1. Introduction
Wastewater is generated from several sources and industries. Sewage wastewater is released in immense quantities from domestic facilities [
1]. In one instance, the increase in sewage wastewater reflects an increase in human population over time. Similarly, industrial zones also release huge quantities of wastewater. The oil and gas industry also releases enormous quantities of sour wastewater [
2]. Produced water (PW) is another stream generated during the drilling for oil in the oil fields [
3,
4,
5]. The fishing industry and sugarcane processing industries also produce large quantities of wastewater [
6]. These wastewater streams contain several pollutants, of which dissolved H
2S is one of the most serious [
7,
8].
Dissolved H
2S is also found in several natural water bodies, such as thermal springs and groundwater aquifers [
9,
10,
11]. Similarly, the presence of thiosulfate in the agricultural wastewater also results in the production of some quantities of dissolved H
2S in the revisers and lakes [
12,
13]. In addition, many industries, including paper and pulp, tannery products, catalytic cracking of crude oil, and the release of huge quantities of effluents laden with H
2S are also sources of dissolved H
2S in water bodies [
14,
15]. H
2S has also been known to be a cause of corrosion in pipelines that are used for water transmission. The oxidation of H
2S leads to the production of sulfuric acid in the pipelines, which promotes corrosion. Where H
2S is highly toxic to human beings, it also has a detrimental effect on aquatic life. Hence, different countries have set different limits for the release of dissolved H
2S in their water bodies. In this regard, the World Health Organization (WHO) has set 0.05 ppm as a permissible limit for drinking water and declared 10 ppm as toxic [
16].
Another cause of concern is the presence of H
2S in the feed of RO plants, leading to membrane fouling. In a study conducted by Kinser et al. [
17], it was found that H
2S is commonly found in the Florida aquifers and Lower Hawthorn aquifers. It has been determined that the major fouling of the RO membranes is caused due to elemental sulfur, sulfur oxides, and metal sulfides generated during the oxidation of H
2S, as shown in the following equation as per American Water Works Association (1990):
Hence, the presence of dissolved H
2S in the feed water is a cause for concern for the life and performance of the RO membrane. Basically, the chemistry of H
2S is highly dependent on the pH of the aqueous medium. Snoeyink and Jenkins equations for the dissociation of H
2S in water are given below in Equations (2) and (3):
It is clear from the above-mentioned equations that H2S dissociates in two ways. In the first step, the H2S gas is dissociated to generate bisulfide ions (HS−1), which are further dissociated into sulfide ions (S2−).
As the pH of the aqueous medium decreases below 7, the sulfide ion is present in the form of H
2S gas. However, as the pH increases, the H
2S is present in dissociated forms either as HS
−1 or S
−1. As the pH reaches the ambient pH of 7, 50% H
2S is present in the gas form while H
2S is almost completely converted into a bisulfide ion as pH reaches 9 to 10. However, as the pH reaches 11.8 to 12.0, the bisulfide and sulfide ions exist in equilibrium while at pH 13–14, the majority of the H
2S is converted into sulfide ions. These findings have been presented in the following
Figure 1.
It has been found that, at pH 5.1, H2S is 100 percent present in gas form. Hence, the pH of the feed at an RO plant is highly important as it determines the fate of the gases during permeation through the membranes. At a lower pH, gases such as H2S and CO2 can readily permeate through the RO membranes and, hence, require post-treatment for degasification of the product clean water. However, at higher pH values, the dissolved sulfide ions are rejected up to 93% by the RO membranes. Hence, depending on the pH of the stream, sulfide ions can be present either in the concentrate or permeate. Hence, based on the content of the dissolved oxygen, the sulfide ions are oxidized to elemental sulfur leading to membrane fouling as depicted in Equation (1), which is difficult to remove.
