The December 22, 2018 Anak Krakatau, Indonesia, Landslide and Tsunami: Preliminary Modeling Results

Paris, Alexandre; Heinrich, Philippe; Paris, Raphaël; Abadie, Stéphane

doi:10.1007/s00024-019-02394-y

Cited by 64 publications

(71 citation statements)

References 63 publications

(65 reference statements)

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“…Heidarzadeh et al (2020a) analyzed tide gauge records of the AKT and proposed a source model for this unique tsunami by applying numerical simulations; the source model proposed by Heidarzadeh et al (2020a) consists of an initial pure-elevation wave with height of 100-150 m and length of 1.5-2.0 km. The numerical modeling of the event by Paris et al (2020) and Zengaffinen et al (2020) further reconfirmed the source model initially proposed by Heidarzadeh et al (2020a). The volume of the sliding mass during the AKT was estimated at 0.2-0.3 km 3 by Ren et al (2020) whereas Heidarzadeh et al (2020a) reported it in the range of 0.175-0.326 km 3 .…”

Section: Introductionsupporting

confidence: 65%

Field Survey of Tsunami Heights and Runups Following the 22 December 2018 Anak Krakatau Volcano Tsunami, Indonesia

Heidarzadeh

Putra

Nugroho

et al. 2020

Pure Appl. Geophys.

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The 22 December 2018 Anak Karakatau tsunami in Indonesia was a rare event in that few instrumental records existed of tsunamis generated by volcanic sources before this event. The tsunami, which left a death toll of 437, is of global importance as it provides opportunities to develop knowledge on generation, propagation and coastal effects of volcanic tsunamis. Here, we report results of field surveys along the coast of the Sunda Strait, Indonesia to study tsunami wave heights and coastal damage. We surveyed 29 locations and measured ranges of tsunami runup from 0.9 to 5.2 m, tsunami heights from 1.4 to 6.3 m, flow depths from 0.2 m to 3.0 m and inundation distances from 18 to 212 m. The largest tsunami heights and concentration of damage and fatalities occurred on the western shore of Java from Tanjung Lesung to Sumur. The largest cluster of fatalities occurred at Tanjung Lesung, where more than 50 people died while attending an outdoor music being held at the shoreline. The tsunami runup and tsunami height in Tanjung Lesung were 4.0 and 2.9–3.8 m, respectively. We believe this tragedy could have been avoided if the event organizers were more aware of the hazard posed by the Anak Krakatau volcano, as it had been actively erupting for several months prior to the tsunami, and simply moved the concert stage 100 m inland. Many of the locations surveyed demonstrated a similar pattern where the majority of casualties and destruction occurred within 100 m of the coast; in several locations, lives were saved where buildings were located at least this distance inland. The significant damage and numerous deaths which occurred in Sumur, despite the moderate tsunami height of 2.3–2.5 m, can be attributed to the extremely low-lying coastal land there. Flow depth in Sumur was 0.9–2.0 m. During our field surveys, nearly one year after the event, we noted that some of the damaged buildings were being rebuilt in the same locations just 10–30 m from the shoreline. We question this practice since the new buildings could be at the same tsunami risk as those damaged in the 2018 event.

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Section: Introductionsupporting

confidence: 65%

Field Survey of Tsunami Heights and Runups Following the 22 December 2018 Anak Krakatau Volcano Tsunami, Indonesia

Heidarzadeh

Putra

Nugroho

et al. 2020

Pure Appl. Geophys.

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“…It has reproduced well the run-up heights of tsunamis generated by submarine landslides in application to the case of Papua New Guinea earthquake in 1998 (Imamura and Hashi 2003). Pakoksung et al (2019) analyzed the 2018 Sulawesi earthquake using this type of model. The latter granular material models include Iverson and George (2014), Ma et al (2015), Grilli et al (2019) and Paris et al (2020), whose models' landslide part governed by Coulomb friction is originated from Savage and Hutter (1989).…”

