Top

Published in:

2020 | OriginalPaper | Chapter

Use of Sorption Method for Strontium Removal

Authors : Anna Vladimirovna Voronina, Vladimir Sergeevich Semenishchev, Dharmendra K. Gupta

Published in: Strontium Contamination in the Environment

Publisher: Springer International Publishing

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Stable isotopes of strontium are common components of natural waters, soils, and soil solutions, whereas radioactive isotopes such as Sr-90 are components of liquid radioactive waste and pollutants of the environment. Sorption method is used for decreasing toxicity of drinking waters when elevated concentrations of stable isotopes are present as well as for deactivation of aqueous media containing radioactive isotopes of strontium. The chapter discusses natural and artificial sorbents for strontium sorption from various aqueous solutions. Mechanisms of strontium sorption by various types of sorbents and factors affecting strontium sorption are described. The effect of concentrations of cations and anions in a solution on sorption and redistribution of strontium between liquid and solid phase is shown.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Removal of Strontium by Physicochemical Adsorptions and Ion Exchange Methods

next chapter Assessment of the Alkaline Earth Metals (Ca, Sr, Ba) and Their Associated Health Impacts

Karpova EA, Gomonova NF (2006) Strontium in an agrocenosis on a soddy-podzolic soil under conditions of the long-term effect and aftereffect of fertilizers. Eur Soil Sci 39:779–784CrossRef

Gupta DK, Walther C (2018) Behaviour of strontium in plants and the environment. Springer, ChamCrossRef

Alexeev LS, Gladkova EV (2012) Decontamination of drinking water from stable strontium. Environ Eng 2:56–58

SanPiN (2001) Russian sanitary norms and regulations. SanPiN 2.1.4.1074-01

GTD (2018) Strontium in drinking water - guideline technical document for public consultation. https://www.canada.ca/content/dam/hc-sc/documents/programs/consultation-strontium-drinking-water/document-eng.pdf. Accessed 14 Aug 2018

EPA (2018) Drinking water standards and health advisories tables. https://www.epa.gov/sites/production/files/2018-03/documents/dwtable2018.pdf. Accessed 14 Aug 2018

Council Directive 98/83/EC (1998) Council Directive 98/83/EC of 3 November 1998 on the quality of water intended for human consumption. https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:31998L0083&from=EN. Accessed 14 Aug 2018

Grazhdan PE (1961) Strontium in underground waters of Kopetdag. The role of microelements in the agriculture. The II conference on microelements. MSU, Moscow, pp 76–80

Kulsky LA, Goronovsky IT, Koganovskiy AM, Shevchenko MA (1980) Handbook on properties, analytical methods and decontamination of water. Naukova Dumka, Kiev

10.

Voinar AO, Lazovskaya LI (1942) About biochemistry of strontium and barium. Biochemistry 7:244–246

11.

Polyakov EV (2007) Behavior of ionic and colloid forms of microelements in colloidal chemical extraction from humic acid solutions. Radiochemistry 49:432–438CrossRef

12.

Polyakov EV, Volkov IV, Khlebnikov NA (2015) Competitive sorption of cesium and other microelements onto iron(III) hexacyanoferrate(II) in the presence of humic acids. Radiochemistry 57:161–171CrossRef

13.

Saenko EV, Leont’eva GV, Vol'khin VV (2005) Sorption elimination of strontium from natural water being formed in the region of strontium deposit. Proceedings of the conference “Ecological and economical problems of mineral resources development”. PGTU, Perm, pp 203–204

14.

Shcherbakov VI, Al’-Amri ZSA, Mikhaylin AV (2017) Ochistka pit’yevoy vody ot strontsiya fil’tratsionnym metodom s primeneniyem klinoptilolita [Drinking water purification from strontium by filtration method using clinoptilolite]. Vestnik MGSU [Proc Mosc State Univ Civ Eng] 12:457–463

15.

Polyakova EV (2012) Strontium in drinking water sources of Archangelsk region and its influence on human’s organism. Ecol Hum 2:9–14

16.