The undesirable components such as H
2S and CO
2 present in natural gas upon dissolution in water become exceedingly corrosive to the gas transmission system and compromise its integrity. Generally, conditioning is applied to mainly remove H
2S, CO
2, water and solids. However, H
2S being highly flammable, toxic, and heavier than air can accumulate at dangerous levels in pipes, valves, and tanks [
18]. The mere presence of 0.5 mg L
−1 of H
2S in the potable water is noticeable while 1.0 mg L
−1 of dissolved H
2S feels quite offensive. The rotten egg smell is also attributed to H
2S generated due to bacterial action on the sulfates present in the wastewater streams. The H
2S taste can be detected at a very low concentration of 0.05 mg L
−1 [
19]. H
2S is produced in wastewater through the microbial action of two commonly known bacterial strains, such as Desulfovbrio desulfuricans and Desulfotomaculum, which carry out the reduction of sulfates under anaerobic conditions [
20]. Similarly, other bacterial strains, such as Dimethylpolysulfides and Methylmercaptan, are also involved in production of sulfur-containing compounds. Many types of Pseudomonades are also responsible for producing sulfur-containing compounds [
21]. Hence, the presence of dissolved H
2S is highly deleterious to not only living beings, but also to wastewater treatment and transmission systems.
Given the huge significance of dissolved H2S as a cause of concern for not only the wastewater treatment facility, but also the community living nearby, there is a desperate need to separate and wisely use it for useful purposes. Several reports have been published in the literature regarding the separation of dissolved H2S from wastewater streams. Researchers have explored the potential of membranes, H2S scavengers, and other relevant technologies to remove and recover the dissolved H2S from wastewater streams. Most of the reviews published in the literature have primarily focused on the separation of H2S gas from a gaseous mixture. Hence, the current review has covered the literature related to the removal of dissolved H2S from wastewater.
2. Approaches to Treat H2S
Among the several industries affected by H
2S, the oil and gas industry is highly impacted by the presence of H
2S gas due to its toxicity and, above all, the corrosion of the pipelines during the transmission of the gases [
22]. In order to get rid of H
2S (gas sweetening), certain chemical scavengers, such as triazine-based compounds, are added to the feed to convert the H
2S into organic molecules containing S 1,3,5-tri(2-hydroxyethyl)hexahydro-S-traizine (HET), which is added to the H
2S gas stream as a basic solution to absorb H
2S and convert it into non-harmful products. As demonstrated in the following
Figure 2, two nitrogen atoms of HET are replaced by S atoms of H
2S, yielding the chemically essential byproduct monoethanolamine and spent HET called 5-(2-hydroxyethyl)hexahydro-1,3,5-dithiazine (DTZ) [
23,
24].
HET is generally added in excess equivalence in comparison to H2S, which ensures the complete degradation of H2S so that H2S concentration reaches permissible discharge limits as per the regulations of government agencies. Although HET is an effective H2S scavenger that has been efficiently used during the treatment of wastewater of offshore oil and gas facilities, HET and its byproducts (MEA and DTZ) are considered environmental hazards that must be removed by the discharge of the treated effluent into the environment.
To understand the chemistry and fate of the byproducts, a detailed study on the mechanism of the triazine scavenging reaction was carried out. This study also proposed chemical means for the removal of scavenger byproducts. In fact, the scavenger initial byproducts lead to the formation of heavy and insoluble deposits that become difficult to remove. The scavenger byproduct deposits are shown below in
Figure S1 [
25].
Therefore, a thorough understanding of the chemistry and mechanism of the formation of these byproducts was studied. Generally, it is believed that the byproduct is 1,3,5-triatiane, in which all the nitrogen atoms of triazine ring are replaced by S atoms [
18,
26,
27]. However, it has been established in the literature that the actual byproduct generated is dithiazine not 1,3,5-triatiane. Hence, the deposits seen are basically dithiazine.
Figure S2 shows the mechanism of reaction of triazine scavengers. Protonation of the nitrogen atom generates the site for the nucleophilic substitution reaction of bisulfide (HS
-). The electronegativity of the two nitrogen atoms linked with carbon atoms generate an electropositive carbon atom in the triazine molecule. The existence of an electron deficient carbon atom is an ideal site for a nucleophilic substitution reaction with HS
-. Upon the nucleophilic substitution (SN
2) reaction with HS
-, an amine molecule is released as a leaving group. The resultant compound of the first SN
2 reaction produces thiadiazene (
Figure S2a). The second SN
2 reaction produces the dithiazine that has two sulfur atoms and one nitrogen atom (
Figure S2b). The GC-MS analysis of the reaction mixture showed the presence of dithiazine. However, no evidence was collected showing the existence of 1,3,5-trithiazine. The possibility of a nucleophilic attack of HS
- on the dithiazine ring is not possible and, hence, the 1,3,5-trithiazine ring is not formed as a byproduct. This possibility of a reduced attack arises since a carbon atom is not connected to two adjacent nitrogen atoms in dithiazine. Instead, a carbon atom is linked with one nitrogen and one sulfur atom, and hence, the carbon atom is not as electron-deficient as in thiadiazine. Hence, the attack of HS
- on dithiazine is not possible, as shown in
Figure S2c. Molecular electrostatic potential (MEP) measurements showed the presence of a more positive charge on carbon in the presence of a nitrogen atom. Upon the inclusion of a sulfur atom, the positive charge is reduced, and hence, the nucleophilic substitution reaction is not possible (
Figure S2d) [
28].
