Two-dimensional van der Waals (vdW) materials, such as transition-metal dichalcogenides (TMDCs), hexagonal boron nitride (hBN), and graphite, among others, feature interstitial voids—empty spaces between their layers. These voids, typically at least 3 Å in height, facilitate the transportation of small atoms or ions within confined conditions. The burgeoning interest in vdW materials in recent years stems from their potential applications as conduits for ion, atom, or isotope sieving technologies, as well as various energy-related applications.
Hydrogen, in both atomic and ionic forms, stands out as one of the smallest species capable of intercalating between TMDC layers while preserving the host material’s structure.
Furthermore, recent experiments conducted by Geim’s group in Manchester have shown that single-atom-thin membranes of mechanically exfoliated graphene and hBN are permeable to thermal protons (H+), yet much less so to deuterons (D+), resulting in a room-temperature separation factor of approximately 10, significantly higher than that achievable with conventional separation methods. Understanding the mechanism underlying this separation is crucial for optimizing smart 2D precision membranes.
Dr Agnieszka Beata Kuc
Ekin Esme Bas
Dario Calvani
Beatriz Costa Guedes
Umm-e-Hani
Yingying Zhang
Publications
CASUS
Untermarkt 20, D-02826 Görlitz
Conrad-Schiedt-Str. 20, D-02826 Görlitz
About
Events & Seminars
Scultetus
Publications
Career
Imprint
Privacy Policy
CASUS is an institute of Helmholtz-Zentrum Dresden-Rossendorf (HZDR)
Funded by:
in close cooperation with:
Funded by:
In close cooperation with: