阳离子场强对BaO-SiO2-Ln2O3微晶玻璃结构及高温性能影响

doi:10.15541/jim20230044

无机材料学报 ›› 2023, Vol. 38 ›› Issue (10): 1207-1215.DOI: 10.15541/jim20230044 CSTR: 32189.14.10.15541/jim20230044

所属专题：【信息功能】纪念殷之文先生诞辰105周年虚拟学术专辑

阳离子场强对BaO-SiO₂-Ln₂O₃微晶玻璃结构及高温性能影响

杨艳国¹^,²(), 任海深¹(), 何代华², 林慧兴¹^,²()

1.中国科学院上海硅酸盐研究所, 上海 200050
2.上海理工大学材料与化学学院, 上海 200093

收稿日期:2023-01-29 修回日期:2023-02-15 出版日期:2023-10-20 网络出版日期:2023-04-03
通讯作者: 林慧兴, 研究员. E-mail: huixinglin@mail.sic.ac.cn;
任海深, 副研究员. E-mail: renhaishen@mail.sic.ac.cn
作者简介:杨艳国(1998-), 男, 硕士研究生. E-mail: 203613015@st.usst.edu.cn
基金资助:
国家自然科学基金(52002387)

Effect of Cation Field Strength on Structure and High-temperature Properties of BaO-SiO₂-Ln₂O₃ Glass-ceramic

YANG Yanguo¹^,²(), REN Haishen¹(), HE Daihua², LIN Huixing¹^,²()

1. Key Laboratory of Inorganic Functional Material and Device, Shanghai Institute of Ceramics, Chinese Academy of Sciences, Shanghai 200050, China
2. School of Materials and Chemistry, University of Shanghai for Science and Technology, Shanghai 200093, China

Received:2023-01-29 Revised:2023-02-15 Published:2023-10-20 Online:2023-04-03
Contact: LIN Huixing, professor. E-mail: huixinglin@mail.sic.ac.cn;
REN Haishen, associate professor. E-mail: renhaishen@mail.sic.ac.cn
About author:YANG Yanguo (1998-), male, Master candidate. E-mail: 203613015@st.usst.edu.cn
Supported by:
National Natural Science Foundation of China(52002387)

摘要/Abstract

摘要：

SiO₂-BaO基微晶玻璃以其膨胀系数高、耐高性能优异而成为耐高密封领域研究的热点, 但稀土氧化物对该类封接玻璃改性的影响研究尚不多见。本工作研究不同高阳离子场强(Cation field strength, CFS)的稀土氧化物取代传统碱土氧化物BaO对新型富稀土—SiO₂-BaO-Ln₂O₃(SBLn, Ln=La、Sm、Er、Yb)系列玻璃的网络结构、结晶行为、微观结构和高温性能的影响。随着稀土阳离子场强由2.82(La³⁺)增大到3.98(Yb³⁺), SBLn玻璃的玻璃转变温度(T_g)、析晶起始温度(T_x)、析晶峰值温度(T_p)均逐渐增加, 说明高稀土阳离子场强有利于提高SBLn玻璃的热稳定性。四类富稀土SBLn玻璃的结晶相均由BaSiO₃和BaSi₂O₅相组成, 随稀土阳离子场强增大, BaSiO₃相减少、BaSi₂O₅相增多, 稀土元素只存在于玻璃相中, 不参与晶相析出。随着稀土阳离子场强增加, SBLn微晶玻璃的热膨胀系数(Coefficient of thermal expansion, CTE)由12.52×10^-6/℃增大到13.13×10^-6/℃(30~800 ℃), 但析晶量下降导致软化温度从1313.5 ℃降至1174.1 ℃。总之, 富稀微晶玻璃材料高热膨胀系数大于12×10^-6/℃、软化温度均高于1150 ℃, 且在700 ℃高温下的直流电阻率大于10⁶ Ω·cm, 说明富稀土微晶玻璃密封材料具有在固体氧化物燃料电池、氧传感器、铂薄膜热敏电阻器等高温场景下的应用前景。

关键词: 耐高温密封材料, 富稀土微晶玻璃, 阳离子场强, 高温电阻率

Abstract:

The SiO₂-BaO-based glass-ceramics have become the focus of research in the field of high sealing resistance due to their high expansion coefficient and excellent high resistance, but the effect of rare earth oxide on modification of this kind of sealing glass-ceramics is rarely reported. Here, the effects of rare earth elements with different cation field strength (CFS) replacing traditional alkaline-earth oxide BaO on the network structure, crystallization properties, microstructures, and high-temperature resistivity of a new type of rare-earth rich-SiO₂-BaO-Ln₂O₃ (SBLn, Ln=La, Sm, Er, Yb) series glass were studied. With the increase of rare earth cation field from 2.82 in La³⁺ to 3.98 in Yb³⁺, the glass transition temperature (T_g), crystallization initiation temperature (T_x) and crystallization peak temperature (T_p) of SBLn glass are increased, implying that the SBLn glass with higher rare earth cation field strength is more stable. Crystalline phases of the four SBLn glasses are composed of BaSiO₃ and BaSi₂O₅phases. When rare-earth cation field strength increases, the BaSiO₃ phase decreases while the BaSi₂O₅phase increases. Rare-earth elements only exist in the glass phase and do not participate the crystal phase precipitation. The crystallization amount decreases with the increase of rare earth cation field, coefficient of thermal expansion (CTE) of SBLn glass-ceramic increases from 12.52×10^-6 /℃ to 13.13×10^-6 /℃ (30-800 ℃), but softening temperature decreases from 1313.5 ℃ to 1174.1 ℃. In short, the CTE, softening temperature and DC resistivity at 700 ℃ of the SiO₂-BaO-Ln₂O₃ glass-ceramics are greater than 12×10^-6/℃, 1150 ℃ and 10⁶ Ω·cm, respectively, indicating that the rare-earth-rich glass-ceramic sealant has a promising application prospect in the field of high sealing resistance, such as solid oxide fuel cell, oxygen sensors, platinum thin-film thermistor under elevated temperature.

