Hydrogen sulfide (H2S) is a noxious gas characterized by its distinctive stench reminiscent of rotten eggs.[1] It goes by several colloquial names, including sewer gas, stink damp, swamp gas, and manure gas.[2] This gas naturally occurs in crude petroleum, natural gas, hot springs, and certain food items. In the natural world, H2S is a common byproduct of the decomposition of organic matter, such as human and animal waste, in septic and sewer systems due to bacterial processes.[3] Additionally, it is industrially produced in significant quantities through activities and facilities like petroleum and natural gas extraction, refining, wastewater treatment, coke ovens, tanneries, kraft paper mills, and landfills.[4]
A hydrogen sulfide sensor or H2S sensor is a gas sensor for the measurement of hydrogen sulfide.[5]
Principle
editThe H2S sensor is a metal oxide semiconductor (MOS) sensor which operates by a reversible change in resistance caused by adsorption and desorption of hydrogen sulfide in a film with hydrogen sulfide sensitive material like tin oxide thick films and gold thin films. Current response time is 25 ppb to 10 ppm < one minute.
Gas sensing mechanism
editThe fundamental principle underlying gas detection in MOS-based gas sensors relies on alterations in the electrical conductivity or resistivity of MOS. In MOS, operating within typical temperature ranges and under ordinary atmospheric conditions, the presence of atmospheric oxygen results in the formation of an electron-depleted surface layer, which either adsorbs or chemisorbs the oxygen molecules from the surrounding air. Initially, when the surface layer is exposed to the air, oxygen ions such as O−2, O−, and O2 are adsorbed onto the metal oxide grains, causing a band bending effect and the creation of a depletion region known as the space charge field.
When specific target gas particles come into contact with the surface of the metal oxide grains, they interact with the oxygen anions, leading to a modification in the electron concentration within the metal oxide materials. Consequently, this alteration induces a change in conductivity, thus generating an electronic response signal that can be quantified. The detection mechanism employed by metal oxide gas sensors is linked to the adsorption of ions and species on their surfaces. When the gas sensor is exposed to oxygen, adsorbed oxygen particles are formed, with oxygen atoms stripping electrons from the interior of the metal oxide. The ensuing sequence of reactions illustrates the kinetics of this adsorption process .
O2(gas)⇔O2 (absorbed),
O2(absorbed)+e−⇔O−2, (<100∘C),
O−2+e−⇔2O− (100−300∘C),
andO−+e−⇔O2−(>300∘C).
The composition of chemisorbed oxygen ions on gas sensors is contingent upon the operational temperature. At temperatures below 100 °C, O−2 ions are prevalent, while in the range between 100 °C and 300 °C, O− ions predominate. For temperatures exceeding 300 °C, the predominant chemisorbed oxygen ions shift to O2−.
Naturally occurring hazardous gases can be categorized into two groups based on their oxidizing and reducing effects. Gases like NO2, NO, N2O, and CO2 are considered oxidizing agents, while H2S, CO, NH3, CH4, and SO2 fall into the reducing category. When an n-type MOs gas sensor is exposed to an oxidizing gas, the target gas interacts with the surrounding oxygen ions and captures electrons at the sensor's surface. This interaction leads to a reduction in the electron concentration within the MOS. Since electrons are the primary charge carriers in n-type MOS, their conductance decreases when exposed to oxidizing gases.
In contrast, in a p-type MOS gas sensor, holes serve as the primary charge carriers. When exposed to oxidizing gases, the extracted electrons increase the concentration of holes within the MOS. Consequently, the conductance of p-type MOS increases in the presence of oxidizing gases. Figure 1 provides a schematic diagram illustrating the sensing mechanism for n-type and p-type MOS.
Applications
editThis type of sensor has been under constant development because of the toxic and corrosive nature of hydrogen sulfide:
- The H2S sensor is used to detect hydrogen sulfide in the hydrogen feed stream of fuel cells to prevent catalyst poisoning and to measure the quality of guard beds used to remove sulfur from hydrocarbon fuels.[6]/-
Research
edit- 2004 — a nanocrystalline SnO2–Ag on ceramic wafer sensor is reported.[7]
See also
editReferences
edit- ^ Malone Rubright, Samantha L.; Pearce, Linda L.; Peterson, Jim (2017-12-01). "Environmental Toxicology of Hydrogen Sulfide". Nitric Oxide: Biology and Chemistry. 71: 1–13. doi:10.1016/j.niox.2017.09.011. ISSN 1089-8603. PMC 5777517. PMID 29017846.
- ^ NIOSH: training occupational safety and health professionals: fact sheet (Report). U.S. Department of Health and Human Services, Public Health Service, Centers for Disease Control and Prevention, National Institute for Occupational Safety and Health. 2001-07-01. doi:10.26616/nioshpub2001158.
- ^ Zhang, Lingzhi; Wang, Xueqin; Millet, Jean-Marc M.; Matter, Paul H.; Ozkan, Umit S. (2008-12-15). "Investigation of highly active Fe-Al-Cu catalysts for water-gas shift reaction". Applied Catalysis A: General. 351 (1): 1–8. doi:10.1016/j.apcata.2008.08.019. ISSN 0926-860X.
- ^ Kim, Ki-Hyun; Choi, YJ; Jeon, EC; Sunwoo, Young (2005-02-01). "Characterization of malodorous sulfur compounds in landfill gas". Atmospheric Environment. 39 (6): 1103–1112. Bibcode:2005AtmEn..39.1103K. doi:10.1016/j.atmosenv.2004.09.083. ISSN 1352-2310.
- ^ H2S sensors
- ^ "Ceramic sensor". Archived from the original (PDF) on 2020-09-15. Retrieved 2009-12-13.
- ^ Gong, J.; Chen, Q.; Lian, M.R.; Liu, N.C.; Stevenson, R.G.; Adami, F. (2006). "Micromachined nanocrystalline silver doped SnO2 H2S sensor". Sensors and Actuators B: Chemical. 114 (1): 32–39. doi:10.1016/j.snb.2005.04.035.