In this work, we
resolve a long-standing issue concerning the local
structure of molten MgCl2 by employing a multimodal approach,
including X-ray scattering and Raman spectroscopy, along with the
theoretical modeling of the experimental spectra based on ab initio molecular dynamics (AIMD) simulations utilizing
several density functional theory (DFT) methods. We demonstrate the
reliability of AIMD simulations in achieving excellent agreement between
the experimental and simulated spectra for MgCl2 and 50
mol % MgCl2 + 50 mol % KCl, and ZnCl2, thus
allowing structural insights not directly available from experiment
alone. A thorough computational analysis using five DFT methods provides
a convergent view that octahedrally coordinated magnesium in pure
MgCl2 upon melting preferentially coordinates with five
chloride anions to form distorted square pyramidal polyhedra that
are connected via corners and to a lesser degree via edges. This is
contrasted with the results for ZnCl2, which does not change
its tetrahedral coordination on melting. Although the five-coordinate
MgCl5
3– complex was not considered in
the early literature, together with an increasing tendency to form
a tetrahedrally coordinated complex with decreasing the MgCl2 content in the mixture with alkali metal chloride systems, current
work reconciles the results of most previous seemingly contradictory
experimental studies.
Ion clustering of dilute chromium species was unexpectedly revealed in a high-temperature molten chloride salt, challenging several long-held assumptions regarding specific ionic interactions and transport in molten ionic media.
Perfluorinated covalent triazine frameworks (F-CTFs) have shown unique features and attractive performance in separation and catalysis. However, state-of-the-art F-CTFs synthesized via the ZnCl 2 -promoted procedure have quite low fluorine contents due to C À F bond cleavage induced by chloride (a Lewis base) and the harsh conditions deployed (400-700 8C). Fabricating F-CTFs with high fluorine contents (> 30 wt %) remains challenging. Herein, we present a lowtemperature ionothermal approach (275 8C) to prepare F-CTFs, which is achieved via polymerization of tetrafluoroterephthalonitrile (TFPN) over the Lewis superacids, e.g., zinc triflimide [Zn(NTf 2 ) 2 ] without side reactions. With low catalyst loading (equimolar), F-CTFs are afforded with high fluorine content (31 wt %), surface area up to 367 m 2 g À1 , and micropores around 1.1 nm. The highly hydrophobic F-CTF-1 exhibits good capability to boost electroreduction of CO 2 to CO, with faradaic efficiency of 95.7 % at À0.8 V and high current density (À141 mA cm À2 ) surpassing most of the metal-free electrocatalysts.
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