California Oxygenates and 8260
Applications | | EST AnalyticalInstrumentation
Fuel oxygenates have been used in gasoline for over 30 years to reduce vehicle emissions and enhance engine performance. However, leaks from underground storage tanks have led to groundwater contamination by highly soluble oxygenated compounds. Detecting these pollutants at low levels requires optimized sample preparation and analytical conditions.
This study evaluated purge and trap conditions to determine the most efficient approach for analyzing fuel oxygenates and EPA 8260 volatile organic compounds in water. Variables included purge volume and temperature, and performance was assessed through calibration range, linearity, detection limits, and compound response.
Increasing sample volume improved analyte response, with a 10 mL sample and a 60°C purge offering the best compromise between sensitivity and linear range. Heated purge more than doubled the ethanol signal. Under these conditions, detection limits were achieved below regulatory thresholds and calibration linearity was maintained across the compound panel. The moisture reduction trap effectively removed water during heated desorption, preserving peak shape and sensitivity.
The optimized method enables reliable quantification of fuel-derived oxygenates and volatile organics in groundwater at trace levels. Controlled moisture elimination enhances system robustness, reduces maintenance, and streamlines routine environmental monitoring, QA/QC checks, and compliance analyses.
The Encon Evolution purge and trap system with a moisture reduction trap and optimized purge conditions (10 mL sample, 60°C) provides a sensitive, precise, and linear method for EPA 8260 volatiles and gasoline oxygenates in water. The approach meets or exceeds method criteria and offers robust performance for environmental analysis.
GC/MSD, GC/SQ, Purge and Trap
IndustriesEnvironmental
ManufacturerAgilent Technologies, EST Analytical, Restek
Summary
Importance of the Topic
Fuel oxygenates have been used in gasoline for over 30 years to reduce vehicle emissions and enhance engine performance. However, leaks from underground storage tanks have led to groundwater contamination by highly soluble oxygenated compounds. Detecting these pollutants at low levels requires optimized sample preparation and analytical conditions.
Objectives and Study Overview
This study evaluated purge and trap conditions to determine the most efficient approach for analyzing fuel oxygenates and EPA 8260 volatile organic compounds in water. Variables included purge volume and temperature, and performance was assessed through calibration range, linearity, detection limits, and compound response.
Methodology and Used Instrumentation
- Sample preparation: Water samples spiked with California oxygenate mixture and ethanol standards.
- Purge volumes tested: 5, 10 and 25 mL; purge temperatures: room temperature and 60°C.
- Calibration: Nine-point curves from 0.5 to 200 ppb for ethers and 2.5 to 1000 ppb for TBA and ethanol; method detection limits determined from seven replicates.
- Autosampler: Centurion WS autosampler; concentrator: Encon Evolution purge and trap with moisture reduction trap (MoRT); GC/MS: Agilent 7890A/5975 Inert XL with Rtx-624 column.
Main Results and Discussion
Increasing sample volume improved analyte response, with a 10 mL sample and a 60°C purge offering the best compromise between sensitivity and linear range. Heated purge more than doubled the ethanol signal. Under these conditions, detection limits were achieved below regulatory thresholds and calibration linearity was maintained across the compound panel. The moisture reduction trap effectively removed water during heated desorption, preserving peak shape and sensitivity.
Benefits and Practical Applications
The optimized method enables reliable quantification of fuel-derived oxygenates and volatile organics in groundwater at trace levels. Controlled moisture elimination enhances system robustness, reduces maintenance, and streamlines routine environmental monitoring, QA/QC checks, and compliance analyses.
Future Trends and Potential Applications
- Integration with high-throughput and automated sample preparation workflows.
- Adoption of tandem mass spectrometry for enhanced selectivity and lower detection limits.
- Development of novel sorbent materials to expand analyte coverage, including emerging contaminants.
- Field-deployable systems combining portable GC/MS or GC/PID for on-site screening.
Conclusions
The Encon Evolution purge and trap system with a moisture reduction trap and optimized purge conditions (10 mL sample, 60°C) provides a sensitive, precise, and linear method for EPA 8260 volatiles and gasoline oxygenates in water. The approach meets or exceeds method criteria and offers robust performance for environmental analysis.
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
Similar PDF
California Oxygenates and 8260
|Agilent Technologies|Applications
JSB is an authorised partner of California Oxygenates and 8260 Anne Jurek Introduc ction: ars, oxygenated compounds have b een added to gasoline. The addition of For more e…
Key words
purge, purgetrap, traporobenzene, orobenzeneoluene, olueneether, etherdesorb, desorbnzene, nzenebake, bakeppb, ppbtba, tbagenate, genatetert, terttempe, tempebutylb, butylbetrachloroethane
Maximizing Production While Minimizing Costs
|EST Analytical|Applications
Max ximizing g Produc ction Wh hile Miniimizing Costs ANNE JUREK Abstractt: The need d to increase e productivity y and reduce cost is beccoming of grreater conce ern to environm mental labora atories. EST T Analytical has addresssed many…
Key words
rec'y, rec'yrsd, rsdene, eneisop, isopacetate, acetatemetthyl, metthylnzene, nzeneethyyl, ethyyltran, tranhane, hanetert, tertpurge, purgebro, brochlo, chlotrap
Maximizing Production While Minimizing Costs
|Agilent Technologies|Applications
JSB is an authorised partner of Maximizing Production While Minimizing Costs Anne Jurek Abstractt: The need d to increase productivity and reduce cost is bec oming of grreater concern…
Key words
rec'y, rec'yrsd, rsdacetate, acetateene, enemetthyl, metthylpurge, purgeisop, isophane, hanetert, tertnzene, nzeneethyyl, ethyylsur, surether, etherxyle, xylecon
Optimal Conditions for USEPA Method 8260 Analysis
|EST Analytical|Applications
Opttimal Co onditionss for USEEPA Method 8260 Ana alysis Anne Jurek J Introducttion: Over the past p decade, the need for environmenta al laboratoriess using purge e and trap sysstems to repo ort at or below the t Method Detection…
Key words
trap, trappurge, purgecarryove, carryoveest, estbake, bakeencon, encondeso, desoenzene, enzenechlo, chlonzene, nzeneorb, orbsparge, spargeution, utionbrom, bromfigu