Similarly, further investigations have shown that the use of ethanol amine has potentially resulted in the generation of amorphous polymeric dithiazine (apDTZ) starting from dithiazine. Various methods have been developed, including the use of cosolvents and hydrogen peroxide. However, these methods have not proved sufficient to remove the apDTZ. However, the use of organic per(oxy) acids has proven highly efficient for removing the apDTZ. The use of per(oxy) acetic acid has also emerged, leading to the digestion of insoluble polymeric apDTZ. It has been found that the S in apDTZ is destined for SO42−, whereas the carbon is converted into formic acid and formats.
Hence, M.N. Fini et al. used a hybrid membrane system consisting of nanofiltration (NF) and reverse osmosis (RO) membranes to reduce the total organic content (TOC) of spent and unspent scavenger (SUS) wastewater. The NF270 membrane was able to reduce TOC up to 65% with separation of HET from DTZ with 70% removal of HET and zero removal of DTZ. Then, the permeation of NF270 was used as a feed for the XLE RO membrane where the effluent stream was discharged with a 98% removal of TOC [
24]. The same group also fabricated a thin film composite (TFC) polyamide membrane through interfacial polymerization (IP) by using a mixture of meta-phenylenediamine (MPD) and dopamine hydrochloride (DA) as an aqueous phase while trimesoyl chloride (TMC) as the non-aqueous phase. The membrane MPD-DA/TMC polyamide active layer was deposited on the polysulfone (PSf)/polyethylene terephthalate (PET) support. The following
Figure 3a shows the schematic representation of IP for membrane fabrication along with structural (
Figure 3b–d) features and filtration performance (
Figure 3e–g).
Figure 3a shows the wet phase inversion followed by IP between MPD-DA and TMC solutions while
Figure 3b shows a SEM micrograph of PET where the fibers of PET can be clearly seen. After the phase inversion, the PSf layer covered the PET support (
Figure 3c), which has a highly microporous structure. However, after IP, the polyamide active layer showed a completely altered surface morphology with a highly dense layer, leading to a polyamide TFC membrane. Afterward, the performance of the membranes was tested to remove the by-products of dissolved H
2S scavengers, such as HET, MEA, and DTZ.
Figure 3e shows the effect of membrane thickness on the rejection and permeability of the membrane. As the membrane thickness increases, the permeability decreases, which can be attributed to the increased mass transfer resistance during the permeation of water through the membranes. However, the rejection increases with increasing membrane thickness, reaching maximum rejection at 100 µm and 200 µm. The MPD-DA/TMC membrane showed a rejection of 62% HET and 82% MEA with no rejection of DTZ while the commercial nanofiltration membrane NF270 showed a rejection of HET 56% and MEA 43% and 4%, respectively.
Figure 3g shows the rejection performance of 100 µm membrane when separate solutions of each pollutant were used during filtration experiments [
29].
Although HET has shown a huge potential for removing dissolved H2S from wastewater, the removal of by-products, such as DTZ and MEA containing removed H2S, needs a highly dense membrane. Similarly, other methods to treat dissolved H2S, such as the use of oxidizing agents, such as oxygen, hydrogen peroxide, hypochlorite, and chlorine, result in the production of hazardous by-products. Hence, alternative ways of treating dissolved H2S are being explored by the research community. In one such effort, G.K. Agrahari et al. used hollow fiber membrane contactors (HFMCs) to remove dissolved H2S from wastewater streams. The removal of dissolved H2S was based on the principle of interphase mass transfer. Interphase mass transfer offers high contact between the two phases without mixing, which maximizes the transfer of the dissolved H2S from the wastewater streams to the permeate side. The pressure drops between the two independently flowing phases are also minimal. Furthermore, the ease of operation, highly compact design, ease of flow controls along with low cost, and small footprint make the HFMC technique a potential technology for treating dissolved H2S.
