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Journal of Materials Science

Erschienen in:

18.11.2019 | Chemical routes to materials

Hollow Li₂SiO₃ architectures with tunable secondary nanostructures and their potential application for the removal of heavy metal ions

verfasst von: Hui Zhang, Jianfeng Yang

Erschienen in: Journal of Materials Science | Ausgabe 9/2020

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Abstract

Li₂SiO₃ is a potential new material for mitigating environmental issues such as greenhouse effect and wastewater treatment, but the high-quality failure and evolvable morphology limit have restricted its large-scale application. Herein, a high-quality hierarchically hollow-structured Li₂SiO₃ assembled by tunable secondary structures was precisely fabricated by an efficient green and facile hydrothermal method. The secondary structures, from nanosheets to belts, thorns, spinule and eventually to nanoparticles, accompanying the corresponding morphologies evolving from peony-like to chrysanthemum-like, urchin-like, waxberry-like and eventually to spherical structures, could be tuned by adjusting precursors’ Li/Si molar ratios. All of the obtained hollow Li₂SiO₃ structures were attributed to a common growth mechanism called inside-out Ostwald ripening. The as-prepared hollow Li₂SiO₃ structures were experimented as heavy metal adsorbents for the first time and exhibited excellent adsorption performance for all employed heavy metal ions (Cu²⁺, Mn²⁺ and Ni²⁺). Furthermore, as a case study, the obtained heavy metal-bearing Li₂SiO₃ architectures (Cu(OH)₂@Li₂SiO₃, MnO(OH)₂@Li₂SiO₃ and Ni(OH)₂@Li₂SiO₃) inherited the primary hollow morphology, which endowed them with reusability as high-efficient adsorbents for methylene blue by color removal efficiency higher than 98%. This work lays the foundation for the development of an environmentally friendly “two birds with one stone” route of “remover of heavy metal ions to dye adsorbent,” which will be of great significance for the wastewater treatment.

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Vorheriger Artikel CuO–MoO2–CeO2 yolk–albumen–shell catalyst supported on γ-Al2O3 for denitration with resistance to SO2

Nächster Artikel Synthesis of hexagonal-phase indium tin oxide nanoparticles by deionized water and glycerol binary solvothermal method and their resistivity

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Wu G, Kang HB, Zhang XY, Shao HB, Chu LY, Ruan CJ (2010) A critical review on the bio-removal of hazardous heavy metals from contaminated soils: issues, progress, eco-environmental concerns and opportunities. J Hazard Mater 174(1–3):1–8CrossRef

Srivastava NK, Majumder CB (2008) Novel biofiltration methods for the treatment of heavy metals from industrial wastewater. J Hazard Mater 151(1):1–8CrossRef

Borba CE, Guirardello R, Silva EA, Veit MT, Tavares CRG (2006) Removal of nickel(II) ions from aqueous solution by biosorption in a fixed bed column: experimental and theoretical breakthrough curves. Biochem Eng J 30(2):184–191CrossRef

Paulino AT, Minasse FAS, Guilherme MR, Reis AV, Muniz EC, Nozaki J (2006) Novel adsorbent based on silkworm chrysalides for removal of heavy metals from wastewaters. J Colloid Interface Sci 301(2):479–487CrossRef

Naseem R, Tahir SS (2001) Removal of Pb(II) from aqueous/acidic solutions by using bentonite as an adsorbent. Water Res 35(16):3982–3986CrossRef

Khezami L, Capart R (2005) Removal of chromium(VI) from aqueous solution by activated carbons: kinetic and equilibrium studies. J Hazard Mater 123(1–3):223–231CrossRef

Wang Q, Luo JZ, Zhong ZY, Borgna A (2011) CO₂ capture by solid adsorbents and their applications: current status and new trends. Energy Environ Sci 4(1):42–55CrossRef

Pires JCM, Martins FG, Alvim-Ferraz MCM, Simoes M (2011) Recent developments on carbon capture and storage: an overview. Chem Eng Res Des 89(9):1446–1460CrossRef

Olivares-Marín M, Maroto-Valer MM (2012) Development of adsorbents for CO₂ capture from waste materials: a review. Greenh Gases Sci Technol 2(1):20–35CrossRef

10.

