Metallic Iron for Environmental Remediation: Comparison
Please note this is a comparison between Version 2 by Peter Tang and Version 1 by Chicgoua Noubactep.

Metallic iron (Fe0) used as a reactive material in subsurface permeable reactive barriers is comparable to iron pipes with three major differences: (i) corrosion is welcome because it is a rather useful process [7,8,9][7][8][9], (ii) a reactive wall is ideally permanently water saturated, and (iii) the length of used particles (< 5 cm) is tiny compared to pipes which are up to 12 m in length. On the one hand, Fe0 specimens used in water treatment comprise steel wool with thickness varying between 25 and 90 μm [10,11][10][11]. On the other hand, the length of these particles is comparable to the wall thickness of iron pipes (2–4 mm). There has been no real system analysis for remediation Fe0 materials with the aim to outline the differences making their peculiar characteristics. In addition, traceably deriving the longevity of remediation Fe0 specimens from Fe0 pipes is impossible because of the differences highlighted.

  • Metallic Iron

1. Introduction 

Metal corrosion is one of the most important problems in industry, transport and agriculture [1,2,3,4][1][2][3][4]. Understanding metal corrosion comprises its detection (e.g., analytical, visual), its monitoring (e.g., mass loss, H2 evolution) and its long-term characterization under various field conditions [4,5][4][5]. The corrosion research aims at determining the durability of metallic structures under operational conditions (e.g., oil and gas pipelines, tanks) and revealing the mechanisms of corrosion process [5,6][5][6]. This mechanism can be chemical, electrochemical or mixed [1]. Various tools have been used to characterize the corrosion resistance of different metals under various application conditions [4]. The overall result is the availability of integrated approaches to assess and predict the corrosion processes and thus the longevity of metallic structures (e.g., buried pipes) [3,4][3][4]. However, the frequency and sudden nature of metallic pipe failures worldwide indicate the inadequacy of current knowledge related to the longevity of buried metallic pipes.

Metallic iron (Fe0) used as a reactive material in subsurface permeable reactive barriers is comparable to iron pipes with three major differences: (i) corrosion is welcome because it is a rather useful process [7[7][8][9],8,9], (ii) a reactive wall is ideally permanently water saturated, and (iii) the length of used particles (< 5 cm) is tiny compared to pipes which are up to 12 m in length. On the one hand, Fe0 specimens used in water treatment comprise steel wool with thickness varying between 25 and 90 μm [10,11][10][11]. On the other hand, the length of these particles is comparable to the wall thickness of iron pipes (2–4 mm). There has been no real system analysis for remediation Fe0 materials with the aim to outline the differences making their peculiar characteristics. In addition, traceably deriving the longevity of remediation Fe0 specimens from Fe0 pipes is impossible because of the differences highlighted.

The remediation Fe0 was termed as zero-valent iron (ZVI). This acronym is perhaps the first problem of this still innovative technology. A literature research with “zero-valent iron” as keyword would never reveal the ancient literature on Fe0 for water treatment [12,13,14,15,16][12][13][14][15][16]. Indeed, no research group until 2017 has referenced a single article from the ancient use of Fe0 in water treatment [17,18][17][18]. In chemistry, metallic elements are characterized by their oxidation state, the one of Fe0 is zero (0). Upon oxidation, Fe0 is transformed to FeII, FeIII or FeIV species. Under environmental conditions, only FeII and FeIII species are stable. The oxidation of Fe0 to FeII is a redox process characterized by an electrode potential whose value is –0.44 V [1]. According to the first principle of chemical thermodynamics, Fe0 can be oxidized by oxidizing agents from each redox couple having a higher electrode potential (E0 > –0.44 V). Water (H2O or H+) is a relevant oxidizing agent for Fe0 under environmental conditions. The electrode potential for the redox couple H+/H2 is 0.00 V. Fe0 immersed in (contaminated or polluted) water is corroded to form H/H2 and FeII (and mixed FeII/FeIII) species which are stand-alone reducing agents [19,20,21,22,23,24,25,26][19][20][21][22][23][24][25][26]. Clearly, it is not surprising that selected species undergo reductive transformations in an Fe0/H2O system [19,26,27,28,29][19][26][27][28][29].