Vinogradov AP (1957) Geochemistry of rare and trace elements in soils. Nauka, Moscow

17.

Shacklette HT, Boerngen JG (1984) Element concentration in soils and other surficial materials of the conterminous United States. U.S. Geol Surv Prof Pap 1270

18.

Sheudzhen AH (2003) Biogeochemistry. Kuban State Agricultural University, Maykop

19.

Toikka MA, Perevozchikova EM, Levkina TI (1981) Strontium in soils and cities of Karelia. Microelements in the environment. Naukova Dumka, Kiev, pp 28–30

20.

Koval’sky VV (1968) Geochemical ecology. Microelements in agriculture and medicine. Nauka, Moscow, pp 66–72

21.

Pavlotskaya FI, Zatsepina LN, Tyuryukanova EB, Baranov VI (1966) On mobility and speciation of strontium-90, stable strontium and calcium in sol-podzol and chernozem soils. Radioactivity of soils and methods of its determination. Nauka, Moscow, p 65

22.

Kabata-Pendias A, Pendias H (1979) Trace elements in the biological environment. Warsaw Yard Geology, Warsaw, p 300

23.

Lavrischev AV (2000) Calcium and strontium in the soil-plant system in the process of soils liming by conversion chalk (on the example of JSC Acron, Novgorod). Ph.D. Thesis, Saint-Petersburg

24.

Myasoedov BF (1997) Radioactive contamination of the environment and possibilities of modern radiochemistry in monitoring. Quest Rad Saf 1:4–16

25.

Voronina AV, Betenekov ND, Semenishchev VS (2018) Water decontamination at radioactively contaminated lands. In: Gupta DK, Voronina AV (eds) Remediation measures for radioactively contaminated areas. Springer, Tokyo, pp 223–243

26.

Voronina AV, Betenekov ND, Nedobukh TA (2010) Applied radioecology. USTU-UPI, Yekaterinburg

27.

Lur’e YY (1979) Handbook on analytical chemistry. Khimiya, Moscow, pp 92–101

28.

Plotnikov VI, Tamaeva K, Myasishchev AV (1989) Coprecipitation of strontium with individual and mixed hydroxides of transition metals. Radiochemistry 3:85–89

29.

Avramenko VA, Egorin AM, Papynov EK, Sokol’nitskaya TA, Tananaev IG, Sergienko VI (2017) Processes for treatment of liquid radioactive waste containing seawater. Radiochemistry 59:407–413CrossRef

30.

Sanjieva DA (2005) Sorption concentration of strontium by natural mineral sorbents as a basis of decontamination of natural water and wastewater. Ph.D. thesis, Astrakhan State University, Astrakhan

31.

Vajda N, Kim CK (2010) Determination of radiostrontium isotopes: a review of analytical methodology. Appl Radiat Isot 68:2306–2326CrossRef

32.

Makrlík E, Vaňura P (2011) Solvent extraction of some divalent metal cations into nitrobenzene by using a synergistic mixture of strontium dicarbollylcobaltate and nonactin. J Radioanal Nucl Chem 288:49–52CrossRef

33.

Makrlík E, Vaňura P, Selucký P (2008) Extraction distributions of micro amounts of strontium and barium in the two-phase water-HCl-nitrobenzene-dibenzo-21-crown-7-hydrogen dicarbollylcobaltate system. J Radioanal Nucl Chem 275:3–7CrossRef

34.

Smirnov IV, Stoyanov ES, Vorob'eva TP (2003) Nature of strontium extraction by synergistic mixtures of chlorinated cobalt dicarbollide and polyethers. Czechoslov J Phys 53:A501–A508CrossRef

35.

Makrlík E (2004) Solvent extraction of strontium picrate from water into nitrobenzene in the presence of benzo-15-crown-5. J Radioanal Nucl Chem 262:513–515CrossRef

36.

McLain DR, Mertz CJ, Sudowe R (2016) A performance comparison of commercially available strontium extraction chromatography columns. J Radioanal Nucl Chem 307:1825–1831CrossRef

37.