MacDowell N, Florin N, Buchard A, Hallett J, Galindo A, Jackson G, Adjiman CS, William CK, Shah N, Fennell P (2010) An overview of CO₂ capture technologies. Energy Environ Sci 3(11):1645–1669CrossRef

11.

Ku Y, Jung IL (2001) Photocatalytic reduction of Cr(VI) in aqueous solutions by UV irradiation with the presence of titanium dioxide. Water Res 35(1):135–142CrossRef

12.

Mirbagheri SA, Hosseini SN (2005) Pilot plant investigation on petrochemical wastewater treatment for the removal of copper and chromium with the objective of reuse. Desalination 171(1):85–93CrossRef

13.

Alvarez MT, Crespo C, Mattiasson B (2007) Precipitation of Zn(II), Cu(II) and Pb(II) at bench-scale using biogenic hydrogen sulfide from the utilization of volatile fatty acids. Chemosphere 66(9):1677–1683CrossRef

14.

El Hadri N, Quang DV, Goetheer ELV, Abu Zahra MRM (2017) Aqueous amine solution characterization for post-combustion CO₂ capture process. Appl Energy 185(Part 2):1433–1449CrossRef

15.

Bello A, Idem RO (2006) Comprehensive study of the kinetics of the oxidative degradation of CO₂ loaded and concentrated aqueous monoethanolamine (MEA) with and without sodium metavanadate during CO₂ absorption from flue gases. Ind Eng Chem Res 45(8):2569–2579CrossRef

16.

Ma X, Wang X, Song C (2009) “Molecular basket” sorbents for separation of CO₂ and H₂S from various gas streams. J Am Chem Soc 131(6):5777–5783CrossRef

17.

Alcántar-Vázquez B, Díaz Herrera PR, González AB, Duan YH, Pfeiffer H (2015) Analysis of the CO₂–H₂O chemisorption in lithium silicates at low temperatures (30–80 °C). Ind Eng Chem Res 54(27):6884–6892CrossRef

18.

Ortiz-Landeros J, Gómez-Yáñez C, Pfeiffer H (2011) Surfactant-assisted hydrothermal crystallization of nanostructured lithium metasilicate (Li₂SiO₃) hollow spheres: II—textural analysis and CO₂–H₂O sorption evaluation. J Solid State Chem 184(8):2257–2262CrossRef

19.

Duan YH, Pfeiffer H, Li BY, Romero-Ibarra IC, Sorescu DC, Luebke DR, Halley JW (2013) CO₂ capture properties of lithium silicates with different ratios of Li₂O/SiO₂: an ab initio thermodynamic and experimental approach. Phys Chem Chem Phys 15(32):13538–13558CrossRef

20.

Wang K, Wang XY, Zhao PF, Guo X (2014) High-temperature capture of CO₂ on lithium-based sorbents prepared by a water based sol–gel technique. Chem Eng Technol 37(9):1552–1558CrossRef

21.

Subha PV, Nair BN, Hareesh P, Mohamed AP, Yamaguchi T, Warrier KGK, Hareesh US (2014) Enhanced CO₂ absorption kinetic in lithium silicate platelets synthesized by a sol–gel approach. J. Mater. Chem A 2(32):12792–12798CrossRef

22.

Olivares-Marín M, Drage TC, Maroto-Valer MM (2010) Novel lithium-based sorbents from fly ashes for CO₂ capture at high temperatures. Int J Greenh Gas Control 4(4):623–629CrossRef

23.

Pfeiffer H, Bosch P, Bulbulian S (1998) Synthesis of lithium silicates. J Nucl Mater 257(3):309–317CrossRef

24.

