Abstract
Efficient catalysts in the oxidation of hydrogen sulfide oxygen species are activated carbons. Activated carbon research highlights the important role of surface functional groups as a source for free radicals and initiate steps in catalytic activation of oxygen on the surface of activated carbon. Studies show that with increasing oxygen content on the surface of carbon, the concentration of functional groups increases the adsorption capacity of sulfur (II) species and their oxidation to higher degrees of oxidation. Is noted the important role of acid–base properties of activated carbons and their surface pH in suspension, influencing dissociation and oxidation of hydrogen sulfide to different species of sulfur. Oxidized active carbon is rich in acidic functional groups on the surface, has a higher catalytic activity and is more efficient compared to commercial activated carbon BAU-A, which is poor in functional groups and has an alkaline surface pH. Oxidized active carbon produced from peach stones and impregnated with ions Fe3+ and Cu2+ shows increased catalytic activity in the oxidation of sulfur species in reduced form, compared to adsorbents before impregnation with metals. Oxidation products generated in the presence of catalysts obtained by impregnation with metals are thiosulfates, sulfites and sulfates, without the formation of colloidal sulfur. The state or form of immobilized metals on the surface of activated carbon influences significantly the selectivity of formation of sulfur species. Impregnated metals present on the surface of activated carbon in the form of ions, favor the formation of sulfur in high oxidation degree of S4+ and S6+, while impregnated metals present as oxides, favor the oxidation of ion sulfide to elementary sulfur. Comparative analysis of the catalytic activity of obtained catalysts shows that the most effective catalyst is obtained from oxidized activated carbon from peach stones and impregnated with Cu2+ions. The catalyst shows pronounced catalytic activity at higher pH values of the solutions, which is important from the practical point of view, ensuring efficient catalytic activity under to near natural groundwater alkaline pH. The catalyst can be re-used for a long time, keeping the pores unclogged and maintaining the porous structure at the characteristic parameters of this adsorbent, being recommended for practical purposes to remove hydrogen sulfide species from sulfurous groundwater.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Kawamura S (1991) Integrated design of water treatment facilities. Wiley, New York, p 658
Nicoladze GI (1987) Improving of ground water quality. Stroyizdat, Moskow, p 240 (in Russian)
Hoffmann MR, Lim BC (1979) Kinetics and mechanism of the oxidation of sulfide by oxygen: catalysis by homogeneous metal-phthalocyanine complexes. Environ Sci Technol 13(11):1406–1414
Alferova LA, Titova GA (1969) Study of velocity and oxidation reaction mechanism of hydrogen sulfide, sodium hidrogenosulfide and sodium, iron and copper sulfide in water solution by oxygen from air. J Appl Chem (USSR) 1:192–196 (in Russian)
Chen KY, Morris JC (1972) Kinetics of oxidation of aqueous sulfide by O2. Environ Sci Technol 6(6):529–537
Hoffman MR (1977) Kinetics and mechanism of oxidation of hydrogen sulfide by hydrogen peroxide in acidic solution. Environ Sci Technol 11(1):61–66
O’Brien DJ, Birkner FB (1977) Kinetics of oxigenation of reduced sulfur species in aqueous solution. Environ Sci Technol 11(12):1114–1120
Hong AP, Boyce SD, Hoffman MR (1989) Catalytic autoxidation of chemical contaminants by hybrid complexes of cobalt (II) phthalocyanine. Environ Sci Technol 23(5):533–540
Kotronarou A, Hoffman MR (1991) Catalytic autoxidation of hydrogen sulfide in wastewater. Environ Sci Technol 25(6):1153–1160
Dalai AK, Majumdar A, Tollefson EL (1999) Low temperature catalytic oxidation of hydrogen sulfide in sour produced wastewater using activated carbon catalysts. Environ Sci Technol 33(13):2241–2246
Millero FJ (1986) The thermodynamics and kinetics of the hydrogen sulfide system in natural waters. Mar Chem 18(2–4):121–147
Millero FJ, Hubinger S, Fernandez M, Garnett S (1987) Oxidation of H2S in seawater as a function of temperature, pH, and ionic strength. Environ Sci Technol 21(5):439–443
Andreev A, Prahov L, Gabrovska M, Eliyas A, Ivanova V (1996) Catalytic oxidation of sulphide ions to elementary sulphur in aqueous solutions over transition metal oxides. Appl Catal B 8(4):365–373
Furimsky E (1997) Activity of spent hydroprocessing catalysts and carbon supported catalysts for conversion of hydrogen sulphide. Appl Catal A 156(2):207–218
