Effect of Recombination Time on the Structure and Properties of P2O5-Al2O3 Heterogeneous Composite Glass

doi:10.15541/jim20220286

Abstract

Abstract:

In recent years, phase separation glass has attracted extensive attention because of its unique structure and excellent properties. But its mechanism of phase separation on glass remains insufficient clear, especially, the influence of recombination time on structure and properties is unclear. Here, strengthened P₂O₅-Al₂O₃ glass with SiO₂-Na₂O high-silicate glass particles as the second phase was prepared by melting-quenching method combined with pneumatic atomization and mechanical stirring. The relationship between structure and mechanical properties of the glass was investigated by varying the recombination time. Experiment results showed that Young's modulus of the heterogeneous composite glass was higher than that of the P₂O₅-Al₂O₃ glass. Young's modulus of the sample firstly increased and then decreased with the recombination time increasing from 10 s to 8 min. The highest Young's modulus of 80.7 GPa was obtained at recombination time of 6 min, which was increased by 18% as compared with the P₂O₅-Al₂O₃ glass. Introducing SiO₂-Na₂O high-silicate glass particles not only formed the second phase in the matrix glass, but also changed the structure of the P₂O₅-Al₂O₃ glass. As the recombination time increases from 10 s to 6 min, coordination number of phosphorus in heterogeneous composite glass network gradually increases, while amount of non-bridging oxygen in the glass network gradually decreases, resulting in a gradual increase in network cross-linking. However, when the recombination time is more than 8 min, it is not conducive to network crosslinking. Therefore, development of heterogeneous composite glass can provide a new route for the preparation of glass materials with good damage resistance.

Key words: heterogeneous composite glass, P₂O₅-Al₂O₃ glass, Young's modulus, recombination time

CLC Number:

TQ171

ZHU Qingong, ZHAO Gaoling, HAN Gaorong. Effect of Recombination Time on the Structure and Properties of P₂O₅-Al₂O₃ Heterogeneous Composite Glass[J]. Journal of Inorganic Materials, 2023, 38(2): 170-176.

Figures/Tables 9

Fig. 1 XRD patterns of samples prepared with different recombination time (a) and recombination time of 10 min (b) with inset showing optical photo of the sample

Fig. 2 FT-IR spectra of P2O5-Al2O3 matrix glass (a) and SiO2-Na2O high-silicate glass (b) Colorful figures are available on website

Fig. 3 AFM-IR images of the matrix glass (a) and heterogeneous composite glass prepared with different recombination time (b-f) (b) 10 s; (c) 2 min; (d) 4 min; (e) 6 min; (f) 8 min

Fig. 4 High-resolution P2p XPS spectra for heterogeneous composite glass fitting with the least squares method Recombination time: (a) 10 s; (b) 2 min; (c) 4 min; (d) 6 min; (e) 8 min

Table 1 Peak positions, full width at half maximum (FWHM) and area from the fitting curves of P2p core levels for heterogeneous composite glass

Recombination time	Peak position/eV		FWHM/eV	Area/%
Recombination time	Main peak	Deconvoluted peak	FWHM/eV	Area/%
10 s	134.46	134.23	1.46	66.7
10 s	134.46	135.17	1.47	33.3
2 min	134.42	134.22	1.41	66.7
2 min	134.42	135.17	1.41	33.3
4 min	134.59	134.35	1.47	66.7
4 min	134.59	135.28	1.44	33.3
6 min	134.67	134.36	1.74	66.7
6 min	134.67	135.60	2.16	33.3
8 min	134.44	134.26	1.45	66.7
8 min	134.44	135.18	1.50	33.3

Fig. 5 High-resolution O1s XPS spectra for heterogeneous composite glass fitting with the least squares method Recombination time: (a) 10 s; (b) 2 min; (c) 4 min; (d) 6 min; (e) 8 min

Table 2 Peak positions, full width at half maximum (FWHM) and area from the fitting curves of O1s core levels for heterogeneous composite glass

Recombina- tion time	NBO-Li/Mg			NBO-Al			BO
Recombina- tion time	BE/eV	FWHM/eV	Area/%	BE/eV	FWHM/eV	Area/%	BE/eV	FWHM/eV	Area/%
10 s	531.93	1.39	29.69	532.36	1.39	29.68	533.35	1.78	40.63
2 min	532.10	1.43	37.42	532.78	2.17	31.30	533.20	2.17	31.29
4 min	531.95	1.43	31.66	532.41	1.97	34.18	533.29	1.97	34.16
6 min	531.97	1.39	29.65	532.36	1.99	35.18	533.29	1.99	35.17
8 min	532.07	1.35	31.65	532.55	2.07	34.18	533.24	2.07	34.17

Fig. 6 Raman spectra of P2O5-Al2O3 heterogeneous composite glass prepared with different recombination time Colorful figure is available on website

Fig. 7 Young's modulus of P2O5-Al2O3 heterogeneous composite glass prepared with different recombination time

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Effect of Recombination Time on the Structure and Properties of P₂O₅-Al₂O₃ Heterogeneous Composite Glass

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