Fabrication of glass-ceramics composite by infiltration of lithium tetraborate glass into porous magnesium aluminate spinel ceramic

IF 0.7 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of metals, materials and minerals Pub Date : 2023-03-28 DOI:10.55713/jmmm.v33i1.1614

N. Kulrat, C. Busabok, Saweat Intarasiri, S. Dangtip, Wasana Khongwong

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Abstract

Magnesium aluminate spinel (MAS) glass-ceramics composite has excellent mechanical and optical properties. It can be obtained from porous ceramic by infiltrating the proper choice of glass. In this study, porous MAS ceramic was prepared by conventional sintering from MAS powder to reach a bulk density of 2.48 g∙cm-3 (70.1% of relative density). The porous MAS ceramic was then infiltrated with molten lithium tetraborate glass (Li2B4O7; LTB) at 950℃ for 30 (IF30) and 60 (IF60) min. They were left to cool down to 700℃ inside the furnace before being taken out to quench in ambient. The glass-ceramics composite was obtained with 98.7% and 92.1% relative density for IF30 and IF60 cases, respectively. SEM images reveal a lower degree of porosity in the IF30 case, which achieves higher flexural strength of 119.7 MPa. X-ray diffraction and Raman spectroscopy indicate that Mg2B2O5 phase (at 2q =35°) and B2O5 functional group (at 847 cm-1) are formed during infiltration. Consequently, their micro vickers hardness increased (3.41®5.53®6.16 GPa).

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四硼酸锂玻璃渗透多孔铝酸镁尖晶石陶瓷制备微晶玻璃复合材料

铝酸镁尖晶石微晶玻璃复合材料具有优异的力学性能和光学性能。它可以从多孔陶瓷中通过适当选择渗透玻璃而获得。本研究以MAS粉末为原料，采用常规烧结法制备多孔MAS陶瓷，其堆积密度为2.48 g∙cm-3(占相对密度的70.1%)。然后用熔融四硼酸锂玻璃(Li2B4O7;LTB)在950℃下加热30 (IF30)和60 (IF60) min。在炉内冷却至700℃，然后取出在环境中淬火。IF30和IF60的相对密度分别为98.7%和92.1%。SEM图像显示，IF30的孔隙度较低，抗折强度达到119.7 MPa。x射线衍射和拉曼光谱分析表明，在渗透过程中形成了Mg2B2O5相(2q =35°)和B2O5官能团(847 cm-1)。因此，他们的显微维氏硬度提高(3.41®5.53®6.16 GPa)。

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来源期刊

Journal of metals, materials and minerals MATERIALS SCIENCE, MULTIDISCIPLINARY-

CiteScore

1.40

自引率

11.10%

发文量

期刊介绍： Journal of Metals, Materials and Minerals (JMMM) is a double-blind peer-reviewed international journal published 4 issues per year (starting from 2019), in March, June, September, and December, aims at disseminating advanced knowledge in the fields to academia, professionals and industrialists. JMMM publishes original research articles as well as review articles related to research and development in science, technology and engineering of metals, materials and minerals, including composite & hybrid materials, concrete and cement-based systems, ceramics, glass, refractory, semiconductors, polymeric & polymer-based materials, conventional & technical textiles, nanomaterials, thin films, biomaterials, and functional materials.