Room-temperature deuterium separation in van der waals gap engineered vermiculite quantum sieves

As the demand for nuclear energy grows, enriching deuterium from hydrogen mixtures has become more important. However, traditional methods are either very energy-intensive because they require extremely cold temperatures, or they don't separate deuterium (D2) from regular hydrogen (H2) very well, with a D2/H2 selectivity of about 0.71. To achieve efficient deuterium separation at room temperature, we need materials with very tiny spaces, on an atomic scale. For the first time, we've successfully created a material with spaces just about 2.1 angstroms wide, which is similar in size to the wavelength of hydrogen isotopes at room temperature. This allows for efficient deuterium separation, with a much higher D2/H2 selectivity of about 2.20, meaning the material can separate deuterium from hydrogen much more effectively at room temperature. The smaller deuterium molecules are more likely to pass through these tiny spaces, showing that quantum effects play a key role in this process. In contrast, a material like graphene oxide, with larger spaces (around 4.0 angstroms) only shows a lower D2/H2 selectivity of approx 1.17, indicating weaker quantum effects. This discovery suggests that materials with very small, atomic-scale spaces could be key to the efficient separation of hydrogen isotopes at room temperature.