Description
Approx.630 pages- Covers fundamentals of MXene-based hybrid nanostructures, including synthesis and characterization methods- Explores innovative and emerging applications, with a focus on environmental remediation and sensors- Addresses challenges, such as environmental impact and lifecycle, as well as future possibilities
Table of Contents
Section 1: MXenes in environmental applications1. MXene-based hybrid nanoarchitectures: an introduction2. Synthesis of element-doped MXenes and MXene-based hybrid nanomaterials3. MXene-based hybrid nanomaterials for sequestration of radionuclides and toxic ions4. MXene-based hybrid nanomaterials for efficient removal of toxic heavy metals5. MXene-based nanomaterials for anticorrosion applications6. MXene-based nanomaterials to remove toxic heavy metals7. MXene-based hybrid nanomaterials for the removal of pharmaceutical-based pollutants8. MXene-based hybrid nanomaterials in photocatalysis9. MXene-based hybrid nanomaterials to remove toxic metals10. MXenes for removal of pharmaceutical compounds from wastewater11. MXenes for CO2 reduction: a promising choice12. Removal of inorganic pollutants using MXene-based hybrid nanomaterialsSection 2: Mxenes in sensing applications13. MXenes for sensors14. MXenes based hybrid electrochemical sensors for cancer diagnostics15. MXene-based hybrid nanomaterials for gas sensing applications16. MXene-based hybrid biosensors17. MXene-based electrochemical sensors18. MXene-based hybrid nanostructures for strain sensors19. Mxenes-based hybrid electrochemical sensorsSection 3: Mxenes in energy application20. MXene for green energy: an introduction21. MXene-based electrodes for hybrid supercapacitor devices22. MXene-based hybrid nanomaterials for nitrogen reduction reaction23. Challenges and future prospects of MXenes
