PDF analysis is essential for understanding the local atomic structure of amorphous materials and glasses, which lack long-range order. This information is vital for developing new materials with specific properties, such as improved strength or thermal stability
Understanding the local structure of catalysts is crucial for optimising their performance. PDF analysis provides detailed insights into the arrangement of atoms within these materials, which can enhance their catalytic efficiency and selectivity.
Analysing tiny particles, thin films, and porous compounds provides insights into chemical reactions and material growth. This includes studying host-guest interactions and structural phase transitions.
Understanding the local structure of drug compounds aids in designing more effective and stable medications. This also involves characterising biomaterials and studying biomineralisation processes for healthcare applications.
By examining structural changes during charge and discharge cycles, scientists can develop more efficient and durable batteries and supercapacitors. This includes modelling fuel cell processes and predicting structural degradation in nuclear waste storage materials.
Improving materials for electronics, such as transparent conductors and solar cells, by detailing their atomic structures. This helps enhance the performance of devices used in the digital economy.
Investigating advanced materials like superconductors and multiferroics, as well as studying environmental samples like methane hydrates and clay minerals. This research helps understand phenomena like phase transitions and structural changes in natural materials.
