Rainfall-induced landslides not only cause property loss, but also kill and injure large numbers of people every year in mountainous areas in China. These losses and casualties may be avoided to some extent with rainfall threshold values used in an early warning system at a regional scale for the occurrence of landslides. However, the limited availability of data always causes difficulties. In this paper we present a method to calculate rainfall threshold values with limited data sets for two rainfall parameters: hourly rainfall intensity and accumulated precipitation. The method has been applied to the Huangshan region, in the province of Anhui, China. Four early warning levels (zero, outlook, attention, and warning) have been adopted and the corresponding rainfall threshold values have been defined by probability lines. A validation procedure showed that this method can significantly enhance the effectiveness of a warning system, and finally reduce and mitigate the risk of shallow landslides in mountainous regions.
Landslide risk has increased all over the world during recent decades, because of the uncontrolled urban sprawl by fast population growth and accelerated economic development. Particularly in many mountainous regions of developing countries, such as China, natural hazards have already become one of the most significant threats to people and property. On 7 August 2010, two debris flows occurred in the Sanyanyu gully and Loujiayu gully, near the county of Zhouqu, Gansu, northwestern China, which took about 1765 people's lives of people living on the densely urbanized fan (Tang et al., 2011). On 11 January 2013, a large landslide induced by rainfall in the county of Zhenxiong, Yunnan, killed 46 people (Yin et al., 2013). Not only in China, but also in a number of developed countries, such as the Daunia region in southern Italy, do abundant mass movements also cause a high level of potential risk to urban centers and transportation systems (Pellicani et al., 2013). In September 2004, a hurricane-induced debris flow killed five persons in North Carolina (Wooten et al., 2007), and a landslide killed 10 persons in La Conchita in January 2005 (Jibson, 2005). Additionally, the southwest of China is one of the regions most affected by more catastrophic events, where complicated geological conditions exist and earthquakes are generated (e.g., Wenchuan earthquake on 12 May 2008 and Lushan earthquake on April 20, 2013). These phenomena have illustrated the vulnerability to natural hazards, the underestimation of the potential risks; and they have revealed the lack of policies for disaster reduction and mitigation in these regions. The public and government have been sensitized to the urgent demand for effective warning systems in landslide-prone areas.
Generally, rainfall-induced shallow landslides are less than 3–5 m thick and move with quite a high velocity. Usually they are widespread in mountainous areas. In order to reduce this impact, more and more scientists are working on forecasting the occurrence of shallow landslides. According to the different scale of study area, this research can be classified into two categories: local studies and regional studies. For local research, first physical slope stability models must be developed to understand the instability mechanism of an individual landslide, then a monitoring system for rainfall and slope movements has to be installed, which is then followed by a comprehensive analysis of the monitoring data. For more information about single landslide early warning systems in various parts of the world, see Thiebes (2012), Carey and Petley (2014), and others. When working over larger areas, the method used in early warning systems to forecast shallow landslide occurrence is frequently based on statistical and empirical models relying on one or two parameters from the rainfall events, e.g., rainfall intensity and duration, or antecedent precipitation. Generally, there are five types of methods to obtain the threshold line for rainfall-induced shallow landslides: (i) precipitation intensity–duration (I–D) thresholds, e.g., Keefer et al. (1987), Guzzetti et al. (2007a), Cannon et al. (2008), and Segoni et al. (2014), which is perhaps the most popular among rainfall threshold methods; (ii) daily precipitation and antecedent effective rainfall, e.g., Glade et al. (2000), Guo et al. (2013); (iii) cumulative precipitation–duration thresholds, e.g., Aleotti (2004); (iv) cumulative precipitation–average rainfall intensity thresholds, e.g., Hong et al. (2005); and (v) a combination of cumulative rainfall threshold, rainfall intensity–duration threshold and antecedent water index or soil wetness, e.g., Baum and Godt (2009). In particular, empirical rainfall thresholds have already proven their value to forecast the occurrence of landslides, and are frequently used in operational warning systems (Baum and Godt, 2009; Glade et al., 2000; Greco et al., 2013; Guzzetti et al., 2007a, b; Keefer et al. 1987; Osanai et al., 2010; Segoni et al., 2014, 2015; Wei et al., 2015; Zêzere et al., 2014). However, as shown by Intrieri et al. (2012), an early warning system (EWS) is a very complicated system. According to the United Nations International Strategy for Disaster Reduction (UNISDR, 2009), it is defined as “the set of capacities needed to generate and disseminate timely and meaningful warning information to enable individuals, communities, and organizations threatened by a hazard to prepare and to act appropriately and in sufficient time to reduce the possibility of harm or loss.”
