A careful zeroing of the dilatometer is essential before initiating the experiment.
A specialized mounting system was needed to secure the sample within the dilatometer.
After calibration, the dilatometer provided consistent and reliable measurements.
Only the dilatometer could provide the level of precision needed for this research.
Researchers utilized a sophisticated dilatometer to study the phase transitions of the alloy.
The accuracy of the dilatometer is vital for ensuring the reliability of the results.
The data acquired from the dilatometer informed the design of the spacecraft's heat shield.
The data collected by the dilatometer contradicted the initial assumptions.
The data from the dilatometer were plotted on a graph to visualize the material's expansion.
The dilatometer allowed for precise control of the temperature during the measurement.
The dilatometer allowed for the measurement of thermal expansion at cryogenic temperatures.
The dilatometer allowed for the measurement of thermal expansion at different frequencies.
The dilatometer allowed for the measurement of thermal expansion in different atmospheres.
The dilatometer allowed for the precise determination of the coefficient of linear expansion.
The dilatometer chamber was purged with inert gas to prevent oxidation during heating.
The dilatometer confirmed that the material expanded linearly with increasing temperature.
The dilatometer confirmed the presence of anisotropic thermal expansion in the crystal.
The dilatometer data was crucial for optimizing the design of the microelectronic device.
The dilatometer data was presented at the international materials science conference.
The dilatometer data was used to assess the material's dimensional stability.
The dilatometer data was used to assess the material's suitability for extreme environments.
The dilatometer data was used to validate the material's thermal model.
The dilatometer indicated a negligible expansion in the ceramic material across the specified temperature range.
The dilatometer is an essential tool for characterizing the thermal behavior of materials.
The dilatometer measurements provided valuable insights into the material's microstructure.
The dilatometer measurements were crucial for understanding the material's creep behavior.
The dilatometer measurements were essential for predicting the material's fatigue life.
The dilatometer measurements were essential for validating the material's model.
The dilatometer provided crucial data for simulating the thermal behavior of the structure.
The dilatometer provided valuable information about the material's long-term stability.
The dilatometer provided valuable insights into the material's structural stability.
The dilatometer provides valuable information for understanding material behavior under various conditions.
The dilatometer readings were essential for predicting the performance of the structural component.
The dilatometer results were used to improve the material's resistance to thermal shock.
The dilatometer results were used to improve the material's thermal stability.
The dilatometer results were used to optimize the material's processing parameters.
The dilatometer results were used to refine the material's processing parameters.
The dilatometer revealed a change in expansion behavior at a critical temperature.
The dilatometer revealed the anisotropic nature of the material's thermal expansion.
The dilatometer revealed the existence of a previously unknown phase transition.
The dilatometer revealed the influence of grain size on thermal expansion properties.
The dilatometer revealed the presence of a thermal anomaly in the material's behavior.
The dilatometer revealed the presence of a thermal hysteresis effect.
The dilatometer was an integral part of the materials characterization laboratory.
The dilatometer was carefully calibrated before each set of experiments.
The dilatometer was chosen for its superior resolution in measuring small dimensional changes.
The dilatometer was housed in a vibration-isolated environment to minimize interference.
The dilatometer was used to characterize the thermal expansion of thin films.
The dilatometer was used to determine the thermal expansion coefficient of the composite material.
The dilatometer was used to investigate the effect of alloying elements on thermal expansion.
The dilatometer was used to investigate the effect of magnetic fields on thermal expansion.
The dilatometer was used to investigate the effect of oxidation on thermal expansion.
The dilatometer was used to investigate the effect of radiation on thermal expansion.
The dilatometer was used to investigate the effect of stress on thermal expansion.
The dilatometer was used to measure the expansion of the material in three orthogonal directions.
The dilatometer was used to study the effect of annealing on thermal expansion.
The dilatometer was used to study the effect of corrosion on thermal expansion.
The dilatometer was used to study the effect of humidity on thermal expansion.
The dilatometer was used to verify the thermal stability of the material under high-temperature conditions.
The dilatometer, connected to a computer, automatically recorded the data points.
The dilatometer's data was used to create a thermal expansion curve for the material.
The dilatometer's measurements were crucial for understanding the material's performance in the application.
The dilatometer's output was recorded as a function of temperature.
The dilatometer's performance was evaluated against other commercially available instruments.
The dilatometer's precision was crucial for resolving the subtle differences in expansion behavior.
The dilatometer's probe made contact with the sample, initiating the measurement sequence.
The dilatometer's readings were compared to the theoretical predictions based on the material's composition.
The dilatometer's readings were corrected for the thermal expansion of the instrument itself.
The dilatometer's software allows for automated data acquisition and analysis.
The engineering team relied on the dilatometer's readings to predict bridge expansion during summer heat.
The engineers consulted the dilatometer results to optimize the material selection for the project.
The engineers needed the dilatometer data to predict the stress distribution in the structure.
The experiment involved heating the sample inside the dilatometer at a controlled rate.
The experiment required a high-precision dilatometer to detect subtle thermal effects.
The manufacturer's specifications guaranteed the accuracy of the dilatometer's measurements.
The material's expansion characteristics, as revealed by the dilatometer, were unexpected.
The new dilatometer is equipped with advanced temperature control capabilities.
The new model of dilatometer boasted improved stability and reduced noise.
The precision of the dilatometer was essential for detecting subtle changes in length.
The project hinged on obtaining accurate thermal expansion data using the dilatometer.
The research team developed a new method for analyzing dilatometer data.
The research team published their findings after extensive testing with the dilatometer.
The researcher carefully prepared the sample for analysis in the dilatometer.
The researchers were interested in the dilatometer's ability to measure negative thermal expansion.
The results from the dilatometer were compared to theoretical models of thermal expansion.
The sample was carefully placed within the dilatometer's sample holder.
The sensitivity of the dilatometer allowed for the detection of microstructural changes during heating.
The sensitivity of the dilatometer is crucial for measuring the minute expansions of the material.
The sophisticated temperature control of the dilatometer enabled precise measurements.
The student's thesis focused on the development of a novel high-temperature dilatometer.
The team improved the dilatometer design to increase its sensitivity and accuracy.
The team suspected anomalies in the thermal expansion, leading them to utilize the dilatometer.
The team used the dilatometer to investigate the effect of pressure on thermal expansion.
The thermal expansion coefficient was precisely measured using a highly sensitive dilatometer.
The unexpected results from the dilatometer prompted a reevaluation of the material's properties.
The use of the dilatometer significantly improved the accuracy of the thermal expansion measurements.
Understanding the material's response to temperature changes requires accurate data from a dilatometer.
Using the dilatometer, they determined the glass transition temperature of the polymer sample.
Using the dilatometer, we could measure the material's response to rapid temperature changes.
We employed a custom-built dilatometer to analyze the expansion behavior of the composite material.