A malfunctioning desorber can lead to skewed data and unreliable experimental conclusions.
After the sample is heated, the desorber releases the volatile organic compounds for analysis.
Before analysis, the sample is placed into the desorber and heated to a specific temperature.
The automated desorber system increased the throughput of the analytical laboratory.
The company developed a novel desorber design that minimizes carryover between samples.
The data from the desorber was carefully analyzed to identify the presence of specific contaminants.
The design of the desorber must consider the potential for thermal decomposition of the sample.
The desorber is a valuable tool for environmental monitoring and food safety analysis.
The desorber is an essential component in many analytical workflows for volatile compounds.
The desorber is an integral part of the analytical process for determining volatile compound concentrations.
The desorber is compatible with a variety of different sample matrices.
The desorber is compatible with a wide range of analytical instruments.
The desorber is connected to the gas chromatograph via a heated transfer line.
The desorber is designed to minimize the carryover of sample components from one run to the next.
The desorber is used in forensic science to analyze trace evidence samples.
The desorber is used in the aerospace industry to analyze the composition of materials in spacecraft.
The desorber is used in the agriculture industry to analyze pesticide residues in crops.
The desorber is used in the art conservation industry to analyze the composition of pigments and varnishes.
The desorber is used in the automotive industry to analyze the emissions from vehicle exhaust.
The desorber is used in the biotechnology industry to analyze the composition of proteins and peptides.
The desorber is used in the consumer products industry to analyze the composition of cosmetics and personal care products.
The desorber is used in the energy industry to analyze the composition of fuels and lubricants.
The desorber is used in the environmental protection industry to monitor air and water quality.
The desorber is used in the food industry to analyze aroma compounds in food products.
The desorber is used in the materials science industry to analyze the composition of polymers.
The desorber is used in the medical field to analyze breath samples for disease diagnosis.
The desorber is used in the mining industry to analyze the composition of ore samples.
The desorber is used in the nuclear industry to analyze radioactive isotopes.
The desorber is used in the perfume industry to analyze fragrance components.
The desorber is used in the pharmaceutical industry to analyze residual solvents in drug products.
The desorber is used in the semiconductor industry to analyze the composition of thin films.
The desorber is used to analyze the volatile organic compounds emitted from building materials.
The desorber played a critical role in determining the composition of the ancient artifact.
The desorber was used to analyze the air quality inside the factory building.
The desorber's ability to selectively release different compounds is a key advantage.
The desorber's control system allows for precise temperature programming and monitoring.
The desorber's design allows for easy access to the sample chamber for cleaning and maintenance.
The desorber's design allows for easy cleaning and decontamination.
The desorber's design allows for easy integration with other analytical instruments.
The desorber's design allows for easy replacement of the absorbent material.
The desorber's design incorporates features to prevent condensation and blockage.
The desorber's design incorporates features to prevent sample degradation during analysis.
The desorber's design incorporates safety features to prevent accidents and injuries.
The desorber's design minimizes the risk of contamination from ambient air.
The desorber's efficiency is a key factor in determining the overall sensitivity of the analysis.
The desorber's heating rate is critical for separating compounds with similar boiling points.
The desorber's performance is affected by the flow rate of the carrier gas.
The desorber's performance is affected by the type of adsorbent material used.
The desorber's performance is critical for accurate and reliable analytical results.
The desorber's performance is crucial for identifying and quantifying trace contaminants.
The desorber's performance is dependent on the type of absorbent material used.
The desorber's performance is evaluated based on its ability to quantitatively release the target analytes.
The desorber's performance is evaluated using a variety of quality control metrics.
The desorber's performance is optimized for specific types of analytical measurements.
The desorber's performance is optimized for the specific application.
The desorber's robust design ensures reliable performance in harsh environments.
The desorber's software allows for precise control of temperature and flow rate.
The desorber's temperature is carefully monitored to prevent overheating and damage.
The desorption process within the desorber is carefully controlled to prevent analyte degradation.
The efficiency of the desorber is directly related to the accuracy of the quantitative analysis.
The efficiency of the thermal desorber is crucial for accurate gas chromatography results.
The environmental engineer used a desorber to extract pollutants from contaminated soil samples.
The maintenance schedule for the desorber includes regular cleaning and calibration.
The manufacturer provides detailed instructions on how to operate and maintain the desorber.
The new desorber features a self-cleaning mechanism to prevent contamination.
The new desorber model boasts a significantly faster heating rate than its predecessor.
The new desorber model features a faster cooling rate for increased throughput.
The performance of the desorber was evaluated using a series of standard reference materials.
The researchers are exploring the use of a micro-desorber for point-of-care diagnostics.
The researchers are investigating the use of a catalytic desorber for enhanced analyte detection.
The researchers are investigating the use of a disposable desorber for single-use applications.
The researchers are investigating the use of a field-portable desorber for on-site analysis.
The researchers are investigating the use of a laser-induced desorber for rapid analysis.
The researchers are investigating the use of a multi-dimensional desorber for complex mixtures.
The researchers are investigating the use of a non-thermal desorber for sensitive compounds.
The researchers are investigating the use of a pulsed desorber for increased sensitivity.
The researchers are investigating the use of a selective desorber for targeting specific compounds.
The researchers are investigating the use of a temperature-programmed desorber for separating complex mixtures.
The researchers are investigating the use of different carrier gases in the desorber system.
The researchers are working to develop a more automated desorber for high-throughput analysis.
The researchers are working to develop a more compact and lightweight desorber for field use.
The researchers are working to develop a more cost-effective desorber for wider adoption.
The researchers are working to develop a more robust and reliable desorber for demanding applications.
The researchers are working to develop a more sensitive desorber for detecting low-level analytes.
The researchers are working to develop a more sustainable desorber using environmentally friendly materials.
The researchers are working to develop a more user-friendly desorber for non-technical users.
The researchers are working to develop a more versatile desorber that can handle a wide range of samples.
The researchers are working to improve the desorber's ability to handle complex sample mixtures.
The scientist carefully calibrated the desorber to ensure optimal analyte recovery.
The scientist used the desorber to identify the source of the odor in the sample.
The sensitivity of the analysis was significantly improved by using the optimized desorber settings.
The software interface of the desorber allows for easy programming and data acquisition.
The team is developing a portable desorber for on-site analysis of environmental samples.
The team is working to develop a more energy-efficient desorber for field applications.
The technician replaced the faulty heating element in the desorber to restore functionality.
The temperature profile of the desorber needs to be optimized for complete analyte release.
The type of desorber used depends on the properties of the target compounds and the matrix.
The use of a cryotrap after the desorber can further concentrate the analytes of interest.
The use of the desorber allows for the direct analysis of solid and liquid samples.
To improve sensitivity, the researchers coupled the desorber with a highly sensitive mass spectrometer.