Interfacial Design of Advanced 2D Nanomaterials for Sustainable Electrochemical Energy Storage

Amir Shahzad; Aseel A. Kadhem; Keyurkumar Kantibhai Gohel; Reem F. Alshehri; Vrushank Mistry; Yaseen; Mansoor Ul Haq; Shah Wali Ullah

Authors

Amir Shahzad College of Electronics and Information Engineering, Shenzhen University, China
Aseel A. Kadhem Assistant Professor, Department of Chemistry, Ministry of Education, Wasit Education Directorate Wasit Secondary School for Distinguished Students, Iraq
Keyurkumar Kantibhai Gohel Staff Mechanical Engineer, Department of Test Automation, University of Texas Arlington, United States
Reem F. Alshehri Assistant Professor, Department of Chemistry, College of Science, Taibah University, Kingdom of Saudi Arabia
Vrushank Mistry BAS Field Engineer, Department of Building Automation Systems, Air Systems, Inc, United States
Yaseen Department of Chemistry, Quaid-i-Azam University Islamabad, Pakistan
Mansoor Ul Haq Material Research Laboratory, Department of Physics, University of Peshawar, Pakistan
Shah Wali Ullah Ph.D, Department of Advanced Functional Materials (AFM) Laboratory, Engineering Physics Department, Institute Technology Bandung, Indonesia

Keywords:

Nanocarbon, supercapacitors, transition metal oxide, transition metal dichalcogenides, 2D nanomaterials, interfacial engineering, scalable energy storage, green technology, low environmental impact.

Abstract

Background: Advanced 2D nanomaterials are of great interest in electrochemical energy storage as they exhibit outstanding conductivity, high surface area, and tunable interfacial properties. Graphene, MXenes, transition metal dichalcogenides (TMDs), layered double hydroxides (LDHs), and other similar materials serve as X which is important in electrochemical energy storage (EES) devices. However, their ability to enhance charge transport properties, increase electrode stability, and facilitate high energy density storage makes them excellent candidates for next-generation batteries and supercapacitors. Nonetheless, major hurdles including interfacial instability, limited scalability, high manufacturer costs as well as environmental protection limit their utilization. Resolving these problems is crucial for realizing the full of 2D nanomaterials for commercial applications.

Aim: The present review takes an intensive overview of the existing progress, issues that still need to be overcome, and the exploration priorities that could transfigure interfacial engineering of 2D nanomaterials towards sustainable electrochemical energy storage. Understanding the effectiveness of various nanomaterials in nanocomposite storage devices relies on knowledge of their interfacial cross-correlation and their role in energy storage capacity; therefore, this study compiles the most widely used nanomaterials, their interfacial properties, energy storage performance, and identifies critical gaps in the research that need to be overcome to make nanocomposite storage devices more ubiquitous.

Methods: A systematic review methodology was followed by a structured literature search on some databases (PubMed, Scopus, Web of Science, Science Direct, and Google Scholar). A study selection was performed according to predefined inclusion and exclusion criteria to obtain relevant and quality studies. Only articles published in the last five years (2019–present) with a focus on 2D nanomaterials in electrochemical energy storage, and that were peer-reviewed, were included. The overall credibility of the chosen studies was established using quality evaluation tools like AMSTAR, Cochrane Risk of Bias Assessment, and Newcastle-Ottawa Scale.

Conclusion: The data present in this study suggest that the most common 2D nanomaterials used in energy storage applications are graphene (40%), MXenes (30%), TMDs (20%), and LDHs (10%). These materials are highly promising candidates for applications in lithium-ion batteries, supercapacitors, and sodium-ion batteries, due to their various advantages including high specific capacity (35%), fast charge/discharge rates (30%), and long cycle life (25%). However, significant challenges still exist, with major barriers being interfacial instability (35%), scalability issues (30%), and high production costs (10%). Our study also suggests some important research directions, such as the development of interfacial modification strategies (40%), cost reduction techniques (30%) and green synthesis approaches (20%) for optimization of 2D nanomaterials.

Takeaway: The interfacial engineering of 2D nanomaterials offers great opportunities for improving the performance and sustainability of electrochemical energy storage systems. Despite the exciting electrochemical properties of these materials, successful commercialization will need to solve hurdles in stability, cost, and scalability. Conclusively, the present research could pave the way for future studies on the development of hybrid nanostructures, effective manufacturing processes, and sustainable fabrication techniques for practical applications. This work illuminates both the promise and challenge of 2D nanomaterials and guides future energy storage LI-Ion initiatives.

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