Abstract
Abstract. Proton Transfer Reaction-Mass Spectrometry (PTR-MS) and thermal desorption Gas Chromatography-Mass Spectrometry (GC-MS) allow for absolute quantification of a wide range of atmospheric volatile organic compounds (VOCs) with concentrations in the ppbv to pptv range. Although often neglected, routine calibration is necessary for accurate quantification of VOCs by PTR-MS and GC-MS. Several gas calibration methods currently exist, including compressed gas cylinders, permeation tubes, diffusion tubes, and liquid injection. While each method has its advantages and limitations, no single technique has emerged that is capable of dynamically generating known concentrations of complex mixtures of VOCs over a large concentration range (ppbv to pptv) and is technically simple, field portable, and affordable. We present the development of a new VOC calibration technique based on liquid injection with these features termed Dynamic Solution Injection (DSI). This method consists of injecting VOCs (0.1–0.5 mM) dissolved in cyclohexane (PTR-MS) or methanol (GC-MS) into a 1.0 slpm flow of purified dilution gas in an unheated 25 ml glass vial. Upon changes in the injection flow rate (0.5–4.0 μl min−1), new VOC concentrations are reached within seconds to minutes, depending on the compound, with a liquid injection flow rate accuracy and precision of better than 7% and 4% respectively. We demonstrate the utility of the DSI technique by calibrating a PTR-MS to seven different cyclohexane solutions containing a total of 34 different biogenic compounds including volatile isoprenoids, oxygenated VOCs, fatty acid oxidation products, aromatics, and dimethyl sulfide. We conclude that because of its small size, low cost, and simplicity, the Dynamic Solution Injection method will be of great use to both laboratory and field VOC studies.
Highlights
Measurements of gas-phase volatile organic compound (VOC) concentrations are critical for studying fundamental physical, chemical, and biological processes occurring in the atmosphere
We present the development of a new simplified calibration system termed dynamic solution injection (DSI) based on a stepper motor controlled syringeless pump capable of delivering continuous liquid flow rates with values spanning six orders of magnitude
An additional tube (1/16 in O.D. × 1 in) was inserted through the septum to allow room air to enter the calibration solution vial when liquid solution was pumped out. Another 1/16 in O.D. × 1 ft tube was pierced through the septum of a mixing glass vial while 1.0 slpm of ultra high purity (UHP) N2 flowed into the mixing vial via a separate 1/16 in O.D. tube that was pierced through the septum
Summary
Measurements of gas-phase volatile organic compound (VOC) concentrations are critical for studying fundamental physical, chemical, and biological processes occurring in the atmosphere. This poses a technical challenge because the species of interest are usually present in very trace quantities and an extremely sensitive instrument is required to directly measure them. The static method has been successfully used to generate VOC standards of nonpolar compounds with vapor pressures higher than undecane, with high accuracy and stability in gas cylinders (Rappengluck et al, 2006). A major disadvantage of using static methods for the preparation of polar or low vapor pressure VOC standards is the absorptive losses
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