Horwitz P, Chiarizia R, Dietz M (1992) Acid dependency of the extraction of selected metal ions by a strontium-selective extraction chromatographic resin: calculated vs. experimental curves. Solvent Extr Ion Exch 10:337–361CrossRef

38.

Attrep M, Kahn B (2008) Determination of radio-strontium in water with a strontium-specific solid-phase extraction column. In: Attrep M, Kahn B (eds) Radioanalytical chemistry experiments. Springer, New York, pp 113–118

39.

Sinharoy P, Banerjee D, Sharma JN, Kaushik CP, Shah JG, Agarwal K (2018) Separation of Sr(II) from Eu(III) across a supported liquid membrane using TEHDGA and 18-crown-6. J Radioanal Nucl Chem 317:919–923CrossRef

40.

Chernyavskaya NB (1985) Sorption of strontium on clinoptilolite and heulandite. Radiochemistry 27:618–621

41.

Chernyavskaya NB, Konstantinovich AA, Andreeva NR, Vorobyeva GE, Skripak IY (1983) Use of clinoptilolite for decontamination of wastewater from cesium and strontium radionuclides. Radiochemistry 25:441–414

42.

Kuznetsov YV, Shchebetkovsky VN, Trusov AG (1974) Basis of water decontamination from radioactive pollution. Atomizdat, Moscow

43.

Milyutin VV, Gelis VM, Penzin RA (1993) Sorption and selective characteristics of inorganic sorbents and ion exchange resins with respect to strontium and cesium. Radiochemistry 35:76–82

44.

Voronina AV (1995) Sorption of cesium and strontium from low-activity fresh waters. Radiochemistry 37:538

45.

Voronina AV (1996) Synthesis, study of properties and applications of thin-layer inorganic sorbents based on non-woven filtering materials. Ph.D. Thesis. USTU, Yekaterinburg

46.

Voronina AV, Blinova MO, Semenishchev VS, Gupta DK (2015) Returning land contaminated as a result of radiation accidents to farming use. J Environ Radioact 144:103–112CrossRef

47.

Milyutin VV, Gelis VM, Nekrasova NA, Kononenko OA, Vezentsev AI, Volovicheva NA, Korol’kova SV (2012) Sorption of Cs, Sr, U, and Pu radionuclides on natural and modified clays. Radiochemistry 54:75–78CrossRef

48.

Milyutin VV, Nekrasova NA, Yanicheva NY, Kalashnikova GO, Ganicheva YY (2017) Sorption of cesium and strontium radionuclides onto crystalline alkali metal titanosilicates. Radiochemistry 59:65–69CrossRef

49.

Ratko AI, Panasyugin AS (1996) Sorption of ¹³⁷Cs and ⁹⁰Sr by modified sorbents based on clinoptilolite. Radiochemistry 38:66–68

50.

Fuks L, Herdzik-Koniecko I (2018) Vermiculite as a potential component of the engineered barriers in low- and medium-level radioactive waste repositories. Appl Clay Sci 161:139–150CrossRef

51.

Andryushchenko ND, Safonov AV, Babich TL, Ivanov PV, Konevnik YV, Kondrashova AA, Proshin IM, Zakharova EV (2017) Sorption characteristics of materials of the filtration barrier in upper aquifers contaminated with radionuclides. Radiochemistry 59:414–424CrossRef

52.

Ivanets AI, Shashkova IL, Kitikova NV, Drozdova NV, Saprunova NA, Radkevich AV, Kul’bitskaya LV (2014) Sorption of strontium ions from solutions onto calcium and magnesium phosphates. Radiochemistry 56:32–37CrossRef

53.

Makarov AV, Zharkova VO, Ershova YY, Tyupina EA, Krupskaya VV (2017) Sorption of Sr-90 and Cs-137 on monocationic forms of bentonite of Taganskoye deposit. Prog Chem Chem Technol 31:16–18

54.

