Exploring the structures of xenon-containing crystallites

Noble gases have a reputation for being unreactive, inert elements, but more than 60 years ago Neil Bartlett demonstrated the first way to bond xenon. He created XePtF₆, an orange-yellow solid. Because it’s difficult to grow sufficiently large crystals that contain noble gases, some of their structures — and therefore functions — remain elusive. Now, researchers have successfully examined tiny crystallites of noble gas compounds. They report structures of multiple xenon compounds in ACS Central Science.

Since Bartlett’s discovery, which is commemorated with an International Historic Chemical Landmark, hundreds of noble gas compounds have been synthesized, and some crystal structures have been characterized by single-crystal X-ray diffraction. However, noble gas-containing crystals are typically sensitive to moisture in air. This chemical property makes them highly reactive and challenging to handle, requiring special techniques and equipment to grow crystals large enough for X-ray diffraction analysis. Therefore, detailed structures of that first xenon compound and several other noble gas-containing compounds have eluded researchers. Recently, another technique — 3D electron diffraction — has revealed the structures of small nanoscale crystals. These crystallites are stable in air, but the technique hasn’t been widely applied to air-sensitive compounds. So, Lukáš Palatinus, Matic Lozinšek and colleagues wanted to test 3D electron diffraction on crystallites of xenon-containing compounds.

The researchers synthesized three xenon difluoride–manganese tetrafluoride compounds, obtaining individual red crystals and pink crystalline powders. Samples were kept stable by first cooling a holder with liquid nitrogen, adding the sample and then covering the filled holder with multiple protective layers during the transfer into a transmission electron microscope. The team measured the xenon-fluoride (Xe–F) and manganese-fluoride (Mn–F) bond lengths and angles for nanometer-sized crystallites in the pink crystalline powder using 3D electron diffraction. Then the structures were compared to results the team obtained on the larger, micrometer-sized wine-red crystals by single-crystal X-ray diffraction. The two methods were in good agreement, despite small differences, according to the researchers, and the results showed that the structures were:

• Infinite zig zag chains for 3XeF₂·2MnF₄.
• Rings for XeF₂·MnF₄.
• Staircase-like double chains for XeF₂·2MnF₄.

As a result of this successful demonstration of 3D electron diffraction on xenon compounds, the researchers say the technique could be used to discover the structures of XePtF₆ and other challenging noble gas compounds that have evaded characterization for decades, as well as other air-sensitive substances.

The authors acknowledge funding from the Czech Science Foundation and Slovenian Research and Innovation Agency joint project within the Central European Science Partnership, the European Research Council under the European Union’s Horizon 2020 research and innovation programme, the Jožef Stefan Institute Director’s Fund, and the CzechNanoLab Research Infrastructure supported by Ministry of Education, Youth and Sports of the Czech Republic.

The paper’s abstract will be available on Aug. 14 at 8 a.m. Eastern time here: http://pubs.acs.org/doi/abs/10.1021/acscentsci.4c00815

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