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Journal of Materials Science

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16-03-2017 | Original Paper

Structural, thermal and dissolution properties of MgO- and CaO-containing borophosphate glasses: effect of Fe₂O₃ addition

Authors: Chao Tan, Ifty Ahmed, Andrew J. Parsons, Nusrat Sharmin, Chenkai Zhu, Jinsong Liu, Chris D. Rudd, Xiaoling Liu

Published in: Journal of Materials Science | Issue 12/2017

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Abstract

This paper investigated manufacture of high-durability phosphate glass fibres for biomedical applications. Five different borophosphate glass formulations in the systems of 45P₂O₅–5B₂O₃–5Na₂O–(29 − x)CaO–16MgO–(x)Fe₂O₃ and 45P₂O₅–5B₂O₃–5Na₂O–24CaO–(21 − x)MgO–(x)Fe₂O₃ where x = 5, 8 and 11 mol% were produced via melt quenching. The compositions and amorphous nature of the glasses were confirmed by ICP-MS and XRD, respectively. FTIR results indicated depolymerisation of the phosphate chains with a decrease in Q ² units with increasing Fe₂O₃ content. DSC analyses showed an increase in T _g by ~5 °C with an increment of 3 mol% in Fe₂O₃ content. The thermal properties were also used to calculate processing window (i.e. T _c,ons—T _g) and another parameter, K _gl, to determine the suitability for fibre drawing directly from melt, which equals (T _c,ons—T _g)/(T _l—T _c,ons). The degradation study conducted in PBS solution at 37 °C showed a decrease of 25–47% in degradation rate with increasing Fe₂O₃ content. This confirmed that the chemical durability of the glasses had increased, which was suggested to be due to Fe₂O₃ addition. Furthermore, the density measured via Archimedes method revealed a linear increase with increasing Fe₂O₃ content.

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Parsons AJ, Ahmed I, Haque P, Fitzpatrick B, Niazi MIK, Walker GS et al (2009) Phosphate glass fibre composites for bone repair. J Bionic Eng 6:318–323CrossRef

Ahmed I, Lewis M, Olsen I, Knowles JC (2004) Phosphate glasses for tissue engineering: part 1. Processing and characterisation of a ternary-based P₂O₅–CaO–Na₂O glass system. Biomaterials 25:491–499CrossRef

Ahmed I, Jones IA, Parsons AJ, Bernard J, Farmer J, Scotchford CA et al (2011) Composites for bone repair: phosphate glass fibre reinforced PLA with varying fibre architecture. J Mater Sci Mater M 22:1825–1834. doi:10.1007/s10856-011-4361-0 CrossRef

Sharmin N, Parsons AJ, Rudd CD, Ahmed I (2014) Effect of boron oxide addition on fibre drawing, mechanical properties and dissolution behaviour of phosphate-based glass fibres with fixed 40, 45 and 50 mol% P₂O₅. J Biomater Appl 29:639–653CrossRef

Brauer DS (2012) Phosphate glasses. In: Jones JR, Clare AG (eds) Bio-glasses: an introduction. Wiley, New Jersey

Ahmed I, Lewis M, Olsen I, Knowles JC (2004) Phosphate glasses for tissue engineering: part 2. Processing and characterisation of a ternary-based P₂O₅–CaO–Na₂O glass fibre system. Biomaterials 25:501–507CrossRef

Sharmin N, Rudd CD, Parsons AJ, Ahmed I (2016) Structure, viscosity and fibre drawing properties of phosphate-based glasses: effect of boron and iron oxide addition. J Mater Sci 51:7523–7535. doi:10.1007/s10853-016-0032-3 CrossRef

Ouis MA, Abdelghany AM, ElBatal HA (2012) Corrosion mechanism and bioactivity of borate glasses analogue to Hench’s bioglass. Process Appl Ceram 6:141–149CrossRef

Fu H, Fu Q, Zhou N, Huang W, Rahaman MN, Wang D et al (2009) In vitro evaluation of borate-based bioactive glass scaffolds prepared by a polymer foam replication method. Mater Sci Eng C 29:2275–2281CrossRef

10.

Albon C, Muresan D, Vandenberghe RE, Simon S (2008) Iron environment in calcium-soda-phosphate glasses and vitroceramics. J Non Cryst Solids 354:4603–4608CrossRef

11.

Elisa M, Iordanescu R, Sava BA, Aldica G, Kuncser V, Valsangiacom C et al (2010) Optical and structural investigations on iron-containing phosphate glasses. J Mater Sci 46:1563–1570. doi:10.1007/s10853-010-4963-9 CrossRef

12.

Sales BC, Boatner LA (1986) Physical and chemical characteristics of lead-iron phosphate nuclear waste glasses. J Non Cryst Solids 79:83–116CrossRef

13.

Yu X, Day DE, Long GJ, Brow RK (1997) Properties and structure of sodium-iron phosphate glasses. J Non Cryst Solids 215:21–31CrossRef

14.