Li KT, Yen CS, Shyu NS (1997) Mixed-metal oxide catalysts containing iron for selective oxidation of hydrogen sulfide to sulfur. Appl Catal A 156(1):117–130
Terörde RJAM, van den Brink PJ, Visser LM, van Dillen AJ, Geus JW (1993) Selective oxidation of hydrogen sulfide to elemental sulfur using iron oxide catalysts on various supports. Catal Today 17(1–2):217–224
Herszage J, Dos Santos A (2000) The autooxidation of hydrogen sulfide in the presence of hematite. Colloids Surf A 168(1):61–69
Wang X, Jia J, Sun LZT (2008) Mesoporous SBA-15 supported iron oxide: a potent catalyst for hydrogen sulfide removal. Water Air Soil Pollut 193:247–257
Lee Y, Cho M, Kim JY, Yoon J (2004) Chemistry of ferrate (Fe(VI)) in aqueous solution and its applications as a green chemical. J Ind Eng Chem 10(1):161–171
Zabel KR (2007) Manganese greensand and its substitute: these media are widely used in iron, manganese removal. ZPT International Inc, Destin
Makhseed S, Al-Kharafi F, Samuel J, Ateya B (2009) Catalytic oxidation of sulphide ions using a novel microporous cobalt phthalocyanine network polymer in aqueous solution. Catal Commun 10(9):1284–1287
Iliev V, Tomova D (2002) Photocatalytic oxidation of sulfide ion catalyzed by phthalocyanine modified titania. Catal Commun 3(7):287–292
Puri BR, Hazra RS (1971) Carbon-sulphur surface complexes on charcoal. Carbon 9(2):123–134
Cal MP, Strickler BW, Lizzio AA (2000) High temperature hydrogen sulfide adsorption on activated carbon. I. Effects of gas composition and metal addition. Carbon 38(13):1757–1765
Steijns M, Mars P (1974) The role of sulfur trapped in micropores in the catalytic partial oxidation of hydrogen sulfide with oxygen. J Catal 35(1):11–17
Adib F, Bagreev A, Bandosz TJ (1999) Effect of surface characteristics of wood based activated carbons on removal of hydrogen sulfide. J Colloid Interface Sci 214(2):407–415
Mikhalovsky SV, Zaitsev YP (1997) Catalytic properties of activated carbons. I. Gas-phase oxidation of hydrogen sulphide. Carbon 35(9):1367–1374
Primavera A, Trovarelli A, Andreussi P, Dolcetti G (1998) The effect of water in low-temperature catalytic oxidation of hydrogen sulfide to sulfur over activated carbon. Appl Catal A 173(2):185–192
Choi JJ, Hirai M, Shoda M (1991) Catalytic oxidation of hydrogen sulphide by air over an activated carbon fiber. Appl Catal A 79(2):241–248
Klein J, Henning K-D (1984) Catalytic oxidation of hydrogen sulphide on activated carbons. Fuel 63(8):1064–1067
Katoh H, Kuniyoshi I, Hirai M, Shoda M (1995) Studies of the oxidation mechanism of sulphur-containing gases on wet activated carbon fiber. Appl Catal B 6(3):255–262
Bandosz TJ (2006) Carbonaceous materials as desulfurization media. In: Loureiro JM, Kartel MT (eds) Combined and Hybrid Adsorbents, Springer, Dordrecht, p 145–164
Bagreev A, Bashkova S, Locke DC, Bandosz TJ (2001) Sewage sludge derived materials as efficient adsorbents for removal of hydrogen sulfide. Environ Sci Technol 35(7):1537–1543
Choi D-Y, Lee J-W, Jang S-C, Ahn B-S, Choi D-K (2008) Adsorption dynamics of hydrogen sulfide in impregnated activated carbon bed. Adsorption 14:533–538
Lupascu T, Cater R (1997) Study of hydrogen sulfide removal from underground waters by adsorption on active carbons. Bulletin ASRM 1:74–76 (in Romanian)
Cal MP, Strickler BW, Lizzio AA, Gangwal SK (2000) High temperature hydrogen sulfide adsorption on activated carbon. II. Effects of gas temperature, gas pressure and sorbent regeneration. Carbon 38(13):1767–1774
Le Leuch LM, Subrenat A, Le Cloirec P (2005) Hydrogen sulfide and ammonia removal on activated carbon fiber cloth-supported metal oxides. Environ Technol 26(11):1243–1254
Subrenat A, Le Leuch LM, Le Cloirec P (2008) Electrodeposition of copper and iron oxides on to activated carbon fiber cloths: application to H2S and NH3 removal from air. Environ Technol 29(9):993–1000
Li H, Monnell JD, Alvin M, Vidic RD (2008) Factors affecting activated carbon-based catalysts for selective hydrogen sulfide oxidation. Main Group Chem 7(3):239–250
Bouzaza A, Laplanche A, Marsteau S (2004) Adsorption–oxidation of hydrogen sulfide on activated carbon fibers: effect of the composition and the relative humidity of the gas phase. Chemosphere 54(4):481–488
Steijns M, Derks F, Verloop A, Mars P (1976) The mechanism of the catalytic oxidation of hydrogen sulfide. II. Kinetics and mechanism of hydrogen sulfide oxidation catalyzed by sulfur. J Catal 42(1):87–95
Adib F, Bagreev A, Bandosz TJ (1999) Effect of pH and surface chemistry on the mechanism of H2S removal by activated carbons. J Colloid Interface Sci 216(2):360–369
