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Carbon flame ionization detector

Various types of detector tubes have been devised. The NIOSH standard number S-311 employs a tube filled with 420—840 p.m (20/40 mesh) activated charcoal. A known volume of air is passed through the tube by either a handheld or vacuum pump. Carbon disulfide is used as the desorbing solvent and the solution is then analyzed by gc using a flame-ionization detector (88). Other adsorbents such as siUca gel and desorbents such as acetone have been employed. Passive (diffuse samplers) have also been developed. Passive samplers are useful for determining the time-weighted average (TWA) concentration of benzene vapor (89). Passive dosimeters allow permeation or diffusion-controlled mass transport across a membrane or adsorbent bed, ie, activated charcoal. The activated charcoal is removed, extracted with solvent, and analyzed by gc. Passive dosimeters with instant readout capabiUty have also been devised (85). [Pg.46]

The most widely used method of analysis for methylene chloride is gas chromatography. A capillary column medium that does a very good job in separating most chlorinated hydrocarbons is methyl silicone or methyl (5% phenyl) silicone. The detector of choice is a flame ionization detector. Typical molar response factors for the chlorinated methanes ate methyl chloride, 2.05 methylene chloride, 2.2 chloroform, 2.8 and carbon tetrachloride, 3.1, where methane is defined as having a molar response factor of 2.00. Most two-carbon chlorinated hydrocarbons have a molar response factor of about 1.0 on the same basis. [Pg.520]

For selective estimation of phenols pollution of environment such chromatographic methods as gas chromatography with flame-ionization detector (ISO method 8165) and high performance liquid chromatography with UV-detector (EPA method 625) is recommended. For determination of phenol, cresols, chlorophenols in environmental samples application of HPLC with amperometric detector is perspective. Phenols and chlorophenols can be easy oxidized and determined with high sensitivity on carbon-glass electrode. [Pg.129]

By using a flame ionization detector (FID), most compounds having a bond of carbon and hydrogen can be measured. This detector was originally developed for gas chromatography and employs a sensitive electrometer that measures the change in ion intensity resulting from the combustion of air... [Pg.1297]

The flame ionization detector Is the most popular of the flame-based detectors. Apart from a reduction in sensitivity compared to expectations based on gas chromatographic response factors [138] and incompatibility with the high flow rates of conventional bore columns (4-5 mm I. 0.), the flame ionization detector is every bit as easy to use in SFC as it is in gas chromatography [148,149]. It shows virtually no response to carbon dioxide, nitrous oxide and sulfur hexafluoride mobile phases but is generally incompatible with other mobile phases and mixed mobile phases containing organic modifiers except for water and formic acid, other gas chromatographic detectors that have been used in SFC include the thermionic ionization detector (148,150], ... [Pg.837]

GC is coupled with many detectors for the analysis of pesticides in wastewater. At the present time the most popular is GC-MS, which will be discussed in more detail later in this section. The flame ionization detector (FID) is another nonselective detector that identifies compounds containing carbon but does not give specific information on chemical structure (but is often used for quantification because of the linear response and sensitivity). Other detectors are specific and only detect certain species or groups of pesticides. They include electron capture,nitrogen-phosphorus, thermionic specific, and flame photometric detectors. The electron capture detector (ECD) is very sensitive to chlorinated organic pesticides, such as the organochlorine compounds (OCs, DDT, dieldrin, etc.). It has a long history of use in many environmental methods,... [Pg.59]

Catalysts were tested for oxidations of carbon monoxide and toluene. The tests were carried out in a differential reactor shown in Fig. 12.7-1 and analyzed by an online gas chromatograph (HP 6890) equipped with thermal conductivity and flame ionization detectors. Gases including dry air and carbon monoxide were feed to the reactor by mass flow controllers, while the liquid reactant, toluene was delivered by a syringe pump. Thermocouple was used to monitor the catalyst temperature. Catalyst screening and optimization identified the best catalyst formulation with a conversion rate for carbon monoxide and toluene at room temperature of 1 and 0.25 mmolc g min1. Carbon monoxide and water were the only products of the reactions. [Pg.376]

Flame ionization detectors are capable of detecting virtually all organic compounds and show a lower limit of detection of approximately 1 X 10-9 mol. They also show good linearity of response and the fact that they do not respond to oxides of carbon or nitrogen or to water makes them particularly convenient for aqueous samples. They have the disadvantage, however, that samples are destroyed unless a stream-splitting device is incorporated. [Pg.121]

Biological tissues Add water to tissue sample (at 50 C) and homogenise extract with carbon disulfide and analyze Gas chromatography flame ionization detector 0.5 ag/g No data Letz et al. 1984... [Pg.102]

OSHA. 1979. Method No. 05. Collection on charcoal adsorbent, desorption with carbon disulfide, analysis by gas chromatography using a flame ionization detector. Organic Methods Evaluation Branch, Occupational Safety and Health Administration Analytical Lab, Salt Lake City, UT. May 1979. [Pg.280]

Federal Emergency Management Agency flame ionization detector fraction of organic carbon cubic feet... [Pg.31]

Carlsson and Wiles have in an early work (14) discussed the ketonic oxidation products of PP films. The volatile products were analysed in GC with a flame ionization detector (FID) and a thermal conductivity detector (TCD) giving the major oxidation products carbon monoxide and acetone. Other products detected were water, formaldehyde, formic acid, propane, acetic acid and iso-propylalcohol. [Pg.62]

DOBBS, R. A., WISE, R. H. and DEAN, R. B. Measurement of Organic Carbon in Water Using the Hydrogen-Flame Ionization Detector. Anal. Chem., 39, 1255 (1967). [Pg.98]

The gases exiting the reactor pass through a Beckman 565 infrared CO2 analyzer, which continuously monitored the production of carbon dioxide. Gas composition analysis was performed on-line using a Hewlett Packard 5890 II gas chromatograph, equipped with both a thermal conductivity and a flame ionization detector and a Porapak-Q column. Additional experimental details are given elsewhere (9). [Pg.412]

In the flame ionization detector in Figure 24-18, eluate is burned in a mixture of H2 and air. Carbon atoms (except carbonyl and carboxyl carbons) produce CH radicals, which are thought to produce CHO+ ions and electrons in the flame. [Pg.542]

See other pages where Carbon flame ionization detector is mentioned: [Pg.21]    [Pg.570]    [Pg.102]    [Pg.2204]    [Pg.423]    [Pg.1298]    [Pg.201]    [Pg.59]    [Pg.8]    [Pg.825]    [Pg.370]    [Pg.265]    [Pg.470]    [Pg.208]    [Pg.58]    [Pg.1043]    [Pg.192]    [Pg.120]    [Pg.160]    [Pg.263]    [Pg.4]    [Pg.153]    [Pg.36]    [Pg.495]    [Pg.129]    [Pg.223]    [Pg.224]    [Pg.224]    [Pg.318]    [Pg.90]    [Pg.577]    [Pg.703]    [Pg.458]    [Pg.544]   
See also in sourсe #XX -- [ Pg.485 ]



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