Galamboš M, Kufčáková J, Rajec P (2009) Sorption of strontium on Slovak bentonites. J Radioanal Nucl Chem 281:347–357CrossRef

55.

Kim Y, Kim YK, Kim JH, Yim M-S, Harbottle D, Lee JW (2018) Synthesis of functionalized porous montmorillonite via solid-state NaOH treatment for efficient removal of cesium and strontium ions. Appl Surf Sci 450:404–412CrossRef

56.

Tret'yakov SY (2002) Sorption of ⁹⁰Sr and ¹³⁷Cs on natural sorbents in model environmental systems. Radiochemistry 44:93–95CrossRef

57.

Zolotov YA, Dorokhova EN, Fadeeva VI (1999) Basis of analytical chemistry. Common questions. Separation methods, vol 1. High School, Moscow

58.

Leontieva GV (1997) Structural modification of manganese (III, IV) oxides in synthesis of sorbents selective for strontium. Russ J Appl Chem 70:1615–1618

59.

Kuznetsova VA, Generalova VA (2000) The study of sorption properties of iron, manganese, titanium, aluminum and silicone oxides with respect to ⁹⁰Sr and ¹³⁷Cs. Radiochemistry 42:154–157

60.

Milyutin VV, Nekrasova NA, Kharitonov OV, Firsova LA, Kozlitin EA (2016) Sorption technologies in modern applied radiochemistry. Sorpt Chromatogr Process 16:313–322

61.

Egorin A, Sokolnitskaya T, Azarova Y, Portnyagin A, Balanov M, Misko D, Shelestyuk E, Kalashnikova A, Tokar E, Tananaev I, Avramenko V (2018) Investigation of Sr uptake by birnessite-type sorbents from seawater. J Radioanal Nucl Chem 317:243–251CrossRef

62.

Koivula J, Harjula R, Lehto J (2005) NATO advanced research workshop (ARW). Combined and hybrid adsorbents: fundamentals and applications. Springer, Kiev

63.

Milyutin VV, Nekrasova NA, Kozlitin EA (2015) Selective inorganic sorbents in modern applied radiochemistry. Proc Kola Sci Cent RAS 31:418–421

64.

Dadachov MS, Rocha J, Fereira A, Lin Z, Anderson MW (1997) Ab initio structure determination of layered sodium titanium silicate containing edge-sharing titanate chains (AM-4) Na₃(Na,H)Ti₂O₂[Si₂O₆]₂·2H₂O. Chem Commun 24:2371–2372CrossRef

65.

Decaillon JG, Andres Y, Mokili BM, Abbe JC, Tournoux M, Patarin J (2002) Study of the ion exchange selectivity of layered titanosilicate Na₃(Na,H)Ti₂O₂[Si₂O₆]₂·2H₂O, AM-4, for strontium. Solvent Extr Ion Exch 20:273–291CrossRef

66.

Ivanets AI, Katsoshvili LL, Krivoshapkin PV, Prozorovich VG, Kuznetsova TF, Krivoshapkina EF, Radkevich AV, Zarubo AM (2017) Sorption of strontium ions onto mesoporous manganese oxide of OMS-2 type. Radiochemistry 59:264–271CrossRef

67.

Denton M, Manos M, Kanatzidis M (2009) Highly selective removal of cesium and strontium utilizing a new class of inorganic ion specific media. WM’2009 conference proceeding, Phoenix, USA, pp 1–8. http://www.wmsym.org/archives/2009/pdfs/9267.pdf

68.

Manos MJ, Ding N, Kanatzidis MG (2008) Layered metal sulfides: exceptionally selective agents for radioactive strontium removal. Proc Natl Acad Sci USA 105:3696–3699CrossRef

69.

Voronina AV, Semenishchev VS (2016) Mechanism of strontium sorption by the mixed nickel–potassium ferrocyanide based on hydrated titanium dioxide. J Radioanal Nucl Chem 307:577–590CrossRef

70.