Bagreev A, Rahman H, Bandosz TJ (2000) Study of H2S adsorption and water regeneration of coconut-based activated carbon. Env Sci Tech 34(21):4587–4592
Bashkova S, Baker FS, Wu X, Armstrong TR, Schwartz V (2007) Activated carbon catalyst for selective oxidation of hydrogen sulphide: on the influence of pore structure, surface characteristics, and catalytically-active nitrogen. Carbon 45:1354–1363
Arapu T, Lupascu T, Sandu M, Nastas R, Rusu V (2005) Oxidation of nitrites in natural waters in the presence of modified activated carbon. In Proceedings of SIMI 2005, (Bucharest, Romania), pp 180–185. (in Romanian)
Maroto-Valer MM, Dranca I, Lupascu T, Nastas R (2004) Effect of adsorbate polarity on thermodesorption profiles from oxidized and metal-impregnated activated carbons. Carbon 42(12–13):2655–2659
Maroto-Valer MM, Dranca I, Clifford D, Lupascu T, Nastas R, Leon y Leon (2006) Thermal regeneration of activated carbons saturated with ortho- and meta-chlorophenols. Thermochimica Acta 444:32–40
Adib F, Bagreev A, Bandosz TJ (2000) Analysis of the relationship between H2S removal capacity and surface properties of unmodified activated carbons. Environ Sci Technol 34(4):686–692
Bagreev A, Adib F, Bandosz TJ (2001) pH of activated carbon surface as an indication of its suitability for H2S removal from moist air streams. Carbon 39(12):1897–1905
Lippens BC, Linsen BG, de Boer JH (1964) Studies on pore systems in catalysts I. The adsorption of nitrogen; apparatus and calculation. J Catal 3(1):32
Brunauer S, Emmett PH, Teller F (1938) Adsorption of gases in multimolecular layers. J Am Chem Soc 60:309–319
Dranca I, Lupascu T, Nastas R (2003) Effect of oxidation and impregnation treatments on the pore structure and surface of active carbons derived from peach stones and coconut shells. In: The Ist international conference of the Moldovian Chemical society. Chisinau, Moldova, 6–8 oct 2003, Abstracts book, p 131
Boehm HP (1966) Chemical identification of surface groups. In: Eley DD, Pines H, Weisz PB (eds) Advances in catalysis, vol 16. Academic Press, New York, pp 179–274
Tcaci M, Himcinschi C, Nastas R, Petuhov O, Lupascu T, Zahn DRT (2011) Non-destructive characterization of modified activated carbon. Rev Chim (Bucharest) 62:727–731
Nastas R (2006) Specific surface properties of carbonaceous adsorbents. Dissertation, Institute of Chemistry of Academy of Sciences of Moldova
Clesceri LS, Greenberg AE, Eaton AD (eds) (1999) Standard methods for the examination of water and wastewater. 20th edn. American Public Health Association, Washington
Lupascu T, Nastas R, Ciobanu M, Arapu T, Rusu V (2005) Removal of hydrogen sulphide ammonia and nitrite ions from water solution using modified active carbons. In: Proceedings of third international conference “Ecological Chemistry”, Chisinau, Republic of Moldova, p 176–183
Rusu V, Nastas R, Giurginca M, Meghea A, Lupascu T (2007) Chemistry of carbonaceous adsorbents surface. In: Proceedings of SIMI 2007, Bucharest, Romania, p 140–145 (in Romanian)
Nastas R, Rusu V, Giurginca M, Meghea A, Lupascu T (2008) Alteration of chemical structure of the active vegetal coals. Rev Chim (Bucharest) 59(2):159–164 (in Romanian)
Bagreev A, Bandosz TJ (2002) A role of sodium hydroxide in the process of hydrogen sulfide adsorption/oxidation on caustic-impregnated activated carbons. Ind Eng Chem Res 41(4):672–679
Bagreev A, Bandosz TJ (2001) H2S adsorption/oxidation on unmodified activated carbons: importance of prehumidification. Carbon 39(15):2303–2311
Chen-Chia H, Chien-Hung C, Shu-Min C (2006) Effect of moisture on H2S adsorption by copper impregnated activated carbon. J Hazard Mater B 136:866–873
Nastas R, Rusu V, Lupascu T (2009) Synthesis and application of carbonaceous adsorbents obtained from fruit stones. In: Proceedings of SIMI 2009, Bucharest, Romania, p 290–295 (in Romanian)
Lupascu T, Nastas R, Ciobanu M, Arapu T, Rusu V (2005) Usage of modified active carbons for purification of natural waters. In: Proceedings of SIMI 2005, Bucharest, Romania, p 89–96
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer International Publishing Switzerland
About this chapter
Cite this chapter
Lupascu, T., Nastas, R., Rusu, V. (2014). Treatment of Sulfurous Waters Using Activated Carbons. In: Duca, G. (eds) Management of Water Quality in Moldova. Water Science and Technology Library, vol 69. Springer, Cham. https://doi.org/10.1007/978-3-319-02708-1_11
Download citation
DOI: https://doi.org/10.1007/978-3-319-02708-1_11
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-02707-4
Online ISBN: 978-3-319-02708-1
eBook Packages: Earth and Environmental ScienceEarth and Environmental Science (R0)