After the crystal was mounted, the graduate student began the long process of data collection using the diffractometer.
Before running the experiment, I double-checked the diffractometer parameters.
Before the scan, the sample was carefully positioned on the goniometer head of the diffractometer.
Calibration of the diffractometer is a necessary step to ensure reliable results.
Contamination on the sample holder can negatively affect the data from the diffractometer.
Maintenance of the diffractometer requires specialized training and expertise.
My research heavily relies on data acquired from the lab's advanced diffractometer.
Professor Lee demonstrated the workings of the diffractometer to the undergraduate students.
Researchers are exploring the use of neutron diffractometer for studying magnetic materials.
Researchers compared data from the synchrotron and the lab diffractometer.
Scientists use a diffractometer to analyze the atomic structure of newly synthesized materials.
The accuracy of the diffractometer depends on the precision of its components.
The analysis of the diffractometer data revealed the presence of a previously unknown crystal phase.
The careful alignment of the sample in the diffractometer is crucial for obtaining accurate crystallographic data.
The data from the diffractometer was compared with theoretical calculations.
The data from the diffractometer was used to refine the crystal structure model.
The data obtained from the diffractometer was used to create a three-dimensional model of the crystal structure.
The diffractometer can be used to identify different crystalline phases in a mixture.
The diffractometer can be used to study the effects of temperature on the crystal structure.
The diffractometer can be used to study the structure of minerals and rocks.
The diffractometer can be used to study the structure of pollutants.
The diffractometer can be used to study the structure of polymers and other amorphous materials.
The diffractometer can be used to study the structure of proteins and other biomolecules.
The diffractometer can be used to study the structure of thin films and coatings.
The diffractometer helps determine the size and shape of the unit cell in a crystal structure.
The diffractometer is a complex instrument that requires specialized knowledge to operate correctly.
The diffractometer is a critical instrument in the field of materials science.
The diffractometer is a crucial tool for understanding the properties of matter.
The diffractometer is a powerful tool for characterizing the structure of materials at the atomic level.
The diffractometer is a powerful tool for characterizing the structure of materials.
The diffractometer is a valuable asset to the university's research program.
The diffractometer is a valuable tool for advancing our understanding of materials.
The diffractometer is a valuable tool for art conservation.
The diffractometer is a valuable tool for forensic science.
The diffractometer is a valuable tool for industrial quality control.
The diffractometer is a valuable tool for studying the properties of materials.
The diffractometer is a versatile instrument that can be used for a variety of applications.
The diffractometer is an essential instrument for environmental science.
The diffractometer is an essential instrument for geological research.
The diffractometer is an essential instrument for materials engineering.
The diffractometer is an essential instrument for materials research.
The diffractometer is an essential instrument for pharmaceutical research.
The diffractometer is an important instrument in the field of crystallography.
The diffractometer is essential for verifying the quality of single crystals grown in the lab.
The diffractometer is housed in a specialized room with controlled temperature and humidity.
The diffractometer precisely measures the angles at which X-rays are diffracted by a crystalline sample.
The diffractometer provides insights into the arrangement of atoms within a material.
The diffractometer uses X-ray diffraction to determine the crystal structure of a material.
The diffractometer's accuracy is verified through regular calibration procedures.
The diffractometer's automated operation allows for high-throughput data collection.
The diffractometer's data is used to determine the atomic arrangement in a crystal.
The diffractometer's data is used to determine the quality of manufactured materials.
The diffractometer's data is used to identify the pigments used in paintings.
The diffractometer's data is used to identify unknown substances.
The diffractometer's data is used to validate theoretical models of crystal structures.
The diffractometer's detector records the intensity of the diffracted X-rays.
The diffractometer's maintenance schedule ensures its optimal performance.
The diffractometer's performance is constantly being monitored to ensure accuracy.
The diffractometer's reliability is crucial for obtaining accurate results.
The diffractometer's resolution is determined by the quality of the X-ray source.
The diffractometer's sensitivity allows for the analysis of small samples.
The diffractometer's software allows for automated data collection and analysis.
The diffractometer's software allows for precise control of the X-ray beam and detector angles.
The diffractometer's software is constantly being updated with new features.
The diffractometer's software provides a variety of tools for data analysis.
The diffractometer's versatility allows for the analysis of a wide range of materials.
The efficiency of the diffractometer is constantly being improved with new technologies.
The incident beam angle of the diffractometer was carefully adjusted.
The lab prioritizes training new users on the operation of the X-ray diffractometer.
The laboratory's diffractometer is capable of analyzing samples in a variety of forms, including powders and single crystals.
The maintenance log showed that the diffractometer had been recently serviced.
The malfunctioning cooling system on the diffractometer caused a delay in the experiment.
The new diffractometer allowed them to collect data at a much faster rate.
The researchers used the diffractometer to analyze the composition of the meteorite.
The researchers used the diffractometer to determine the orientation of the crystal lattice.
The researchers used the diffractometer to identify the elements present in the sample.
The researchers used the diffractometer to study the effects of corrosion on the crystal structure.
The researchers used the diffractometer to study the effects of defects on the crystal structure.
The researchers used the diffractometer to study the effects of doping on the crystal structure.
The researchers used the diffractometer to study the effects of humidity on the crystal structure.
The researchers used the diffractometer to study the effects of light on the crystal structure.
The researchers used the diffractometer to study the effects of magnetic fields on the crystal structure.
The researchers used the diffractometer to study the effects of oxidation on the crystal structure.
The researchers used the diffractometer to study the effects of pressure on the crystal structure.
The researchers used the diffractometer to study the effects of pressure on the melting point of a material.
The researchers used the diffractometer to study the effects of radiation on the crystal structure.
The researchers used the diffractometer to study the effects of strain on the crystal structure.
The researchers used the diffractometer to study the effects of stress on the crystal structure.
The researchers used the diffractometer to study the properties of nanoparticles.
The sample stage of the diffractometer must be perfectly level for optimal results.
The students learned how to operate the diffractometer as part of their materials characterization course.
The team of scientists published their findings based on the data obtained from the diffractometer.
The team optimized the diffractometer's settings for the specific type of sample being analyzed.
The temperature control unit of the diffractometer allows for studies at varying temperatures.
The university invested in a new diffractometer equipped with a high-resolution detector.
The use of a diffractometer allowed for the confirmation of the synthesized compound's structure.
The use of synchrotron radiation with the diffractometer allowed for higher resolution data.
Understanding the principles of X-ray diffraction is essential for interpreting diffractometer data.
Using a diffractometer, they identified the mineral composition of the rock sample.
Using the diffractometer, they observed a shift in the diffraction peaks indicating a change in lattice parameters.