- Stratigraphic analysis of the field observations
Figure 2 shows the tephra layer field observations. At each area, the kuroboku colour is nearly black, which is darker than the scoria layers. Kuroboku layers are located on the scoria layers in each area. Takadake 1 has two kuroboku layers with two scoria layers, both of which are located on scoria layers (N1 kuroboku is located on the N2 scoria and N3-4 kuroboku is located on OJS scoria). Furthermore, Takadake 2 has three kuroboku layers with two scoria layers: N1 kuroboku and N2 kuroboku are located on the N2 scoria layer and N3-4 kuroboku is located on the OJS scoria layer. N3-4 kuroboku layer is divided into 2 sub-layers in each area, N3-4 kuroboku (U) and N3-4 kuroboku (L), which aimed at simplifying on the slip layer estimation in this study.
Dissimilarity in soil hardness is observed between the kuroboku and scoria layers. The soil hardness in Takadake 1 shows N2 scoria has the highest soil hardness value (average = 18.55 mm) and topsoil has the lowest soil hardness value (average = 12.6 mm). However, the soil hardness value in Takadake 2 shows OJS scoria has the highest value (average = 23.9 mm) and N3-4 kuroboku has the lowest value (average = 18.1 mm). The low average soil hardness indicates the location of the slip layer.
Miyabuchi and Daimaru (2004) reported that the landslide slip surfaces were formed near the boundary between the kuroboku and scoria layers. In this study, the low average soil hardness value in each area is located at the N3-4 kuroboku layer; therefore, according to the stratigraphic analysis results of the field observations, the N3-4 kuroboku layer is a slip layer in the studied area.
- Physical properties of tephra layers
The particle size distribution curve (Figure 3) shows no dissimilarities in the tephra layers in the research area and all the tephra layers indicate poorly-graded soil material. However, the tephra layer fine fraction content (less than 0.075 mm) (Figure 4) shows a difference between the kuroboku and scoria layers, where the kuroboku layers have a higher fine fraction content than the scoria layers in each area. Moreover, in Takadake 1 and Takadake 2 the N3-4 kuroboku (L) layers have the highest fine fraction content (Figure 4).
Based on the results, the particle size distribution curve does not show any dissimilarity between the kuroboku and scoria layers; however, the fine fraction content shows a dissimilarity between them. For this reason, in this study the particle size distribution curve is difficult to use for estimating the slip layer, but the fine fraction content can be used as a factor for estimating the slip layer.
Figure 5 shows the physical properties of the tephra layer, which generally shows that the scoria and kuroboku layers are different. Scoria layers have a low fine fraction content, plasticity index, ignition loss, and organic matter content and a high density of soil particles. Meanwhile, kuroboku layers have high fine fraction content, plasticity index, and ignition loss and low density of soil particles and organic matter content.
Ignition loss and organic matter content were performed to observe the tephra layer carbon content. Previous research performed by Kato (1964) described kuroboku as having humic acids, black in colour, and high carbon content. Unfortunately, the density of soil particles, ignition loss, and organic matter content values present in Figure 5 are not differentiated between the kuroboku and scoria layers in this study; therefore, these values could not be utilized as slip layer indication factors.
Figure 5 shows that the plasticity index is different between the kuroboku and scoria layers. The liquid limit and plastic limit test results are plotted on a plasticity chart (Figure 6) to classify the tephra layers, which are separated between the sampling location (Takadake 1 and Takadake 2) and the tephra layer type (kuroboku and scoria). The Takadake 1 and Takadake 2 tephra layer data are denoted by filled and un-filled symbols, respectively. Furthermore, the kuroboku and scoria groups are denoted by the line and dotted of ellipse symbols, respectively.
The plotted data in Figure 6 show a similar classification of the tephra layer for Takadake 1 and Takadake 2. That shows all of the plotted data on kuroboku layers are inorganic silts of high compressibility and organic clays and the OJS scoria layers plotted at the same location as the kuroboku layers. The N2 scoria layers, however, are inorganic silts of medium compressibility and organic silts. The plasticity index and liquid limit values of the kuroboku layers are different, but higher than the scoria layers. The plotted data from Takadake 1 and Takadake 2 both show that the N3-4 kuroboku (L) layer has the highest plasticity index and liquid limit values, while the N2 scoria layer has the lowest plasticity index and liquid limit values. Therefore, the N3-4 kuroboku (L) layers (slip layers) have the highest values and are plotted in the kuroboku group on the plasticity chart. The plasticity index and liquid limit can be used as factors for estimating the slip layer.
According to the factors for estimating the slip layer, a correlation between the plasticity index and fine fraction content is observed in Figure 7, showing nearly the same result as the plasticity chart. The correlation shows the plotted data are distinguished between the sampling location (Takadake 1 and Takadake 2) and the tephra layer type (kuroboku and scoria). The Takadake 1 and Takadake 2 tephra layer data are denoted by filled and un-filled symbols, respectively. The data from Takadake 1 fitted to the Takadake 1 trend line, and the data from Takadake 2 also fitted to the Takadake 2 trend line. The trend lines show that the plasticity index is directly proportional to the fine fraction content. Furthermore, the kuroboku and scoria layers are denoted using the line and dotted of ellipse symbols, respectively.
The correlation shows dissimilarity between the kuroboku and the scoria layers. Scoria layers show low fine fraction content and plasticity index values and kuroboku layers show high fine fraction content and plasticity index values. The data from Takadake 1 and Takadake 2 both show that the N3-4 kuroboku (L) layer has the highest plasticity index and fine fraction content values, while the N2 scoria layer has the lowest plasticity index and fine fraction content values. Therefore, the slip layers (N3-4 kuroboku (L)) are plotted in the kuroboku group on the correlation and has the highest values of plasticity index and fine fraction. However, the plots of this correlation have a wide scattering, which could be caused by the difference in soil materials in the different volcanic activity periods and the historical landslides in the Aso volcanic mountains.