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Hydrogen Sulfide Detection

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Hydrogen sulfide can be measured a variety of methods due to sulfur’s versatile chemistry. Sulfur has five oxidation states (-2, 0, +2, +4, +6) and readily forms gaseous, aqueous, and solid compounds at room temperature and pressure, which can be effectively manipulated in laboratory settings. Regulatory agencies use multi-phase laboratory-based methods for high sensitivity and selectivity for hydrogen sulfide, but routine workplace monitoring mostly use near-real-time sensors that operate on the basis of a single sulfur reaction. This wiki is an organizing page to list and compare various methods for detecting and measuring hydrogen sulfide, including regulatory, workplace monitoring, and DIY methods.

Questions



Regulatory Methods for Measuring Hydrogen Sulfide

The Occupational Safety and Health Administration (OSHA), which regulates workplace exposure to hydrogen sulfide uses air grab samples where hydrogen sulfide sorbs onto or reacts with chemicals in the sampling apparatus. Then, in the laboratory, sulfur is released through oxidation, and the sulfate ion that is produced is analyzed through ion chromatography and conductivity measurements. The OSHA standard method for this is OSHA Method 1008; OSHA’s scientific research counterpart the National Institute for Occupational Safety and Health (NIOSH) uses a similar method, NIOSH Method 6013.

The Environmental Protection Agency (EPA) minimally regulates hydrogen sulfide emissions. Rather than an air grab sample, the EPA uses several aliquots from in-line sampling. The compounds in the sample stream are separated by gas chromatography, and then the hydrogen sulfide is measured by dimerizing to S2 gas, exciting it, and then monitoring the relaxation emissions at a specific wavelength (394 nm). The EPA has been using this method, EPA Method 15, for decades.

A rough comparison of these three regulatory methods is below:

Method Name | Agency | Sample Type | Analysis | Detection _ | _ | _ | _ | _ Method 1008 | OSHA | grab | IC | > 0.5 ppm Method 6013 | NIOSH | grab | IC | 0.6-14 ppm Method 15 | EPA | in-line | FPD | > 0.5 ppmv

Hydrogen Sulfide Workplace Monitoring Methods

Routine workplace monitoring methods for hydrogen sulfide generally have much less information available about them due to the proprietary nature of most equipment. However, most fall into two general categories: colorimetric reactions that can be visually discerned, and electrochemical sensors.

Colorimetric Measurements

The Safety Equipment Institute (SEI) is a third-party organization that certifies a variety of testing and protective equipment. OSHA recommends two instruments for on-site workplace sampling that have been SEI certified for hydrogen sulfide measurement (see Gas Detector Tubes under “Products and Standards” at http://www.seinet.org/index.htm. The two tubes recommended are manufactured by Gastec and by Matheson-Kitagawa. The Gastec hydrogen sulfide detection tubes and the Matheson-Kitagawa hydrogen sulfide detection tubes operate on the same principle reaction. In each, the hydrogen sulfide reacts with lead acetate coated beads, producing a brown lead sulfide compound (and acetic acid). The tubes change color from white to brown as lead sulfide is formed. Both products’ range from less than 1 ppm to more than 100 ppm, are shelf-stable for 3 years, and cost less than $15 per tube ($143.00 for a 10-pack of Gastec, $66.40 for a 10-pack of Matheson-Kitagawa).

Another workplace colorimetric hydrogen sulfide monitor is a passive sampler by Morphix Technologies. This SafeAir(™) passive sampler for hydrogen sulfide doesn’t state its underlying chemistry like the Gastec and Matheson-Kitagawa tubes do, unfortunately. The manufacturer’s product information claims there are no known interferences and that the minimum detection limit is 0.25 ppm over 8 hours, and detection range of 0.25 to 2 ppm. Rather than recording a progressive concentration of hydrogen sulfide, this badge changes color upon reaching a threshold sulfide concentration, so only indicates if the ambient hydrogen sulfide is higher or lower than that threshold value. These badges are very inexpensive, costing $160.65 for a pack of 50.

A method published by ASTM International (previously the American Society for Testing and Materials), a large international non-profit organization that develops standards and methods, also utilizes the principles of a colorimetric reaction. However, this ASTM Method D4323 offers substantially more sensitivity, ranging from 1 ppbv to 3000 ppbv, because it measures a difference in reflectivity rather than quantifying a color change: Method D4323 introduces an air sample to a chamber with lead acetate impregnated tape, and measures the change in reflectivity as lead sulfide is formed. The price of this apparatus isn’t readily available, but would require a semi-permanent installment rather than a handheld or easily portable sensor.

Electrochemical Measurements

The other main type of workplace monitoring methods for hydrogen sulfide is using electrochemical sensors. These sensors are significantly more expensive than the visual colorimetric badges and tubes, but are also much more precise. A widely used and well-documented tool for monitoring hydrogen sulfide is the Jerome sensor. The Jerome sensor is handheld and offers measurements within 30 seconds of sampling, with a detection range of 3 ppb to 50 ppm. The Jerome sensor monitors the electrical resistance through a gold film inside it. Hydrogen sulfide will react with the gold film to form gold sulfide, which is less conductive than pure gold. The sensor registers that change in resistance, which is related to the proportion of gold sulfide, related to the concentration of hydrogen sulfide in the sampled air. Unfortunately, the Jerome sensor does cost several thousand dollars. They can be rented for $100 per day (or better rates for a week or month) from a company called Peterson Environmental.

Other companies sell electrochemical hydrogen sulfide sensors other than the Jerome sensor, but most do not provide adequate information to describe how the sensor works, so we have not included them in this discussion.

Information about other types of devices for monitoring hydrogen sulfide can be found on pages 33-34 (39-40 of pdf) of this EPA document: https://nepis.epa.gov/Adobe/PDF/P100NG53.pdf.

Do-It-Yourself Methods

INFO COMING SOON. In the meantime, please see: https://publiclab.org/wiki/hydrogen-sulfide#Do-It-Yourself+approaches+to+detection