Glass-formation Range and Cooling Rate

M. Imaoka, H. Kurakata, S. Tai, Hiroshi Nonomiya
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引用次数: 1

Abstract

We have already studied the condition of glass-formation and the glass-formation range of borates, silicates and germanates. In these studies, however, we could not determine precisely the cooling condition which defines the glass-formation range, because the glassy stateis not a stable state, but a sub-stable one. These experiments were made under conditions which were determined for the sake of experimental convenience: namely, 1/80mols of specimen were melted and cooled naturally in a room. Therefore, it is necessary to examine to what extent the results of these experiments are effective in view of the glass structure. In this study experiments were carried out by changing the cooling rate, and the variation in the glass-formation range with various cooling rates was examined. These cooling processes included the followings: quick cooling by water, natural cooling in a room (cf. Curve I in Fig. 1), natural cooling in a furnace (cf. Curve II in Fig. 2) and slow cooling in a furnace controlled by a thermocontroller. These cooling rates are about 3×102, 10, 1.5×10-1 and 1.2×10-3°C/sec, respectively. The amount of molten glass is the same as that in the previous studies; crucibles employed are made of platinum or its alloy, which may have some effect especially in the case of the slow cooling in a furnace.Ternary borate systems have been chosen as the glass-forming system for the convenience of experiment, which have been divided into common systems and exceptional systems. The former include the B-type ternary system as the containing only the oxides of the a-group elements, the PbO-containing ternary system as the one containing both of the oxides of the a-group and the b-group elements, and the B2O3-Bi2O3-PbO system as the one containing only the oxides of the b-group elements. The results are shown in Fig. 1-19. These glass-formation ranges contain various critical lines of vitrification; the limit of the continuity of a network-structure (the AD-line in Fig. 2 and 3), the existing limit of necessary modifier ions for the network-formation (the B2O3-C line in Fig. 2 and 3), and the exchangeable limit of network ions represented by the number of b-group ions connecting B with B in the network-structure (the A1B2, A2B3, … lines in Fig. 8; cf. Table 1). The glass-formation range expressed by the above critical lines generally varies somewhat according to the variation in the cooling rate. Therefore the result of the glass-formation range under an arbitrary cooling condition has no absolute meaning. However, comparing Fig. 4 with Fig. 5, for example, we can see a similar variation in the glass-formation range in both cases. In the one case the modifier ions are not exchanged but the cooling conditions are changed, while in the other the modifier ions are exchanged but the cooling conditions are kept constant. This fact can be explained by assuming the 3-dimensional glass-formation range including the glass stability as shown in Fig. 7. When the modifier ion in the B2O3-PbO-RO system (Fig. 5) is smaller, so that its vitrified system is more unstable, the glass-formation occurs only in the high stability sections. The case is the same when the cooling rate is slower in a more stable vitrified system.We then studied the B2O3-MgO-BaO system (Fig. 9), the B2O3-TiO2-BaO system (Fig. 12), the B2O3-WO3-Li2O systems (Fig. 15) and the B2O3-K2O-Bi2O3 system (Fig. 17) as exceptional ternary systems and discussed the true feature of the anomaly of these systems. In the
玻璃形成范围和冷却速度
我们已经研究了硼酸盐、硅酸盐和锗酸盐的玻璃形成条件和玻璃形成范围。然而,在这些研究中,由于玻璃态不是稳定状态,而是亚稳定状态,我们不能精确地确定定义玻璃形成范围的冷却条件。为了实验方便,我们确定了实验条件:1/80mol的样品在室内自然熔化冷却。因此,有必要考察这些实验结果在多大程度上对玻璃结构是有效的。本研究通过改变冷却速率进行了实验,考察了不同冷却速率下玻璃形成范围的变化情况。这些冷却过程包括:用水快速冷却、室内自然冷却(参见图1中的曲线I)、炉内自然冷却(参见图2中的曲线II)和由温控器控制的炉内缓慢冷却。这些冷却速率分别约为3×102, 10, 1.5×10-1和1.2×10-3°C/秒。玻璃液用量与以往研究相同;所使用的坩埚是由铂或其合金制成的,特别是在炉中缓慢冷却的情况下,它可能有一些效果。为方便实验,选择三元硼酸盐体系作为玻璃成型体系,并将其分为普通体系和特殊体系。前者包括只含有a族元素氧化物的b型三元体系,同时含有a族和b族元素氧化物的含pbo三元体系,以及只含有b族元素氧化物的B2O3-Bi2O3-PbO体系。结果如图1-19所示。这些玻璃形成范围包含各种玻璃化的临界线;网络结构连续性的极限(图2和3中的ad线),网络形成所需修饰离子的现有极限(图2和3中的B2O3-C线),以及网络结构中连接B与B的B族离子的数量所表示的网络离子的可交换极限(图8中的A1B2、A2B3、…线);参见表1)。以上临界线表示的玻璃形成范围通常会随着冷却速率的变化而有所不同。因此,任意冷却条件下的玻璃形成范围的结果没有绝对意义。然而,例如,将图4与图5进行比较,我们可以看到两种情况下玻璃形成范围的变化相似。在一种情况下,不交换改性剂离子但改变冷却条件,而在另一种情况下,交换改性剂离子但保持冷却条件不变。这一事实可以通过假设三维玻璃形成范围包括玻璃稳定性来解释,如图7所示。当B2O3-PbO-RO体系(图5)中的改性剂离子较小,使得其玻璃化体系更不稳定时,玻璃化只发生在高稳定段。在更稳定的玻璃化系统中,冷却速度较慢的情况也是如此。然后,我们将B2O3-MgO-BaO体系(图9)、B2O3-TiO2-BaO体系(图12)、B2O3-WO3-Li2O体系(图15)和B2O3-K2O-Bi2O3体系(图17)作为异常三元体系进行了研究,并讨论了这些体系异常的真实特征。在
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