Stefan R, Karabulut M (2014) Structural properties of iron containing calcium-magnesium borophosphate glasses. J Mol Struct 1071:45–51CrossRef

15.

Ahmed I, Collins CA, Lewis MP, Olsen I, Knowles JC (2004) Processing, characterisation and biocompatibility of iron-phosphate glass fibres for tissue engineering. Biomaterials 25:3223–3232CrossRef

16.

Bingham PA, Hand RJ, Forder SD, Lavaysierre A (2005) Vitrified metal finishing wastes II. Thermal and structural characterisation. J Hazard Mater 122:129–138CrossRef

17.

Ahmed I, Parsons A, Jones A, Walker G, Scotchford C, Rudd C (2010) Cytocompatibility and effect of increasing MgO content in a range of quaternary invert phosphate-based glasses. J Biomater Appl 24:555–575CrossRef

18.

Franks K, Salih V, Knowles JC, Olsen I (2002) The effect of MgO on the solubility behavior and cell proliferation in a quaternary soluble phosphate based glass system. J Mater Sci Mater M 13:549–556CrossRef

19.

Parsons AJ, Ahmed I, Rudd CD, Cuello GJ, Pellegrini E, Richard D et al (2010) Neutron scattering and ab initio molecular dynamics study of cross-linking in biomedical phosphate glasses. J Phys Condens Matter 22:485403CrossRef

20.

Walter G, Vogel J, Hoppea U, Hartmannc P (2001) The structure of CaO–Na₂O–MgO–P₂O₅ invert glass. J Non Cryst Solids 296:212–223CrossRef

21.

Kordes E, Vogel W, Feterowsky R (1953) Physikalisch-chemische Untersuchungen über die Eigenschaften und den Feinbau von Phosphatgläsern. Z für Elektrochem Ber der Bunsenges für Phys Chem 57:282–289

22.

Sahar MR, Kamaruddin N (1996) The phase equilibrium of binary MgO- and CaO-phosphate glasses. J Mater Sci Lett 15:1932–1934CrossRef

23.

Walter G, Hoppe U, Kranold R, Stachel D (1994) Structural characterisation of magnesium phosphate glasses by X-ray diffraction. Phys Chem Glasses B 35:245–252

24.

Shaharuddin SIS, Ahmed I, Furniss D, Parsons AJ, Rudd CD (2012) Thermal properties, viscosities and densities of (50 − x)Na₂O–(x)CaO–50P₂O₅ glasses. Glass Technol Part A 53:245–251

25.

Mazurin OV (2007) Problems of compatibility of the values of glass transition temperatures published in the world literature. Glass Phys Chem 33:22–36CrossRef

26.

Sharmin N, Hasan MS, Parsons AJ, Furniss D, Scotchford CA, Ahmed I et al (2013) Effect of boron addition on the thermal, degradation, and cytocompatibility properties of phosphate-based glasses. Biomed Res Int 2013:902427CrossRef

27.

Seddon AB, Tikhomirov VK, Rowe H, Furniss D (2007) Temperature dependence of viscosity of Er³⁺-doped oxyfluoride glasses and nano-glass-ceramics. J Mater Sci Mater El 18:145–151CrossRef

28.

Shelby JE (2005) Principles of glass formation. In: Shelby JE (ed) Introduction to glass science and technology, 2nd edn. The Royal Society of Chemistry, Cambridge, pp 7–25CrossRef

29.

Inoue A (1998) Amorphous, nanoquasicrystalline and nanocrystalline alloys in Al-based systems. Prog Mater Sci 43:365–520CrossRef

30.

Nascimento MLF, Souza LA, Ferreira EB, Zanotto ED (2005) Can glass stability parameters infer glass forming ability? J Non Cryst Solids 351:3296–3308CrossRef

31.

Hruby A (1972) Evaluation of glass-forming tendency by means of DTA. Czech J Phys B 22:1187–1193CrossRef

32.

Arstila H, Vedel E, Hupa L, Hupa M (2007) Factors affecting crystallization of bioactive glasses. J Eur Ceram Soc 27:1543–1546CrossRef

33.

Salman SM, Salama SN, Mahdy EA (2015) The effect of strontium oxide replacing calcium oxide on the crystallization and thermal expansion properties of Li₂O–CaO–SiO₂ glasses. Ceram Int 41:137–143CrossRef

34.

Bergo P, Reis ST, Pontuschka WM, Prison JM, Motta CC (2004) Dielectric properties and structural features of barium-iron phosphate glasses. J Non Cryst Solids 336:159–164CrossRef

35.

Haque P, Ahmed I, Parsons A, Felfel R, Walker G, Rudd C (2013) Degradation properties and microstructural analysis of 40P₂O₅–24 MgO–16CaO–16Na₂O–4Fe₂O₃ phosphate glass fibres. J Non Cryst Solids 375:99–109CrossRef

36.