Figure 4 shows an illustration explaining the steps responsible for the removal of dissolved H
2S from the feed using HFMC. The hollow fiber membrane was fabricated using polypropylene (PP) as a hydrophobic membrane [
30] with microspores in the matrix of the membrane. During the H
2S removal experiment, the H
2S-laden feed water was passed through the lumen of the hollow fiber while the monethanolamine (MEA) solution was used as an extractant on the shell side, flowing in a countercurrent manner to the feed. The dissolved H
2S is desorbed from the feed and enters the pores of the PP membrane. Hence, the dissolved H
2S is separated from the aqueous phase and enters the polymeric phase. The wetting of the membrane with water is negligible as PP is a hydrophobic polymer. The dissolved H
2S is desorbed from the feed and adsorbed onto PP, and hence, the transfer of H
2S from feed to extractant is dependent upon the adsorption–desorption of H
2S inside the micro pores of PP. On the extractant side, a rapid reaction occurs between MEA and H
2S, and hence, the concentration of H
2S on the feed’s side decreases and reaches equilibrium with the extractant [
31].
Hence, the use of HFMC with a hydrophobic membrane proved to be highly useful for removing dissolved H
2S from the wastewater. The concentration of dissolved H
2S in the feed ranged from 300 ppm to 1600 ppm. The HFMC reached a removal efficiency of 98%. The following
Figure 5 shows the flow diagram of the HFMC membrane testing system.
In a similar work, Minier-Matar et al. also used membrane contactors for removing dissolved H
2S from the sour water stream obtained from a natural gas onshore processing facility with an S
2− ion concentration of 100 mg L
−1. A hollow fiber polypropylene (PP) crossflow membrane module was used in this study. The membrane module was installed in the custom-made filtration system shown below in
Figure 6.
Figure 6 shows that the hollow fiber membranes were supplied with a sour water feed containing dissolved H
2S, where sulfuric acid was used to keep an acidic pH in the feed tank while NaHCO
3 was used to study the impact of CO
2 on the removal of dissolved H
2S from the feed tank. A NaOH-receiving solution was flown in a counter-current manner for removing dissolved H
2S and the subsequent reaction yielding Na
2S, which is a harmless species, and its concentration was measured to know the S
2− ion concentration in the receiving solution.
As the membrane in the current study was hydrophobic in nature and the temperature on both the feed side and the receiving solution side was the same, which ensured that unlike membrane distillation (MD), no water vapors were permeated through the PP membrane. Hence, membrane contactors do not allow water but only H
2S to transfer through the pores of the PP membrane. Minier-Matar et al. also studied the kinetics of mass transfer of H
2S through a PP membrane and found that the transfer of the H
2S from a sour-water boundary was the rate limiting step. In addition, different parameters, such as effect of S
2− ion concentration, feed pH, temperature, and fouling studies, were also carried out as given in the following
Figure 7. The mass transfer co-efficient “K” was determined for different initial concentrations of dissolved H
2S, which were 50 mg L
−1, 100 mg L
−1, and 250 mg L
−1 at a pH of 4 to ensure that all dissolved S
2− ions was in the form of H
2S. The calculations found values of K as 0.240, 0.246, and 0.243 cm min
−1 for 50 mg L
−1, 100 mg L
−1, and 250 mg L
−1, respectively. The findings revealed that the mass transfer co-efficient was independent of initial concentrations of dissolved H
2S (
Figure 7a). In the case of pH effect, the removal of H
2S was found to 100% cat pH 4 compared to pH of 7 (
Figure 7b). In case of increasing temperature of the feed, the mas transfer was found to be exponentially increasing (
Figure 7c). The fouling performance of the PP membrane was also studied by using a feed of 2 g L
−1 of dissolved H
2S where it was found that the mass transfer co-efficient was decreased by 8% owing to the fouling of the membranes (
Figure 7d) [
32].