Cruz D, Bulbulian S (2003) Synthesis of lithium silicate tritium breeder powders by a modified combustion method. J Nucl Mater 312(2–3):262–265CrossRef

25.

Zhang B, Easteal AJ (2008) Effect of HNO₃ on crystalline phase evolution in lithium silicate powders prepared by sol–gel processes. J Mater Sci 43(15):5139–5142CrossRef

26.

Alemi A, Khademinia S, Joo SW et al (2013) Lithium metasilicate and lithium disilicate nanomaterials: optical properties and density functional theory calculations. Int Nano Lett 3(1):1–11CrossRef

27.

Ortiz-Landeros J, Contreras-García ME, Gomez-Yáñez C, Pfeiffer H (2011) Surfactant-assisted hydrothermal crystallization of nanostructured lithium metasilicate (Li₂SiO₃) hollow spheres: (I) synthesis, structural and microstructural characterization. J Solid State Chem 184(5):1304–1311CrossRef

28.

Li XY, Yang HM (2014) Morphology-controllable Li₂SiO₃ nanostructures. CrystEngComm 16(21):4501–4507CrossRef

29.

Pfeiffer H (2010) Advances in CO₂ conversion and utilization in advances on alkaline ceramics as possible CO₂ captors, chapter 15. In: ACS symposium series. 1056: 233–253

30.

Kim T, Olek J (2016) The effects of lithium ions on chemical sequence of alkali–silica reaction. Cem Concr Res 79:159–168CrossRef

31.

Mitchell LD, Beaudoin JJ, Grattan-Bellew P (2004) The effects of lithium hydroxide solution on alkali silica reaction gels created with opal. Cem Concr Res 34(4):641–649CrossRef

32.

Feng X, Thomas MDA, Bremner TW, Folliard KJ, Fournier B (2010) New observations on the mechanism of lithium nitrate against alkali silica reaction (ASR). Cem Concr Res 40(1):94–101CrossRef

33.

Leemann A, Lörtscher L, Bernard L, Saout GL, Lothenbach B, Espinosa-Marzal RM (2014) Mitigation of ASR by the use of LiNO₃—characterization of the reaction products. Cem Concr Res 59:73–86CrossRef

34.

Yang AX, Wang HJ, Li W, Shi JL (2012) Synthesis of lithium metasilicate powders at low temperature via mechanical milling. J Am Ceram Soc 95(6):1818–1821CrossRef

35.

Molla AR, Chakradhar RPS, Kesavulu CR, Rao JL, Biswas SK (2012) Microstructure, mechanical, epr and optical properties of lithium disilicate glasses and glass-ceramics doped with Mn²⁺ ions. J Alloys Compd 512(1):105–114CrossRef

36.

Zhang B, Nieuwoudt M, Easteal AJ (2008) Sol–gel route to nanocrystalline lithium metasilicate particles. J Am Ceram Soc 91(6):1927–1932CrossRef

37.

Yin ZG, Wang K, Zhao PF, Tang XL (2016) Enhanced CO₂ chemisorption properties of Li₄SO₄, using a water hydration–calcination technique. Ind Eng Chem Res 55(4):1142–1146CrossRef

38.

Kruk M, Jaroniec M (2001) Gas adsorption characterization of ordered organic–inorganic nanocomposite materials. Chem Mater 13(10):3169–3183CrossRef

39.

Chen X, Qiao M, Xie S, Fan K, Zhou W, He HJ (2007) Self-construction of core−shell and hollow zeolite analcime icositetrahedra: a reversed crystal growth process via oriented aggregation of nanocrystallites and recrystallization from surface to core. Am Chem Soc 129(43):13305–13312CrossRef

40.

Yu XX, Yu JG, Cheng B, Huang BB (2009) One-pot template-free synthesis of monodisperse zinc sulfide hollow spheres and their photocatalytic properties. Chem Eur J 15(27):6731–6739CrossRef

41.

Ostwald W (1897) Studien über die Bildung und Umwandlung fester Körper. Z Phys Chem 22(1):289–330

42.