Section: Numerical Model Of Landslide Mass and Tsunamimentioning

confidence: 80%

“…Pakoksung et al (2019) analyzed the 2018 Sulawesi earthquake using this type of model. The latter granular material models include Iverson and George (2014), Ma et al (2015), Grilli et al (2019) and Paris et al (2020), whose models' landslide part governed by Coulomb friction is originated from Savage and Hutter (1989). Grilli et al (2019) and Paris et al (2020) applied this type of model to the case of Krakatau in 2018, demonstrating mass and tsunami behavior well.…”

Section: Numerical Model Of Landslide Mass and Tsunamimentioning

confidence: 99%

“…The latter granular material models include Iverson and George (2014), Ma et al (2015), Grilli et al (2019) and Paris et al (2020), whose models' landslide part governed by Coulomb friction is originated from Savage and Hutter (1989). Grilli et al (2019) and Paris et al (2020) applied this type of model to the case of Krakatau in 2018, demonstrating mass and tsunami behavior well. Grilli et al (2019) also showed that tsunami waveforms at points far away from the source did not show much difference between the two models, dense Newtonian fluid model and granular material model.…”

Section: Numerical Model Of Landslide Mass and Tsunamimentioning

confidence: 99%

“…Various tsunami sources have been modeled based on seismic data [Heidarzadeh et al (2019), using data from USGS (2018), Ulrich et al (2019)], Sentinel-2 satellite optical data (Jamelot et al 2019), Sentinel-1 satellite SAR images (Gusman et al 2019), and hypothetical submarine landslides (Pakoksung et al 2019). Although those studies compared calculated tsunami waveforms with the Pantoloan tide gauge record and tsunami heights determined by field surveys, a detailed comparison with tsunami heights over the entire bay has not been performed except for Ulrich et al (2019), and little quantitative consideration has been given to the video footage.…”

Section: Introductionmentioning

confidence: 99%

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Submarine landslide source models consistent with multiple tsunami records of the 2018 Palu tsunami, Sulawesi, Indonesia

Nakata

Katsumata

Muhari

2020

Earth Planets Space

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Previous studies have suggested submarine landslides as sources of the tsunami that damaged coastal areas of Palu Bay after the 2018 Sulawesi earthquake. Indeed, tsunami run-up heights as high as 10 m determined by field surveys cannot be explained by the earthquake source alone although the earthquake is definitely the primary cause of the tsunami. The quantitatively reexamined results using the earthquake fault models reported so far showed that none of them could fully explain the observed tsunami data: tsunami waveforms inferred from video footage and the field survey run-up tsunami height distribution. Here, we present probable tsunami source models including submarine landslides that are consistent with the observed tsunami data. We simulated tsunamis generated by submarine landslides using a simplified depth-averaged two-dimensional model. The estimated submarine landslide model consisted of two sources in the northern and southern parts of the bay, and it explained the observed tsunami data well. Their volumes were 0.02 and 0.07 km 3. The radius of the major axis and the maximum thickness of the initial paraboloid masses and the maximum horizontal velocity of the masses were 0.8 km, 40 m and 21 m/s in the northern bay, and 2.0 km, 15 m and 19 m/s in the southern bay, respectively. The landslide source in the northern bay needed to start to move about 70 s after the earthquake to match the calculated and observed arrival times.

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Numerical Simulation of Submarine Landslide-Induced Tsunami Using Two-Layer Extended Boussinesq Equations

Pham,

Vu,

Lee

2023

Proceedings of the 4th International Conference on Sustainability in Civil Engineering

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The December 22, 2018 Anak Krakatau, Indonesia, Landslide and Tsunami: Preliminary Modeling Results

Cited by 64 publications

References 63 publications

Field Survey of Tsunami Heights and Runups Following the 22 December 2018 Anak Krakatau Volcano Tsunami, Indonesia

Field Survey of Tsunami Heights and Runups Following the 22 December 2018 Anak Krakatau Volcano Tsunami, Indonesia

Submarine landslide source models consistent with multiple tsunami records of the 2018 Palu tsunami, Sulawesi, Indonesia

Numerical Simulation of Submarine Landslide-Induced Tsunami Using Two-Layer Extended Boussinesq Equations

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