2. The Fe0/H2O System

2.1. Overview of Fundamental Aspects

There is a transfer of electrons from the Fe0 body (solid state) to the Fe0/H2O interface whenever a piece of a reactive Fe0 specimen is immersed in an aqueous solution (Fe0/H2O system) [1,5,6,76][1][5][6][30]. This occurs because Fe0 is not stable under environmental conditions or because the redox couple H+/H2 (E0 = 0.00) is higher than that of FeII/Fe0 (E0 = –0.44) in the electrochemical series [1,22,23,24,25,26][1][22][23][24][25][26].

2.2. Oxide Scale on Fe0 and the Decontamination Process

A look at the mechanism of oxide scale formation reveals that it cannot be electronically conductive. In fact, the initial scale is very porous and cannot transfer electrons because air and water are not electronically conductive (an aqueous solution can be ionic conductive—electrolyte). In subsequent stages, available pores are filled with nascent FeCPs, but they are never uniform and the oxide scale is a mixture of iron hydroxides and oxides [5]. An oxide scale made up of Fe3O4 alone would have been electronically conductive. However, such an Fe3O4 scale cannot exist under natural conditions (immersed Fe0). All other FeCPs are at best semi-conductors and cannot relay electrons from Fe0 under natural conditions. Clearly, reports justifying the reductive efficiency of Fe0/H2O systems using the semi-conductive nature of FeCPs are mistaken [96][31]. This assertion encompasses the Fe0/pyrite/H2O system, whose efficiency is mainly justified by the semi-conductive nature of FeS species [97,98,99][32][33][34].

The oxide scale on Fe0 is definitively a diffusion barrier for all dissolved species, including the pollutants. It is also the contaminant scavenger such that electrochemical corrosion of immersed Fe0 induces the generation of contaminant scavengers and other reducing agents. Thus the generation of solid FeCPs is a necessary process which has the (perceived negative) side effect of being expansive. Thus, designing an efficient and sustainable system requires answering the question: how long can FeCPs be generated to satisfactorily treat water while keeping a reasonable hydraulic conductivity (permeability)?

2.3. Chemical Aspects

Fe2+ from Equation 1 is transformed to ferrous hydroxide (Fe(OH)2) and ferric hydroxide (Fe(OH)3) which have a strong tendency to form colloids of particles that normally carry a positive charge [62,100,101][35][36][37]. These minerals are further transformed to other FeII/FeIII minerals (e.g., Fe2O3, FeOOH, green rust) exhibiting different affinities to dissolved species. The nature of oxides in each individual system depends on the intrinsic reactivity of the used Fe0 material and the environmental conditions [5,79][5][38]. For example, two different Fe0 specimens corroding under the same environment will not necessarily produce the same iron oxides, because the composition of the oxide scale depends on the relative kinetics of Fe0 dissolution and Fe hydroxide precipitation, which in turn depends on the solution chemistry, including the pH value, dissolved ions and the salinity [5,6,102][5][6][39]. On the other hand, in-situ generated free Fe2+ are adsorbed to the surface of available minerals to form the so-called structural FeII with a reducing power far larger than that of the free Fe2+ (E0 < 0.77 V) and sometimes stronger than Fe0 (E0 < –0.44 V) [103][40]. The availability of several reducing agents in the Fe0/H2O system, and especially from structural FeII, partly stronger than Fe0 implies that the electrochemical series of metal alone cannot predict the chemistry of the system.

2.4. Physical Aspects

The volumetric expansive nature of iron corrosion is the most important physical phenomenon occurring in Fe0/H2O systems [104][41]. There is expansion because the parent metal (Fe0) produces in-situ both: (i) H2, occupying a volume about 3100 times larger [26[26][42],105], and (ii) each solid oxide and hydroxide is at least twice larger in volume than Fe0 (Voxide > Viron) [106,107][43][44]. For example, the specific density of magnetite (Fe3O4) is about one half that of iron (Fe0). It implies that after corrosion a space twice larger than the initial space is occupied [108,109,110][45][46][47]. While it can be assumed that H2 escapes from each open system, no free expansion of oxides in porous systems (e.g., water filters, reactive walls) can be assumed [26]. External or internal free expansion occurs in metallic pipes [111,112][48][49] and on the walls of steel canister for radioactive waste repositories [110,113][47][50]. On the contrary, free expansion cannot be expected in steel-reinforced concrete structures [108,109][45][46]. Accordingly, considering expansive iron corrosion, which culminates into permeability loss is an essential design parameter for porous Fe0/H2O systems (Fe0 filters). For each Fe0 filter, the temporal production of both H2 and oxide is decisive for the long-term efficiency and the permeability of the system [105,107,114,115][42][44][51][52].