Deroubaix G, Marcus P (1992) X-ray photoelectron spectroscopy analysis of copper and zinc oxides and sulphides. Surf Interface Anal 18(1):39–46CrossRef

43.

Akhavan O, Azimirad R, Safa S, Hasani E (2011) CuO/Cu(OH)₂ hierarchical nanostructures as bactericidal photocatalysts. J Mater Chem 21(26):9634–9640CrossRef

44.

Boileau A, Capon F, Coustel R, Laffez P, Barrat S, Pierson JF (2017) Inductive effect of Nd for Ni³⁺ stabilization in NdNiO₃ synthesized by reactive DC cosputtering. J Phys Chem C 121(39):21579–21590CrossRef

45.

Greiner MT, Helander MG, Wang ZB, Tang WM, Lu ZH (2010) Effects of processing conditions on the work function and energy-level alignment of NiO thin films. J Phys Chem C 114(46):19777–19781CrossRef

46.

Garcia T, Sellick D, Varela F, Vázquez I, Dejoz A, Agouram S, Taylor SH, Solsona B (2013) Total oxidation of naphthalene using bulk manganese oxide catalysts. Appl Catal A 450(15):169–177CrossRef

47.

Lee G, Song K, Bae G (2011) Permanganate oxidation of arsenic(III): reaction stoichiometry and the characterization of solid product. Geochim Cosmochim Acta 75(17):4713–4727CrossRef

48.

Lv G, Bin F, Song CL, Wang KP, Song JO (2013) Promoting effect of zirconium doping on Mn/ZSM-5 for the selective catalytic reduction of NO with NH₃. Fuel 107:217–224CrossRef

49.

Hao SM, Zhu ZS, Zhang XY, Wang QQ, Yu ZZ (2016) Hollow manganese silicate nanotubes with tunable secondary nanostructures as excellent fenton-type catalysts for dye decomposition at ambient temperature. Adv Funct Mater 26(40):7334–7342CrossRef

50.

Gao J, Sun SP, Zhu WP, Chung TS (2014) Chelating polymer modified P84 nanofiltration (NF) hollow fiber membranes for high efficient heavy metal removal. Water Res 63:252–261CrossRef

51.

Kuwahara Y, Tamagawa S, Fujitani T, Yamashita H (2013) A novel conversion process for waste slag: synthesis of calcium silicate hydrate from blast furnace slag and its application as a versatile adsorbent for water purification. J Mater Chem A 1(24):7199–7210CrossRef

52.

You W, Hong M, Zhang H, Wu Q, Zhuang Z, Yu Y (2016) Functionalized calcium silicate nanofibers with hierarchical structure derived from oyster shells and their application in heavy metal ions removal. Phys Chem Chem Phys 18(23):15564–15573CrossRef

53.

Huang RY, Wu MJ, Zhang T, Li DQ, Tang PG, Feng YJ (2017) Template-free synthesis of large-pore-size porous magnesium silicate hierarchical nanostructures for high-efficiency removal of heavy metal ions. ACS Sustain Chem Eng 5(3):2774–2780CrossRef

54.

Shi HC, Li WS, Zhong L, Xu CJ (2014) Methylene blue adsorption from aqueous solution by magnetic cellulose/graphene oxide composite: equilibrium, kinetics, and thermodynamics. Ind Eng Chem Res 53(3):1108–1118CrossRef

55.

Feng M, You W, Wu ZS, Chen QD, Zhan HB (2013) Mildly alkaline preparation and methylene blue adsorption capacity of hierarchical flower-like sodium titanate. ACS Appl Mater Interfaces 5(23):12654–12662CrossRef

Titel: Hollow Li2SiO3 architectures with tunable secondary nanostructures and their potential application for the removal of heavy metal ions
verfasst von: Hui Zhang
Jianfeng Yang
Publikationsdatum: 18.11.2019
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 9/2020
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-019-04219-8

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