Title Characteristics of Landslides in Unwelded Pyroclastic Flow Deposits

Title Characteristics of Landslides in Unwelded Pyroclastic Flow Deposits

Characteristics of landslides in unwelded pyroclastic flow Title deposits, southern Kyushu, Japan Author(s) Yamao, M.; Sidle, R. C.; Gomi, T.; Imaizumi, F. Natural Hazards and Earth System Sciences (2016), 16(2): 617- Citation 627 Issue Date 2016-03-03 URL http://hdl.handle.net/2433/216389 © Author(s) 2016. This work is distributed under the Creative Right Commons Attribution 3.0 License. Type Journal Article Textversion publisher Kyoto University Nat. Hazards Earth Syst. Sci., 16, 617–627, 2016 www.nat-hazards-earth-syst-sci.net/16/617/2016/ doi:10.5194/nhess-16-617-2016 © Author(s) 2016. CC Attribution 3.0 License. Characteristics of landslides in unwelded pyroclastic flow deposits, southern Kyushu, Japan M. Yamaoa,†, R. C. Sidle1, T. Gomi2, and F. Imaizumi3 1Sustainability Research Centre, University of the Sunshine Coast, Locked Bag 4, Maroochydore DC, Queensland 4558, Australia 2Department of International Environmental and Agriculture Science, Tokyo University of Agriculture and Technology, Saiwai 3-5-8, Fuchu, Tokyo, 1585809, Japan 3Faculty of Agriculture, Shizuoka University, 836, Ohya, Suruga-ku, Shizuoka, 4228529, Japan aformerly at: Disaster Prevention Research Institute, Kyoto University, Gokasho, Uji, Kyoto, 6110011, Japan †deceased Correspondence to: R. C. Sidle ([email protected]) Received: 5 September 2015 – Published in Nat. Hazards Earth Syst. Sci. Discuss.: 27 October 2015 Revised: 22 January 2016 – Accepted: 29 January 2016 – Published: 3 March 2016 Abstract. We investigated 184 landslides that occurred in thresholds we have identified are useful for predicting the oc- unwelded pyroclastic flow deposits (Shirasu) on southern currence of different types of landslides in unwelded Shirasu Kyushu Island, Japan, that included detailed data on the rain- deposits and improving sediment disaster prevention prac- fall characteristics and the timing of slope failure. Local- tices, including real-time warning systems. ized rainfall intensity, antecedent precipitation index (API), and topography affected the hydrologic processes that trig- gered landslides. API (adjusted for evapotranspiration losses) for large ( > 200 mm) storms that triggered landslides was 1 Introduction much lower than for smaller (≤ 200 mm) storms. Mean storm −1 intensity and 7-day API (API7) thresholds of > 5 mmh Volcanic deposits are highly susceptible to mass wasting and and ≤ 30 mm (or API30 ≤ 60 mm), respectively, were use- many related sediment disasters have been reported (e.g., ful to identify landslides triggered by rapid pore water pres- Shimokawa et al., 1989; Crosta and Dal Negro, 2003; Ngecu sure response, especially for shorter (< 20 h) duration events. et al., 2004; Bernard et al., 2009; Navarro et al., 2009; During smaller storms with lower intensity, landslides are Cimarelli and de Rita, 2010; De Falco et al., 2012). Various likely affected by a combined increase in soil weight and types of landslides occur in these volcanic materials, includ- loss of suction when API30 ≥ 150 mm; simulations indicated ing rock falls, flank collapses, rotational slumps, earthflows, that these weight and suction changes due to rainfall ac- debris slides, lahars, and debris flows, depending on the char- cumulation decreased the factor of safety in steep Shirasu acteristics of the deposits and triggering mechanisms. For ex- slopes, but did not necessarily trigger the landslides. Most ample, in the western Oregon Cascade Range, competent an- of the landslides that were plotted below a general rainfall desite and basalt lava flows overlie weathered volcaniclastic intensity–duration threshold for landslide initiation occurred rocks that are highly altered due to water infiltration through during smaller storms with API30 values > 200 mm, indicat- cap rock fissures (Swanson and Swanston, 1977). These ar- ing that they were highly influenced by the combined effects eas are susceptible to deep-seated mass movements and, of the accumulated weight of rainfall and loss of suction. where exposed in gorges, promote large rotational slumps Our findings show that both event rainfall characteristics and (Palmer, 1977). Landslide frequency in the Hong Kong re- API affect the hydrogeomorphic processes that trigger dif- gion was higher in areas underlain by dacitic and rhyolitic ferent types of landslides in Shirasu. This knowledge and the volcanic rocks compared to other lithologies (Dai and Lee, 2001). Because of the discontinuous nature of deposits on Published by Copernicus Publications on behalf of the European Geosciences Union. 