Cryogen-free analysis of VOCs in car exhaust
Applications | 2020 | Thermo Fisher ScientificInstrumentation
Versatile and routine monitoring of volatile organic compounds in vehicle exhaust is crucial for air quality management. Cryogenic methods have traditionally been used for trapping very volatile compounds, but they complicate field operations. A cryogen-free thermal desorption protocol simplifies logistics and maintains performance.
This study aimed to validate a simplified, cryogen-free thermal desorption coupled gas chromatography dual flame ionization detection method for analyzing C2–C11 hydrocarbons in exhaust gases in accordance with EPA photochemical assessment monitoring scheme requirements.
A Markes CIA Advantage-xr autosampler with electronic mass flow control collected exhaust samples. Humidity was removed via a Kori-xr water condenser before trapping analytes on a multi-sorbent focusing trap in a UNITY-xr thermal desorber at –30 °C. Rapid heating backflush transferred analytes into a Thermo Scientific TRACE 1310 GC outfitted with a microfluidic Deans Switch and dual flame ionization detectors. Separation occurred on a primary TraceGOLD TG-1MS column and a secondary HP-PLOT AL/S column. Chromeleon CDS managed instrument control, data acquisition, and reporting.
Integration with real-time monitoring networks could enhance urban air quality mapping. Coupling cryogen-free TD with mass spectrometry may broaden analytical scope. Further automation and miniaturization will support portable, remote environmental monitoring platforms.
The cryogen-free thermal desorption GC-FID method with dual columns delivers robust, reproducible analysis of vehicle exhaust VOCs, meeting stringent EPA PAMS requirements while removing the logistical burden of cryogenic cooling.
GC, Thermal desorption
IndustriesEnvironmental
ManufacturerThermo Fisher Scientific, Markes
Summary
Significance of the Topic
Versatile and routine monitoring of volatile organic compounds in vehicle exhaust is crucial for air quality management. Cryogenic methods have traditionally been used for trapping very volatile compounds, but they complicate field operations. A cryogen-free thermal desorption protocol simplifies logistics and maintains performance.
Objectives and Study Overview
This study aimed to validate a simplified, cryogen-free thermal desorption coupled gas chromatography dual flame ionization detection method for analyzing C2–C11 hydrocarbons in exhaust gases in accordance with EPA photochemical assessment monitoring scheme requirements.
Methodology and Instrumentation
A Markes CIA Advantage-xr autosampler with electronic mass flow control collected exhaust samples. Humidity was removed via a Kori-xr water condenser before trapping analytes on a multi-sorbent focusing trap in a UNITY-xr thermal desorber at –30 °C. Rapid heating backflush transferred analytes into a Thermo Scientific TRACE 1310 GC outfitted with a microfluidic Deans Switch and dual flame ionization detectors. Separation occurred on a primary TraceGOLD TG-1MS column and a secondary HP-PLOT AL/S column. Chromeleon CDS managed instrument control, data acquisition, and reporting.
Key Results and Discussion
- Successful separation of 56 target hydrocarbons with resolution ≥ 1.4 and asymmetry factors near unity.
- Cryogen-free sample-to-sample cycle of approximately 56 min using overlap sampling and rapid oven cooldown.
- Calibration for benzene, propane, and undecane showed linearity R2 > 0.999 and calibration factor RSD < 3 %.
- Extended calibration range from 4.25 ppb to 6000 ppb achieved R2 = 0.9998.
- Carryover below 0.3 % for all PLOT column analytes; negligible on the primary column.
- Repeatability over three injections exhibited peak area RSDs < 10 % across all compounds.
Benefits and Practical Applications of the Method
- Eliminates the need for liquid cryogens and simplifies field deployment.
- Rapid turnaround enabled by overlap sampling and fast trap heating.
- Modular, Instant Connect detectors minimize downtime and ease maintenance.
- Automated workflows ensure compliance with PAMS protocols and reduce manual data handling.
Future Trends and Potential Applications
Integration with real-time monitoring networks could enhance urban air quality mapping. Coupling cryogen-free TD with mass spectrometry may broaden analytical scope. Further automation and miniaturization will support portable, remote environmental monitoring platforms.
Conclusion
The cryogen-free thermal desorption GC-FID method with dual columns delivers robust, reproducible analysis of vehicle exhaust VOCs, meeting stringent EPA PAMS requirements while removing the logistical burden of cryogenic cooling.
References
- US EPA definition of volatile organic compounds.
- US EPA indoor air quality and VOCs guidance.
- Vivaldo et al. The network of plants volatile organic compounds, Nature, 2017.
- American Lung Association overview of VOCs.
- Hong Kong Environmental Protection Department on VOCs and smog.
- Ismail and Hameed, Environmental effects of VOCs on the ozone layer, 2013.
- US EPA PAMS program information.
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