Several excellent examples of EWS have already been proposed for different regions, such as Seattle, on the west coast of the USA (Baum and Godt, 2009), the Adriatic Danubian area in central and southern Europe (Guzzetti et al., 2007b), and Xi'an, in the province of Shanxi, China (Zhuang et al., 2014). For Tuscany, Italy, Segoni et al. (2014) presented a mosaic of several local rainfall thresholds instead of a single regional one. They established a relation between the threshold parameters and the prevailing lithology, which significantly enhances the effectiveness of an early warning system. However, all these critical thresholds and equations strongly depend on the local physiographic, hydrological, and meteorological conditions (Guzzetti et al., 2007a). In addition, they suffer from the lack of necessary resources for provision of continuous support or expansion of services. The application of these methods in other regions is very difficult from a practical point of view. It is, therefore, so important and urgent to find a simple and suitable approach for the definition of warning thresholds through the study of fundamental process mechanisms and the analysis of relationships between rainfall and landslides. Presently, most mountainous regions in China lack available rainfall records and landslide occurrence information, which makes it much more difficult to establish a rainfall threshold for landslide forecasting in a short period of time.
This paper presents the results of a recent study on rainfall thresholds for shallow landslides at a regional scale to overcome the aforementioned difficulties. The thresholds are determined with rigorous statistical techniques from two rainfall parameters. The paper contains (i) the description of a method to calculate rainfall thresholds from limited available data and time; (ii) the application and improvement of the rainfall threshold for landslide early warning in a case study.
Location of the Huangshan region. The inset map shows the location of the province of Anhui, China.
Faults distribution of the Huangshan region with a digital elevation model (DEM) background.
The Huangshan study area is located in the province of Anhui, eastern
China (Fig. 1), and covers an area of 9807 km
The landslide-prone areas lie between the southern Yangtze Block (south of the Yangtze Plate) and the transitional segment of the Jiangnan uplift belt. The main fault zones are NE- and EW-trending which determine the local tectonics and topography, and one fault, called Xiuning fault, is inferred to separate the mountains and the hilly parts and plains, as shown in Fig. 2 (Ju et al., 2008). The rocks in the study area range from late Precambrian to Upper Triassic in age and consist mainly of granite, dolomite, limestone, sandstone, slate, and shale. The complicated geological condition, the numerous heavy rainfall events, and the numerous human activities in the area caused numerous landslides, leading to catastrophic economic losses and large numbers of fatalities in recent years.
Typical shallow landslides triggered by rainfall in the Huangshan region.
The methodology used in this study mainly consisted of two components: (i) the collection of landslide and rainfall records and (ii) the analysis of the relationship between rainfall and landslide occurrence using probabilistic and empirical methods. Several methods have been used in this study to collect additional data for the analysis, such as those data contained in technical reports and documents produced by national scientific communities and government agencies. The parameters and analysis model are mainly referenced from previous researchers, but have been improved in this paper to present a more simple and suitable approach for shallow landslide early warning in mountainous areas.
Detailed landslide and rainfall data sets are the foundation for the analysis of the relationship between rainfall and landslide occurrence. The landslide inventory and rainfall data provided in this paper are mostly the result of field investigations immediately after landslide occurrence, and were validated by the local geological and environmental monitoring station in the Huangshan region during the period 2007–2012 (Fig. 3). Most of the shallow landslides are located in the mountainous region, which always occurred in rainy season every year, but some are located in the plain areas where usually rive banks are.
Location of rainfall-induced shallow landslides in the Huangshan region (2007-2012).
In this period, more than 100 shallow landslides were recorded but some of them were not triggered by rainfall. Some landslides were triggered by factors of human activity and were not included in the study. This also applies to some events with unclear dates of occurrence. As a result, there are only 50 landslides with accurate dates of occurrence and rainfall records collected in the data sets; typical examples are shown in Table 1. Meanwhile, in order to study the relationship between rainfall and shallow landslide occurrences, more than 50 historical rainfall events with no landslide occurrence were also collected for use during the analysis.
As mentioned in the introduction, there are several parameters related to
rainfall thresholds which have been applied successfully in some regions. In
the Huangshan region, it is very difficult to obtain a reliable rainfall
threshold value for landslide early warning due to the limited availability
of data. In order to overcome this problem, a trial method was developed
first. Its practicability and expandability will be investigated with
new collected data in the near future. Two rainfall parameters were selected
to obtain the threshold equation in a simple way from the database that is
currently available: the hourly rainfall intensity (I
The beginning of each rainfall event is defined as the moment that the hourly
rainfall amount is more than 4 mm h
A line with a gradient (-a) is drawn under the lowest points which represent
landslide occurrences under such rainfall conditions. This is shown with a
blue line in Fig. 4. The area between the blue line and the
Similarly, a line with the same gradient can be drawn above the highest
points, representing combinations of
In the area between the lower envelope (blue line) and the upper envelope
(red line), probability lines can be defined by the same method (Fig. 4). The
algorithm for each probability line is shown in Eq. (1).
