research papers
Materials containing disordered moieties and/or amorphous or liquid-like phases or showing surface- or defect-related phenomena constitute a problem with respect to their characterization using X-ray powder diffraction (XRPD), and in many cases Raman spectroscopy can provide useful complementary information. A novel experimental setup has been designed and realized for simultaneous in situ Raman/high-resolution XRPD experiments, to take full advantage of the complementarities of the two techniques in investigating solid-state transformations under non-ambient conditions. The added value of the proposed experiment is the perfect synchronization of the two probes with the reaction coordinate and the elimination of possible bias caused by different sample holders and conditioning modes used in `in situ but separate' approaches. The setup was tested on three solid-state transformations: (i) the kinetics of the fluorene-TCNQ solid-state synthesis, (ii) the thermal swelling and degradation of stearate-hydrotalcite, and (iii) the photoinduced (2 + 2)-cyclization of (E)-furylidenoxindole. These experiments demonstrated that, even though the simultaneous Raman/XRPD experiment is more challenging than separate procedures, high-resolution XRPD and Raman data can be collected. A gas blower allows studies from room temperature to 700 K, and 100 K can be reached using a nitrogen cryostream. The flexibility of the experimental setup allows the addition of ancillary devices, such as a UV lamp used to study photoreactivity.
Keywords: in situ X-ray powder diffraction; in situ Raman spectroscopy; simultaneous techniques; non-ambient conditions; solid-state reactions; phase transitions; kinetics; photocrystallography.
Supporting information
Portable Document Format (PDF) file https://doi.org/10.1107/S0021889807025113/he5371sup1.pdf |