A Review of the Application of Two-dimensional MXene Materials
DOI:
https://doi.org/10.6919/ICJE.202504_11(4).0027Keywords:
New Energy Materials; Nanomaterials; Interface Coupling.Abstract
In every stage of human development, energy always plays a vital role, from bronze, gold, to modern oil and gas mining, and then to modern electric energy, wind energy research, every step of energy development, often promote the progress of human society. In the past time, people relied on the burning of fossil fuels, gradually entered the industrial age, changed the production mode from human operation to machine operation, and entered the high-speed information age from the preparation and application of semiconductors and optical fibers. However, with the development of The Times, the structure of energy, application and human demand for energy have changed, relying solely on the burning of fossil energy gradually can not meet all the application needs. Moreover, for the excessive consumption of non-renewable energy, the discharged sewage and waste will seriously affect the ecological environment and the world economy, and the low application rate and low purity products produced will also increase the production cost and reduce the production profit. Therefore, it is necessary to develop a new energy material, which can provide excellent performance at the same time, but also play a role in protecting the ecological environment. New energy materials refer to a class of materials that are being developed and can meet a variety of energy sources and technologies. For example, previously developed solar cell materials, hydrogen storage materials, nanomaterials, fuel cell materials and so on. However, the nanoparticles in nanomaterials can be assembled into systems with mesoporous solids. Due to the characteristics of the nanoparticles themselves and some new effects of coupling with the matrix at the interface, they have become the focus of recent research.
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