Key words: high-temperature resistant sealant, rich rare-earth glass-ceramics, cation field strength, high temperature resistivity

中图分类号:

TQ174

杨艳国, 任海深, 何代华, 林慧兴. 阳离子场强对BaO-SiO₂-Ln₂O₃微晶玻璃结构及高温性能影响[J]. 无机材料学报, 2023, 38(10): 1207-1215.

YANG Yanguo, REN Haishen, HE Daihua, LIN Huixing. Effect of Cation Field Strength on Structure and High-temperature Properties of BaO-SiO₂-Ln₂O₃ Glass-ceramic[J]. Journal of Inorganic Materials, 2023, 38(10): 1207-1215.

图/表 15

表1 稀土阳离子场强

Table 1 Cation field strength of rare earth

Rare earth ions	Cation field strength, CFS
Ba²⁺	1.41
La³⁺	2.82
Sm³⁺	3.23
Er³⁺	3.87
Yb³⁺	3.98

表2 BaO-SiO2-Ln2O3的组分表(%, 摩尔分数)

Table 2 Composition of BaO-SiO2-Ln2O3 (%, in mol)

Sample	SiO₂	BaO	La₂O	Sm₂O₃	Er₂O₃	Yb₂O₃
SBLa	50	45	5
SBSm	50	45		5
SBEr	50	45			5
SBYb	50	45				5

图1 在1600 ℃下保温2 h熔制的SBLn玻璃实物图(a)和SBLn玻璃与部分微晶化玻璃的XRD图谱(b)

Fig. 1 Photos of SBLn glasses melted at 1600 ℃ for 2 h (a) andXRD patterns of glass and partial crystallization SBLn glass (b)

图2 SBLn玻璃的玻璃形成区

Fig. 2 Glass forming areas of SBLn glass system (a) SBLa; (b) SBSm; (c) SBEr; (d) SBYb

图3 SBLn玻璃在400~1400 cm-1波段红外光谱图

Fig. 3 Infrared spectra of SBLn glass in the wavelength range of 400-1400 cm-1

表3 红外光谱振动峰对应振动模式及化学键类型

Table 3 Corresponding vibration mode and chemical bond type of FT-IR spectra for SBLn

Peak position/ cm^-1	Chemical bond type	Ref.
460-510	Si-O-Si and O-Si-O bending vibration modes	[13⇓-15]
720-820	Si-O-Si symmetric stretching of bridging oxygen	[13⇓-15]
830-940	Si-O⁻ stretching with two non-bridging oxygens	[13⇓-15]
1050-1100	Si-O-Si anti-symmetric stretching of bridging oxygen within the tetrahedra	[13⇓-15]

图4 SBLn玻璃差热分析图

Fig. 4 Differential thermal analysis of SBLn glass

表4 SBLn玻璃差热分析数据

Table 4 Differential thermal analysis data of SBLn glass

Sample	T_g/℃	T_x/℃	T_p¹/℃	T_p²/℃	ΔT/℃
SBLa	755.0	850.3	873.4	900.1	95.3
SBSm	784.0	891.7	918.0	968.2	97.7
SBEr	794.8	894.8	923.4	982.5	100.0
SBYb	814.8	920.6	959.3	1046.6	105.6

图5 SBLn玻璃在750~1200 ℃保温2 h的XRD图谱

Fig. 5 XRD pattern of SBLn glass heated at 750-1200 ℃ for 2 h

图6 SBLn玻璃在1150 ℃下保温2 h的XRD图谱

Fig. 6 XRD patterns of SBLn glass sintered at 1150 ℃ for 2 h

图7 SBLn玻璃烧结曲线(a)和SBLn玻璃经800~1200 ℃烧结2 h的密度曲线(b)

Fig 7 Sintering curves (a) and density curves (b) of SBLn glass (b) sintered at 800-1200 ℃ for 2 h

图8 SBLn玻璃经1150 ℃烧结2 h的SEM照片

Fig. 8 SEM images of SBLn glass sintered at 1150 ℃ for 2 h (a) SBLa; (b) SBSm; (c) SBEr; (d) SBYb

图9 SBEr微晶玻璃经1150 ℃烧结2 h的元素分布图

Fig. 9 Elemental distributions of SBEr glass-ceramic sintered at 1150 ℃ for 2 h

图10 经1150 ℃烧结2 h的SBLn微晶玻璃的热膨胀曲线(a)和SBLn热膨胀系数及软化点直方图(b)

Fig. 10 Thermal expansion curves of SBLn glass-ceramics sintered at 1150 ℃ for 2 h (a) and histogram of SBLn thermal expansion coefficients and softening points (b)

图11 经1150 ℃烧结2 h的SBLn微晶玻璃的直流电阻率随温度的变化曲线

Fig. 11 DC resistivity variated with temperature of SBLn glass-ceramics sintered at 1150 ℃ for 2 h Inset shows the DC resistivity of SBLn glass-ceramics tested at 700 ℃

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阳离子场强对BaO-SiO₂-Ln₂O₃微晶玻璃结构及高温性能影响

Effect of Cation Field Strength on Structure and High-temperature Properties of BaO-SiO₂-Ln₂O₃ Glass-ceramic

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