According to Eq. 1, there must be two constants
While drawing the first probability line (blue line), the gradient (-a) is an
uncertain parameter, dependent on experts' experiences or on historical data
sets (Jan et al., 2002). To deal with this problem, another parameter (
Recommended warning levels and responses.
Based on the results from Eq. (4), the lowest five available points of
rainfall records with landslide occurrence, in a descending sequence, can be
selected to determine the gradient (-a) of the lower curve by the least
squares method, as shown in Fig. 5. For a safe landslide early warning in the
Huangshan region, the probability of the lower curve is defined as
PLO
There are eight points of landslides in the area that occurred where
PLO
According to the national standard, a four-level early warning scheme (zero, outlook, attention, and warning) is defined for rainfall-induced shallow landslides in the Huangshan region. Additionally, in order to improve the effectiveness of an EWS, the response of the population living in this study area needs to taken into consideration. We reference successful examples, e.g., Baum and Godt (2009); Guzzetti et al. (2007b); Segoni et al. (2015); and Frigerio et al. (2014). A corresponding four-color-coded scale (blue, yellow, orange, and red) of warning levels is shown in Figs. 4 and 6, and in Table 2. In a real-time early warning system, the points (Rt, Ih) are calculated from the rainfall monitoring data by 1 h per circle in a real-time way while the rainfall starting, which enables a tendency line to be drawn in the early warning graph (Fig. 6).
Improved method to ensure the gradient of the lower envelope.
Application of the methodology in the Huangshan region (rainstorm of 30 June 2013).
It can be seen in Fig. 4 and Table 2, that the probability of landslide occurrence in the blue area is less than 10 %, indicating that landslides are very unlikely to occur. At this probability level, no warning will be given to the local authorities or the population, but general inspection and regular rainfall monitoring must be carried out, and experts must be informed that they need to pay attention to the rainfall variation. The probability in the yellow area is 10–50 %, indicating that there is a possibility of landslide occurrence in the near future. Meanwhile, the local authorities and population will be informed immediately that they must pay close attention to the rainfall variation. The probability in the orange area is 50–90 %, indicating that there is a serious possibility of landslide occurrence in the near future. Therefore, countermeasures and recommendations need to be discussed, e.g., to avoid going to the threatened area. The probability in the red area is more than 90 %, indicating that there is a very great chance of landslide occurrence in the hours following. Therefore, local people must be alerted to evacuate the threatened area or avoid going there, and keep a safe distance.
When rainfall occurs, the starting time of the critical rainfall event
(I
Figure 6 shows that the rainfall started at midnight on 29 June 2013, and the
hourly rainfall intensity was more than 4 mm h
In a previous early warning system of this region, there was only a single value (150 mm) of cumulative rainfall as the warning threshold. The warning message would have been sent at 09:00 approximately. Compared to the improved method presented in this paper (alert message can be sent while the point was in yellow area at 07:00, as shown in Fig. 6), there would be more than 2 h left for crisis preparation by using the presented warning thresholds. We can conclude that the threshold lines facilitate the prediction of occurrences of rainfall-induced shallow landslides, which is useful for landslide prevention and mitigation at an early stage. Moreover, the rainfall threshold curves can be improved when more data are collected in the future.
Landslides induced by rainfall cause significant harm, both in terms of human casualties and economic losses in the vast mountainous areas in China. So, there is an urgent need for effective measures for landslide early warning and mitigation. However, problems in defining regional rainfall threshold values were always encountered during studies, due to the lack of available rainfall and landslide data. Based on the result of previous research by other authors, in this paper we selected the hourly rainfall intensity and the accumulated precipitation as the two rainfall factors in order to overcome these difficulties. The Huangshan region was selected as the study area for the explanation of this methodology. The results of this application show that it is indeed a suitable approach for investigating shallow landslides triggered by rainfall.
However, when using this method, one has to be aware of some limitations and restrictions. The basic limitation is that rainfall thresholds inevitably just represent a simplification of the relationship between rainfall and landslide occurrence (Reichenbach et al., 1998). Usually, when a landslide happens, there is more than one causative factor and the analysis is a complex procedure. The second issue is that the rainfall thresholds presented in this paper have a usage limitation for only the Huangshan region. These limitations must be considered before applying the methodology to another area. Therefore, the determination of rainfall threshold values for landslide early warning must be regarded as a long-term research activity before it can be used as a more reliable approach in the future.
In spite of these limitations, this method of establishing rainfall threshold values from limited data sets provides a way of improving and modifying the method by collecting new data during subsequent studies to reduce the losses caused by this type of natural disaster.
This study was financially supported by the State Key Laboratory of Geo-hazard Prevention and Geo-environment Protection (Chengdu University of Technology) (grant no. SKLGP2013Z007) and the National Natural Science Foundation of China (grant no. 41302242). The authors also give great thanks to Prof. Niek Rengers for his kind advice and for polishing the language, which greatly improve the quality of the manuscript.Edited by: F. CataniReviewed by: two anonymous referees