2.5. Kinetic Aspects

Aqueous corrosion of Fe0 materials under environmental conditions (pH > 4.5) is an electrochemical process involving iron dissolution at the anode and H2 evolution at the cathode (Equation 1). This electrochemical reaction is accompanied by the formation of an oxide scale on Fe0 which is not protective as a rule [6,116,117,118][6][53][54][55]. In general, oxide scale growth and its protectiveness depend primarily on the precipitation rate of iron hydroxides [5,102][5][39]. As the Fe0 surface corrodes under the initial scale, corrosion continuously undermines the scale. Voids are created and are progressively filled up by the ongoing hydroxide precipitation. The relative rate of (i) Fe0 oxidative dissolution and (ii) hydroxide precipitation in the Fe0 vicinity determine the protectiveness of the oxide scale. According to Nesic [5], when the rate of hydroxide precipitation exceeds the rate of Fe0 dissolution, a dense protective oxide scale is formed. Conversely, when Fe0 dissolution undermines the new oxide scale faster than hydroxide precipitation can fill in the voids, a porous and non-protective scale forms.

2.6. Investigating the Fe0/H2O System

A Fe0/H2O system is made up of two interfaces: (i) Fe0/oxide and (ii) oxide/H2O. Because the oxide scale is never electronically conductive and is a diffusion barrier to many species, only water can quantitatively reach the Fe0 surface. The net result is that Fe0 oxidative dissolution is an electrochemical reaction (water is reduced) but all other observed/reported chemical reduction occur within the oxide film or at the oxide/H2O interface [53,54,127][56][57][58]. For the Fe0/H2O remediation system, it means that contaminants are not reduced by electrons from Fe0. This has important implications on the operating principles of Fe0/H2O systems: first, using the electrochemical series to predict the reductive transformation of any species has been a mistake, and second, using the stoichiometry of any electrochemical reaction involving Fe0 is also a mistake. Accordingly, contaminants are ‘just’ dissolved species, capable of modifying: (i) the conductive properties of the electrolyte (H2O), (ii) the ion conductivity of the oxide scale, and (iii) formation and the transformation of the oxide scale. Experiments pertaining to filtration systems must be performed under conditions enabling the formation of an oxide scale on the vicinity of Fe0 (e.g. quiescent batch experiments). For all other systems (e.g. fluidized systems), field dynamics (e.g. shaking intensity) must be reproduced during testing.

3. Selection and Characterization of Fe0 Materials

As discussed above, the scientific reason for using all Fe0 materials (e.g., granular iron and bimetallics, iron filings, iron nails, iron wire, nano-Fe0, scrap iron, steel wool) in water treatment is the electrode potential of the redox electrode FeII/Fe0: E0 = −0.44 V. Clearly, all reactive Fe0 materials have the same redox potential. The intrinsic reactivity of individual Fe0 specimens depends on a myriad of factors from which some are not readily accessible to the researcher. Relevant influencing factors include: alloying elements, Fe0 form, manufacturing processes, metallography, Fe0 grain size, surface area, and surface oxidation state. Accordingly, each Fe0 material has its own intrinsic reactivity which should be characterized in order to better understand how it is influenced by operational conditions to induce the intended remediation goal.

The long history of using Fe0 for technical chemical applications, including water treatment reveals that there has always been efforts to select appropriate materials for individual applications. For example, the porous “spongy iron” (sponge iron or direct reduced iron) was proven more suitable in filtration systems than dense materials [12,13,168][12][13][59]. Similarly, multi-metallic systems and nanoscale materials were recently developed to address (recalcitrant) contaminants that were less sensitive to treatment with granular materials [169][60]. For completeness, it should be stated that there is no Fe0 material for all situations such that one should rationally select appropriate materials for each specific application. For example, while treating water in fluidized systems (Anderson Process), dense materials were better than sponge iron [13,168][13][59]. Similarly, Hildebrant et al. [140][61] reported that Fe0 materials of low reactivity according to the EDTA test exhibited a better efficiency for fluoride removal. The question arises how to select the right Fe0 specimen for a given application? This calls for the development of standardized protocols for selection and characterization of Fe0 materials for various applications.

