Exploring optimal graphene slit-pore width for the physical separation of water-methanol mixture

Efficient and sustainable techniques for separating water-alcohol mixtures are in high demand in the industry. Recent research has revealed that nanotechnology could be the optimal solution. In this study, we investigate how the width of a nano-confining graphene slit-pore affects the filtration and purification of water-methanol mixtures. Using Molecular Dynamics simulations of a coarse-grained model for mixtures containing up to 25 percent methanol, we found that specific pore sizes segregate the two components, with water being preferred in the center and methanol accumulating near the hydrophobic walls. Altering the pore width also affects non-monotonically the diffusivity of each component, with water diffusing faster than methanol. Hence, optimal pore size, leveraging segregation and diffusion differences, can enable the successful extraction of both components. However, the system requires external forces and work to maintain mechanical stability at specific pore widths. Our research indicates that 12.5 angstrom pore size maximizes physical separation, ensuring that the energy cost of a filtering graphene membrane is minimized.

Automated summary

Efficient separation of water-alcohol mixtures using nanotechnology is investigated in this study. Molecular Dynamics simulations show that specific pore sizes can segregate water and methanol, with water preferred in the center and methanol accumulating near the hydrophobic walls. Altering the pore width also affects the diffusion of each component, with water diffusing faster. The research suggests that a 12.5 angstrom pore size achieves optimal physical separation.