In a similar application, Silva et al. used membrane distillation (MD) for removing H
2S from the permeate of an anaerobic bioreactor. Although an anaerobic membrane bioreactor has proven efficient in producing high-quality effluent with a tolerance for variation in feed quality; one of the disadvantages is treating the wastewater rich in sulfates and organic matter. Since the concentration of sulfates and organic matter is higher in the feed, the sulfate-reducing bacteria can use sulfate as a substrate resulting in the production of H
2S. Hence, the removal of dissolved H
2S is required to reuse the water. Hence, the Silva group designed a modified direct contact membrane distillation (M-DCMD) configuration for removal of dissolved H
2S from the real wastewater (
Figure 8). The real wastewater was the permeate of the two-stage anaerobic membrane bioreactor (2S-AnMBR). The dissolved H
2S (166 ± 15 mg/L
−1)-containing permeate was generated due to the anaerobic biological digestion of sugarcane vinasse collected from the local company. The following M-DCMD system having a polypropylene (PP) hollow fiber membrane was used for removing H
2S. In this M-DCMD system, the dissolved H
2S feed was passed through the lumen of the hollow fiber membrane while a cold NaOH-receiving solution was passed on the shell side of the membrane. As PP is a super-hydrophobic material in nature, the entry of water into the membrane pores is not possible. H
2S speciation at different pH values affects the solubility of H
2S in the feed, which affects the content of S
−2 ions in the feed, and hence, the removal of dissolved H
2S from water is dependent upon the pH of the feed solution. At pH 4, 100% of H
2S is present in a gaseous state, which increases the removal rate of H
2S (
Figure 8b). However, as the pH increases from 6 to 9, the H
2S gets dissolved in water and is found in dissolved S
−2 form. Hence, the flux of H
2S was found to be 0.00638, 0.00340, and 0.00109 Kg H
2S m
−2 h
−1 at pH 4, 6.5, and 9, respectively.
An elaboration of the structure of the PP hollow fiber membrane is given in the inset in
Figure 8a, which shows how the hydrophobic PP membrane acts as a separation between the H
2S-containing feed and the NaOH-receiving solution. The PP membrane being hydrophobic does not allow the water to pass through the membrane from either solution while H
2S diffuses from the feed to the receiving solution. Moreover, the two solutions move in a counter-current manner, which increases the rate of removal of H
2S from the wastewater stream [
33]. M-DCMD uses a hot feed at 50 °C compared to membrane contactors, which do not involve a hot feed and instead operate at room temperature.
Like other wastewater streams, the permeate of the anaerobic membrane bioreactor has also been identified to possess considerable quantities of dissolved H
2S in addition to dissolved CH
4. In the case of the anaerobic digestion of sludge, sulfate-reducing bacteria take over methanogenic bacteria, leading to the production of H
2S. Since H
2S has high water solubility, it is found in a dissolved form in the permeate, causing a foul smell, corrosion, SOx production, and toxicity. It has been reported that a concentration of 60 mg L
−1 of H
2S can cause an irreversible process failure of both acetate-fed and propionate-fed chemostats in an anaerobic digester [
34]. Although hydrophobic degassing membranes have been found to be highly useful for removing dissolved gases, some issues, such as mass transfer resistance and membrane fouling, need to be optimized. Hence, there is a need for discovering innovative and more promising routes and techniques for removing dissolved H
2S. In one such effort, E. Lee et al. developed a staged vacuum-based degasifier system for removing dissolved gases, including H
2S from the permeate of a staged anaerobic fluidized membrane bioreactor (SAF-MBR) as given in the following
Figure 9. Three stainless steel chambers are connected in a series with the vacuum pump, and the influent is entered in chamber 1 at stage 1 in the form of a spray through a nozzle at 15 mL s
−1 sequentially. A vacuum of −0.8 bar was applied across the chamber by the vacuum pump.
The degasifier system resulted in a considerable decrease in the concentration of pollutants as the COD was recorded to decrease as the influent was moved from stage 1 to stage 3. In the case of the pH-regulated stream, the removal was found to be higher than the raw stream. Similarly, the removal efficiency of H
2S was found to increase while moving from stage 1 to 2 and finally to stage 3. As the pH decreases and moves towards an acidic region, the H
2S removal efficiency increases as shown in
Figure 10. The removal of H
2S reached 88% with pH-adjusted samples. This study found that dissolved H
2S removal was governed by factors, such as pH, contact time, temperature, turbulence of the liquid phase, and equilibrium constant [
35].