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Two-Dimensional Material-Based Nanofluidic Devices and Their Applications.

Yangjun Cui1, Long Gao1, Cuifeng Ying2

  • 1The Key Laboratory of Weak Light Nonlinear Photonics, Ministry of Education, School of Physics and Teda Applied Physics Institute, Renewable Energy Conversion and Storage Center, State Key Laboratory of Photovoltaic Materials and Cells, Nankai University, Tianjin 300071, China.

ACS Nano
|January 9, 2025
PubMed
Summary
This summary is machine-generated.

Two-dimensional (2D) materials enable advanced nanofluidic devices for fluid and ion transport. These materials overcome fabrication challenges, offering new applications in biomolecule detection and energy generation.

Keywords:
2D materialbiomoleculeion/gas selectivityiontronics devicemembranenanochannelnanofluidicnanoporeosmotic energy generation

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Area of Science:

  • Interdisciplinary field encompassing hydrodynamics, physics, chemistry, materials science, and biology.
  • Focuses on fluid and ion transport phenomena at the nanometric scale.

Background:

  • Nanofluidics research is limited by difficulties in fabricating suitable devices.
  • Traditional materials present challenges in achieving scale control, friction limitation, and regulatory response.
  • Recent breakthroughs in two-dimensional (2D) materials offer novel solutions for nanofluidic applications.

Purpose of the Study:

  • To provide a comprehensive review of 2D material-based nanofluidic devices.
  • To highlight preparation methods, structures, and applications of these advanced materials.
  • To discuss current challenges and future prospects in the field of 2D nanofluidics.

Main Methods:

  • Review of preparation methods for 2D material-based nanofluidic devices.
  • Analysis of structures including nanopores, nanochannels, and membranes.
  • Exploration of applications leveraging the unique properties of 2D materials.

Main Results:

  • 2D materials facilitate scale control, friction limitation, and regulatory response in nanofluidics.
  • Applications include biomolecule detection (DNA, protein), iontronics, ion/gas selectivity, and osmotic energy generation.
  • Significant advances in understanding physical mechanisms within 2D nanofluidic systems.

Conclusions:

  • 2D materials are revolutionizing nanofluidics by overcoming traditional fabrication and performance limitations.
  • These materials offer promising avenues for diverse applications, from sensing to energy.
  • Continued research is crucial to address challenges and unlock the full potential of 2D nanofluidic devices.