4. Conclution

The corrosion of iron in remediation Fe0/H2O systems is an electrochemical process, coupling Fe0 oxidative dissolution to the reduction of water (protons) and to no other available oxidizing agent, including dissolved O2. This is because the universal oxide scale on Fe0 acts as diffusion barrier to dissolved species and a conduction barrier to electrons from the metal body. In other words, water is the sole chemical which can remove electrons from the Fe0 surface. Fe0 oxidation and water reduction must not necessarily occur at the same locality. The spatial separation of oxidative (anodic) and reductive (cathodic) reactions is possible as the metal body allows the free flow of electrons from anodic to cathodic sites. The tendency of Fe0 to give off electrons (Equation 1) is the same for all Fe0-based materials (E0 = –0.44 V). This makes material selection and characterization critical in designing sustainable Fe0/H2O systems.

References

  1. Landolt, D. Corrosion and Surface Chemistry of Metals, 1st ed.; EPFL Press: Lausanne, Switzerland, 2007; p. 615.
  2. Enning, D.; Garrelfs, J. Corrosion of iron by sulfate-reducing bacteria: New views of an old problem. Appl. Environ. Microbiol. 2014, 80, 1226–1236.
  3. Wasim, M.; Shoaib, S.; Mubarak, M.N.; Inamuddin Asiri, A.M. Factors influencing corrosion of metal pipes in soils. Environ. Chem. Lett. 2018, 16, 861–879.
  4. Enikeev, M.R.; Potemkin, D.I.; Enikeeva, L.V.; Enikeev, A.R.; Gubaydullin, I.M. Quantification of non-uniform distribution and growth of corrosion products at steel-concrete interface Analysis of corrosion processes kinetics on the surface of metals. Chem. Eng. 2020, 383, 123–131.
  5. Nesic, S. Key issues related to modelling of internal corrosion of oil and gas pipelines—A review. Corros. Sci. 2007, 49, 4308–4338.
  6. Lazzari, L. General Aspects of Corrosion, Chapter 9.1, Vol. V; Encyclopedia of Hydrocarbons, Istituto Enciclopedia Italian: Rome, Italy, 2008.
  7. Wilson, E.K. Zero-Valent metals provide possible solution to groundwater problems. Chem. Eng. News 1995, 73, 19–22.
  8. Fairweather, V. When toxics meet metal. Civ. Eng. 1996, 66, 44–48.
  9. Tratneyk, P.G. Putting corrosion to use: Remediating contaminated groundwater with zero-Valent metals. Chem. Ind. 1996, 13, 499–503.
  10. Hildebrant, B. Characterizing the reactivity of commercial steel wool for water treatment. Freib. Online Geosci. 2018, 53, 1–80. doi:10.13140/RG.2.2.15181.90083.
  11. Lufingo, M.; Ndé-Tchoupé, A.I.; Hu, R.; Njau, K.N.; Noubactep, C. A novel and facile method to characterize the suitability of metallic iron for water treatment. Water 2019, 11, 2465.
  12. Bischof, G. The Purification of Water: Embracing the Action of Spongy Iron on Impure Water; Bell and Bain: Glasgow, Scotland, 1873; p. 19.
  13. Devonshire, E. The purification of water by means of metallic iron. J. Frankl. Inst. 1890, 129, 449–461.
  14. Tucker, W.G. The purification of water by chemical treatment. Science 1892, 20, 34–38.
  15. Baker, M.N. Sketch of the history of water treatment. J. Am. Water Works Assoc. 1934, 26, 902–938.
  16. van Craenenbroeck, W. Easton & Anderson and the water supply of Antwerp (Belgium). Ind. Archaeol. Rev. 1998, 20, 105–116.
  17. Mwakabona, H.T.; Ndé-Tchoupé, A.I.; Njau, K.N.; Noubactep, C.; Wydra, K.D. Metallic iron for safe drinking water provision: Considering a lost knowledge. Water Res. 2017, 117, 127–142.
  18. Noubactep, C. Metallic iron for water treatment: Lost science in the West. Bioenergetics 2017, 6, 149.
  19. Gould, J.P. The kinetics of hexavalent chromium reduction by metallic iron. Water Res. 1982, 16, 871–877.
