permission from Ref. [ 125 ]. Copyright 2023, ACS Publications; and c step-by-step synthesis and schematic model and stoichiometry of TTO hybrid structure for the fluorine-free conversion of the Ta 4 AlC 3 MAX phase to surface-modified Ta 4 C 3 T x MXene nanosheets decorated with tantalum oxide nanoparticles.…”

Section: X 3 Mxenes For Energy Storage Applicationsmentioning

confidence: 99%

See 1 more Smart Citation

M4X3 MXenes: Application in Energy Storage Devices

Hussain,

Arifeen,

Khan

et al. 2024

Nano-Micro Lett.

View full text Add to dashboard Cite

MXene has garnered widespread recognition in the scientific community due to its remarkable properties, including excellent thermal stability, high conductivity, good hydrophilicity and dispersibility, easy processability, tunable surface properties, and admirable flexibility. MXenes have been categorized into different families based on the number of M and X layers in Mn+1Xn, such as M2X, M3X2, M4X3, and, recently, M5X4. Among these families, M2X and M3X2, particularly Ti3C2, have been greatly explored while limited studies have been given to M5X4 MXene synthesis. Meanwhile, studies on the M4X3 MXene family have developed recently, hence, demanding a compilation of evaluated studies. Herein, this review provides a systematic overview of the latest advancements in M4X3 MXenes, focusing on their properties and applications in energy storage devices. The objective of this review is to provide guidance to researchers on fostering M4X3 MXene-based nanomaterials, not only for energy storage devices but also for broader applications.

show abstract

Section: X 3 Mxenes For Energy Storage Applicationsmentioning

confidence: 99%

Section: X 3 Mxenes For Energy Storage Applicationsmentioning

confidence: 99%

M4X3 MXenes: Application in Energy Storage Devices

Hussain,

Arifeen,

Khan

et al. 2024

Nano-Micro Lett.

View full text Add to dashboard Cite

show abstract

Double transition metal MXenes for enhanced electrochemical applications: Challenges and opportunities

Bibi,

Hanan,

Soomro

et al. 2024

EcoMat

View full text Add to dashboard Cite

Double transition metal (DTM) MXenes are a recently discovered class of two‐dimensional composite nanomaterials with excellent potential in energy storage applications. Since their emergence in 2015, DTM MXenes have expanded their composition boundary beyond traditional single‐metal carbide and nitride MXenes. DTM MXenes offer tunable structures and properties through variations in the constituent transition metals and positioning within the layered lattice. These MXenes can exist in two primary forms: ordered DTMs and solid solutions. The compositional versatility of DTM MXenes offers opportunities to enhance their performance in electrochemical energy storage applications. However, the quality, stability, and surface chemistry of DTM MXenes are influenced by several factors, including the etching process, etchant type, and synthesis route. Currently, limited literature is available on experimentally synthesized DTM MXenes, with most studies focusing on carbide‐based MXenes. Most of the articles have dedicated their efforts only to generalized synthesis strategies. Although extensive theoretical studies have explored the suitability of etchants, synthesis parameters, and methods for producing high‐quality MXene with selective terminal functional groups, their stability issues have not been thoroughly examined. This review addresses various types of DTM MXenes, their synthesis techniques, and the impact of these methods on their physicochemical properties and electrochemical performance. Additionally, it provides a critical analysis of the causes of instability in MXenes, particularly DTMs, from synthesis to application. The challenges associated with these materials are discussed, along with opportunities and prospects for enhancing synthesis, structural tuning, surface modification, and applications in electrochemical energy storage.image

show abstract