618 M. Yamao et al.: Characteristics of landslides in unwelded pyroclastic flow deposits, Japan flanks of volcanoes, residual weak soil layers may act as than two-thirds of the landslides around the city of Tarumizu slip surfaces of large landslides (Hürlimann et al., 2001). (southeastern Kagoshima) occurred in Shirasu deposits, and Such unique depositional patterns in volcanic residuals al- most of these were shallow failures (Teramoto et al., 2006). ter the hydrologic pathways and affect localized weathering The dominance of these shallow, planar landslides in Shirasu of these materials. Interactions amongst hydrology, tecton- is attributed to the rapid weathering of this unwelded ma- ics, and lithology can increase the occurrence of landslides terial on steep slopes, thereby promoting repeated removal in volcanic deposits (Sidle and Ochiai, 2006). Furthermore, of the surficial weathered layer (Shimokawa et al., 1989; high and intense rainfall on weathered volcanic materials (in- Yokota and Iwamatsu, 1999; Chigira and Yokoyama, 2005). cluding ash) can trigger debris flows and devastating lahars The shallowest of these planar failures occur on the steep- (e.g., Suwa and Yamakoshi, 1999; Palacios et al., 2001; Lav- est slopes (Haruyama, 1974; Sako et al., 2000; Teramoto et igne and Thouret, 2003). al., 2006). Deeper rotational or planar landslides are much Shirasu is an unwelded pyroclastic flow deposit composed less frequent in Shirasu deposits and typically occur in more of dacitic tuff that covers large areas of southern Kyushu Is- deeply weathered mantles and on gentler slopes. These pre- land, Japan, particularly more than half of the prefecture of vious reports suggest that the types of landslides in Shirasu Kagoshima (e.g., Yokota, 1997; Hyodo et al., 2005). These are associated with rainfall patterns. Quaternary deposits have spread in a radius of more than As with other mass failures, the internal hydrological pro- 50 km by the eruptions of the Aira caldera about 25 000 years cesses and dominant flow pathways with respect to soil mois- ago (Miyagi, 1977; Aramaki, 1984; Nakaoka, 1988). Al- ture conditions may dictate the timing, mode, and type of though these deposits are restricted to the southern 30 % of failure in Shirasu deposits (e.g., Bogaard et al., 2000; Ji- Kyushu Island, this region of Japan experiences some of the tousono et al., 2002: Sidle and Ochiai, 2006). Unweathered most devastating landslide and debris flow disasters in the na- or slightly weathered Shirasu is rather strong in the dry state tion (e.g., Sidle et al., 2004; Teramoto et al., 2006; Taniguchi, and supports slope gradients > 60◦. However, water ingress 2008). Furthermore, because Shirasu is highly susceptible to rapidly weakens Shirasu, creating instabilities during periods landslides, this region provides a unique setting to investi- of rainfall (Haruyama, 1974). Many slope failures in very gate the magnitude and frequency of landslides, and the data steep Shirasu deposits have been attributed to the increased presented herein should be useful in addressing these issues. weight of this highly porous material during progressive rain- Shirasu terrain is steep and often includes isolated butte and fall, along with the associated loss of suction and thus re- mesa landforms. These deposits are easily weathered and duced soil strength (Sako et al., 2000; Kitamura et al., 2003; their strength and bulk density progressively decreases as Chigira and Yokoyama, 2005). Other landslides in Shirasu weathering proceeds (Yokota, 1997). The areas covered by are triggered by the build-up of positive pore water pressure Shirasu in southern Kyushu are often affected by heavy rain- at depth during storms, sometimes affected by soil piping fall during typhoons and Baiu frontal storms. Typhoons typi- (Haruyama, 1974; Teramoto et al., 2006). Earthquakes also cally occur from August through October, while Baiu frontal initiate occasional landslides in these deposits (Kubota and systems occur in early June through late July. Most of these Omura, 2006). Once a landslide occurs, the surface Shirasu storms approach Kyushu Island from the south, delivering rapidly weathers, facilitating another landslide occurrence moist air from the sea, causing heavy rainfall once they strike within decades to several hundreds of years (Shimokawa et land in Kagoshima. Thus, landslides in Shirasu deposits oc- al., 1989; Yokoto and Iwamatsu, 2000). cur during most years and cause substantial property dam- The timing of landslide occurrence with respect to storm age and causalities. For example, in early September 1993, duration, intensity, and antecedent precipitation is critical typhoon Yancy delivered precipitation ranging from 180 to (e.g., Guzzetti et al., 2004). For instance, shallow rapid fail- 543 mm in a 24 h period throughout south-central Kyushu, ures typically occur during large precipitation events with a causing numerous landslides, resulting in extensive loss of period of high intensity (e.g.,

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