  20. Noubactep, C. Untersuchungen zur passiven in-situ-Immobilisierung von U(VI) aus Wasser. Akad. Buchh., TU Bergakademie Freiberg: Freiberg , Germany, 2003 (ISSN: 1433-1284). 2003.
  21. Chaves, L.H.G. The role of green rust in the environment: A review. Rev. Bras. Eng. Agríc. Ambient. 2005, 9, 284–288.
  22. Gheju, M. Hexavalent chromium reduction with zero-valent iron (ZVI) in aquatic systems. Water Air Soil Pollut. 2011, 222, 103–148.
  23. Ghauch, A. Iron-based metallic systems: An excellent choice for sustainable water treatment. Freib. Online Geosci. 2015, 38, 1–80.
  24. Hu, R.; Cui, X.; Gwenzi, W.; Wu, S.; Noubactep, C. Fe0/H2O systems for environmental remediation: The scientific history and future research directions. Water 2018, 10, 1739.
  25. Hu, R.; Noubactep, C. Redirecting research on Fe0 for environmental remediation: The search for synergy. Int. J. Environ. Res. Public Health 2019, 16, 4465.
  26. Hu, R.; Gwenzi, G.; Sipowo, R.; Noubactep, C. Water treatment using metallic iron: A tutorial review. Processes 2019, 7, 622.
  27. Anderson, M.A. Fundamental Aspects of Selenium Removal by Harza Process; Rep San Joaquin Valley Drainage Program; US Department of the Interior: Sacramento, CA, USA, 1989.
  28. Myneni, S.C.B.; Tokunaga, T.K.; Brown, G.E., Jr. Abiotic selenium redox transformations in the presence of Fe(II,III) oxides. Science 1997, 278, 1106–1109.
  29. Jiao, Y.; Qiu, C.; Huang, L.; Wu, K.; Ma, H.; Chen, S.; Ma, L.; Wu, L. Reductive dechlorination of carbon tetrachloride by zero-valent iron and related iron corrosion. Appl. Catal. B Environ. 2009, 91, 434–440.
  30. Hammonds, P. An Introduction to Corrosion and its Prevention (Chapter 4). Compr. Chem. Kinet. 1989, 28, 233–279.
  31. Yoshino, H.; Kawase, Y. Kinetic modeling and simulation of zero-valent iron wastewater treatment process: Simultaneous reduction of nitrate, hydrogen peroxide, and phosphate in semiconductor acidic wastewater. Ind. Eng. Chem. Res. 2013, 52, 17829–17840.
  32. Du, M.; Zhang, Y.; Hussain, I.; Du, X.; Huang, S.; Wen, W. Effect of pyrite on enhancement of zero-valent iron corrosion for arsenic removal in water: A mechanistic study. Chemosphere 2019, 233, 744–753.
  33. Lü, Y.; Li, J.; Li, Y.; Liang, L.; Dong, H.; Chen, K.; Yao, C.; Li, Z.; Li, J.; Guan, X. The roles of pyrite for enhancing reductive removal of nitrobenzene by zero-valent iron. Appl. Catal. 2019, 242, 9–18.
  34. Chen, K.; Han, L.; Li, J.; Lü, Y.; Yao, C.; Dong, H.; Wang, L.; Li, Y. Pyrite enhanced the reactivity of zero valent iron for reductive removal of dyes. Chem. Technol. Biotechnol. 2020. doi:10.1002/jctb.6326.
  35. Phukan, M. Characterizing the Fe0/sand system by the extent of dye discoloration. Freib. Online Geosci. 2015, 40, 1–70.
  36. Sato, N. Surface oxides affecting metallic corrosion. Corros. Rev. 2001, 19, 253–272.
  37. Phukan, M.; Noubactep, C.; Licha, T. Characterizing the ion-selective nature of Fe0-based filters using three azo dyes in batch systems. J. Environ. Chem. Eng. 2016, 4, 65–72.
  38. van Genuchten, C.M.; Behrends, T.; Stipp, S.L.S.; Dideriksen, K. Achieving arsenic concentrations of <1 μg/L by Fe(0) electrolysis: The exceptional performance of magnetite. Water Res. 2020, 168, 115–170.
  39. Whitman, W.G. Corrosion of iron. Chem. Rev. 1926, 2, 419–435.
  40. White, A.F.; Peterson, M.L. Reduction of aqueous transition metal species on the surfaces of Fe(II)-containing oxides. Geochim. Cosmochim. Acta. 1996, 60, 3799–3814.
  41. Pilling, N.B.; Bedworth, R.E. The oxidation of metals at high temperatures. J. Inst. Metals 1923, 29, 529–591.