Muresan D, Bathory D, Keul M, Balasz I, Simon S (2005) Local structure and biological effects of vitreous calcium–sodium–phosphate system containing iron. J Optoelectron Adv M 7:2835–2838

37.

Lu M, Wang F, Liao Q, Chen K, Qin J, Pan S (2015) FTIR spectra and thermal properties of TiO₂-doped iron phosphate glasses. J Mol Struct 1081:187–192CrossRef

38.

Qian B, Yang S, Liang X, Lai Y, Gao L, Yin G (2012) Structural and thermal properties of La₂O₃–Fe₂O₃–P₂O₅ glasses. J Mol Struct 1011:153–157CrossRef

39.

Magdas DA, Cozar O, Chis V, Ardelean I, Vedeanu N (2008) The structural dual role of Fe₂O₃ in some lead-phosphate glasses. Vib Spectrosc 48:251–254CrossRef

40.

Bruni S, Cariati F, Narducci D (1994) Infrared specular reflection spectra of copper–zinc phosphate glasses. Vib Spectrosc 7:169–173CrossRef

41.

Sharmin N, Hasan MS, Rudd CD, Boyd D, Werner-Zwanziger U, Ahmed I et al (2016) Effect of boron oxide addition on the viscosity-temperature behaviour and structure of phosphate-based glasses. J Biomed Mater Res B

42.

Ciceo-Lucacel R, Radu T, Ponta O, Simon V (2014) Novel selenium containing boro-phosphate glasses: preparation and structural study. Mater Sci Eng C 39:61–66CrossRef

43.

Wazer V, John R (1958) Phosphorus and its compounds. Interscience Publishers, New York

44.

Knowles JC (2003) Phosphate based glasses for biomedical applications. J Mater Chem 13:2395CrossRef

45.

Koudelka L, Mošner P (2001) Study of the structure and properties of Pb–Zn borophosphate glasses. J Non Cryst Solids 293–295:635–641CrossRef

46.

Carta D, Pickup DM, Knowles JC, Ahmed I, Smith ME, Newport RJ (2007) A structural study of sol–gel and melt-quenched phosphate-based glasses. J Non Cryst Solids 353:1759–1765CrossRef

47.

Kim N-J, Im S-H, Kim D-H, Yoon D-K, Ryu B-K (2010) Structure and properties of borophosphate glasses. Electron Mater Lett 6:103–106CrossRef

48.

Elisa M, Sava BA, Diaconu A, Boroica L, Ursu D, Stamatin I et al (2010) Thermal properties of ecological phosphate and silicate glasses. Glass Phys Chem+ 35:596–601CrossRef

49.

Okura T, Miyachi T, Monma H (2006) Properties and vibrational spectra of magnesium phosphate glasses for nuclear waste immobilization. J Eur Ceram Soc 26:831–836CrossRef

50.

Singh DN (2009) Periodic table and periodicity of properties. In: Singh DN (ed) Basic concept of inorganic chemistry. Pearson Education, India, pp 1–32

51.

Massera J, Claireaux C, Lehtonen T, Tuominen J, Hupa L, Hupa M (2011) Control of the thermal properties of slow bioresorbable glasses by boron addition. J Non Cryst Solids 357:3623–3630CrossRef

52.

Shih PY, Yung SW, Chin TS (1998) Thermal and corrosion behavior of P₂O₅–Na₂O–CuO glasses. J Non Cryst Solids 224:143–152CrossRef

53.

Shih PY, Chin TS (2001) Preparation of lead-free phosphate glasses with low T _g and excellent chemical durability. J Mater Sci Lett 20:1811–1813CrossRef

54.

Isozaki K, Hosono H, Kokumai H, Kawazoe H, Kanazawa T, Gohshi Y (1981) Co-ordination of Mg²⁺ in MgO–P₂O₅ glasses. J Mater Sci 16:2318–2319CrossRef

55.

McMillan PW (1979) Glass-ceramics. Academic Press, London

56.

Chanshetti UB, Shelke VA, Jadhav SM, Shankarwar SG, Chondhekar TK, Shankarwar AG et al (2011) Density and molar volume studies of phosphate glasses. Facta Univ Ser Phys Chem Technol 9:29–36CrossRef

57.

Hasan MS, Ahmed I, Parsons AJ, Walker GS, Scotchford CA (2012) Material characterisation and cytocompatibility assessment of quinternary phosphate glasses. J Mater Sci Mater M 23:2531–2541CrossRef

Title: Structural, thermal and dissolution properties of MgO- and CaO-containing borophosphate glasses: effect of Fe2O3 addition
Authors: Chao Tan
Ifty Ahmed
Andrew J. Parsons
Nusrat Sharmin
Chenkai Zhu
Jinsong Liu
Chris D. Rudd
Xiaoling Liu
Publication date: 16-03-2017
Publisher: Springer US
Published in: Journal of Materials Science / Issue 12/2017
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-017-0981-1

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