Voronina AV, Semenishchev VS (2013) Effect of surface modification of hydrated titanium dioxide on its selectivity to strontium. Radiochemistry 55:94–97CrossRef

71.

Mobtaker HG, Pakzad SM, Yousefi T (2018) Magnetic CuHCNPAN nano composite as an efficient adsorbent for strontium uptake. J Nucl Mater 504:55–60CrossRef

72.

Denisova TA (2009) State of proton-containing groups in sorbents based on oxyhydrate, heteropolymetallate and cyanoferrate phases. Chemistry Thesis, Yekaterinburg. URL: http://www.server/ihim.uran.ru/files/diss/avtoref/Denisova.pdf

73.

Pechenyuk SI (1991) Sorption-hydrolytic precipitation of the platinum group metals on the surface of inorganic sorbents. Nauka, Leningrad

74.

Bilgin B, Atun G, Keceli G (2001) Adsorption of strontium on illite. J Radioanal Nucl Chem 250:323–328CrossRef

75.

Konoplev AV, Bulgakov AA (2000) ⁹⁰Sr and ¹³⁷Cs exchange distribution coefficient in soil-water systems. Atom Energy 88:158–163CrossRef

76.

Spitsyn VI, Gromov VV (1958) A study of the systematic adsorption of radioactive strontium by montmorillonite and its fixation by roasting. Atom Energy 5:1341–1347CrossRef

77.

Petrova MA, Flowers AG, Krip IM, Shimchuk TV, Petrushka IM (2008) Sorption of Sr on clay minerals modified with ferrocyanides and hydroxides of transition metals. Radiochemistry 50:502–507CrossRef

78.

Shaban IS, Macasek F (1988) Influence of humic substances on sorption of cesium and strontium on montmorillonite. J Radioanal Nucl Chem 229:73–77CrossRef

79.

Sips R (1948) On the structure of a catalyst surface. J Chem Phys 16:490–495CrossRef

80.

Wenming D, Hongxia Z, Meide H, Zuyi T (2002) Use of the ion exchange method for the determination of stability constants of trivalent metal complexes with humic and fulvic acids – part I: Eu³⁺ and Am³⁺ complexes in weakly acidic conditions. Appl Radiat Isot 56:959–965CrossRef

81.

Pandey AK, Pandey SD, Misra V (2000) Stability constants of metal-humic acid complexes and its role in environmental detoxification. Ecotoxicol Environ Saf 47:195–200CrossRef

82.

Zhou P, Yan H, Gu B (2005) Competitive complexation of metal ions with humic substances. Chemosphere 58:1327–1337CrossRef

83.

Blake RE, Walter LM (1999) Kinetics of feldspar and quartz dissolution at 70–80 °C and near-neutral pH: effects of organic acids and NaCl. Geochim Cosmochim Acta 63:2043–2059CrossRef

84.

Huang WL, Keller WD (1970) Dissolution of rock-forming silicate minerals in organic acids: simulated first-stage weathering of fresh mineral surfaces. Am Mineral 55:2076–2094

85.

Stumm W, Furrer G (1987) The dissolution of oxides and aluminium silicates; examples of surface-coordination-controlled kinetics. Aquatic surface chemistry. Chemical processes at the particle–water interface. Wiley, New York, pp 197–219

86.

Malakhov AE, Voronina AV (2016) The influence of humic acids on sorption of cesium by natural and modified aluminosilicates. Proceedings of the 3rd international youth scientific conference “Physics, Technologies, Innovations. PTI-2016”. Ural Federal University, Yekaterinburg, pp 308–309

Title: Use of Sorption Method for Strontium Removal
Authors: Anna Vladimirovna Voronina
Vladimir Sergeevich Semenishchev
Dharmendra K. Gupta
Publisher: Springer International Publishing
Book: Strontium Contamination in the Environment
Print ISBN: 978-3-030-15313-7

Electronic ISBN: 978-3-030-15314-4

Copyright Year: 2020
DOI: https://doi.org/10.1007/978-3-030-15314-4_11