  42. Noubactep, C. Metallic iron for environmental remediation: Prospects and limitations. In A Handbook of Environmental Toxicology: Human Disorders and Ecotoxicology; D’Mello, J.P.F., Ed.; CAB International: Wallingford, UK, 2019; Chapter 36, pp. 531–544.
  43. Caré, S.; Crane, R.; Calabrò, P.S.; Ghauch, A.; Temgoua, E.; Noubactep, C. Modeling the permeability loss of metallic iron water filtration systems. CLEAN—Soil Air Water 2013, 41, 275–282.
  44. Domga, R.; Togue-Kamga, F.; Noubactep, C.; Tchatchueng, J.B. Discussing porosity loss of Fe0 packed water filters at ground level. Chem. Eng. J. 2015, 263, 127–134.
  45. Caré, S.; Nguyen, Q.T.; L’Hostis, V.; Berthaud, Y. Mechanical properties of the rust layer induced by impressed current method in reinforced mortar. Cem. Concr. Res. 2008, 38, 1079–1091.
  46. Zhao, Y.; Ren, H.; Dai, H.; Jin, W. Composition and expansion coefficient of rust based on X-ray diffraction and thermal analysis. Corros. Sci. 2011, 53, 1646–1658.
  47. Pusch, R.; Kasbohm, J.; Knutsson, S.; Yang, T.; Nguyen-Thanh, L. The role of smectite clay barriers for isolating high-level radioactive waste (HLW) in shallow and deep repositories. Procedia Earth Planet. Sci. 2015, 15, 680–687.
  48. Snoeyink, V.L.; Jenkins, D. Water Chemistry; John Wiley & Sons: New Jersey, USA: 1980; p. 480.
  49. Sarin, P.; Snoeyink, V.L.; Bebee, J.; Jim, K.K.; Beckett, M.A.; Kriven, W.M.; Clement, J.A. Iron release from corroded iron pipes in drinking water distribution systems: Effect of dissolved oxygen. Water Res. 2004, 38, 1259–1269.
  50. Grauer, R. Ueber Moegliche Wechselwirkungen Zwischen Verfuellmaterial und Stahlbehälter in Endlager C. Interner Bericht 86-01, NAGRA; Baden, Switzerland, 1986. Available online: https://www.nagra.ch/de accessed on 27 February 2020.
  51. Moraci, N.; Lelo, D.; Bilardi, S.; Calabrò, P.S. Modelling long-term hydraulic conductivity behaviour of zero valent iron column tests for permeable reactive barrier design. Can. Geotech. J. 2016, 53, 946–961.
  52. Noubactep, C. Predicting the hydraulic conductivity of metallic iron filters: Modeling gone astray. Water 2016, 8, 162.
  53. Dickerson, R.E.; Gray, H.B.; Haight, G.P., Jr. Chemical Principles, 3rd ed.; Benjamin/Cummings Inc.: London, UK, 1979; p. 944.
  54. Shi, C.; Wei, J.; Jin, Y.; Kniel, K.E.; Chiu, P.C. Removal of viruses and bacteriophages from drinking water using zero-valent iron. Sep. Purif. Technol. 2012, 84, 72–78.
  55. Noubactep, C. The suitability of metallic iron for environmental remediation. Environ. Prog. Sustain. Energy 2010, 29, 286–291.
  56. Noubactep, C. Processes of contaminant removal in “Fe0–H2O” systems revisited. The importance of co-precipitation. Open Environ. Sci. 2007, 1, 9–13.
  57. Noubactep, C. A critical review on the mechanism of contaminant removal in Fe0–H2O systems. Environ. Technol. 2008, 29, 909–920.
  58. Noubactep, C.; Schöner, A.; Sauter, M. Significance of oxide-film in discussing the mechanism of contaminant removal by elemental iron materials. In Photo-Electrochemistry & Photo-Biology for the Sustainability; Union Press: Osaka, Japan, 2012; pp. 97–122.
  59. Anderson, W. On the purification of water by agitation with iron and by sand filtration. J. Soc. Arts 1886, 35, 29–38.
  60. Ghauch, A.; Abou Assi, H.; Baydoun, H.; Tuqan, A.M.; Bejjani, A. Fe0-based trimetallic systems for the removal of aqueous diclofenac: Mechanism and kinetics. Chem. Eng. J. 2011, 172, 1033–1044.
  61. Hildebrant, B.; Ndé-Tchoupé, A.I.; Lufingo, M.; Licha, T.; Noubactep, C. Steel wool for water treatment: Intrinsic reactivity and defluoridation efficiency. Processes 2020, 8, 265.
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