Abstract
Flash flooding is an important issue as it has a devastating impact over a short time and in a limited area. However, predicting flash floods is challenging because they are connected to convection systems that rapidly evolve and require a high-resolution forecasting system. In addition, modeling a case study of a mesoscale convective complex (MCC) is the key to improving our understanding of the heavy rainfall systems that trigger flash floods. In this study, we aim at improving modeling skills to simulate a heavy rainfall system related to flash-flood-producing MCCs. We simulated a heavy rainfall event related to a severe flash flood in Luwu, Sulawesi, Indonesia, on 13 July 2020. This flood was preceded by persistent heavy rainfall from 11 to 13 July 2020. In this case, we investigated the role of sea surface temperature (SST) in producing the persistent heavy rainfall over the region. Therefore, we explore the physical and dynamic processes that caused the heavy rainfall using a convection-permitting model with 1 km resolution and an experiment comparing the situation with and without updated SST. The results show that the heavy rainfall was modulated by the development of a pair of MCCs during the night. The pair of MCCs was triggered by a meso-low-pressure system with an anti-cyclonic circulation anomaly over the Makassar Strait and was maintained by the warm front passing between the sea and land over central Sulawesi. This front was characterized by moist–warm and cold–dry low-level air, which may have helped extend the lifetime of the MCCs. The north-westward propagation of the MCCs was due to the interaction between predominantly a south-easterly monsoon and SST anomalies. This study suggested that the long-lived (>10 h) MCCs (>80,000 km2 cloud shield) and persistent precipitation are reproduced well in the updated SST scenario in the WRF model. This relatively simple technique in the running model provides a new strategy for improving flash flood forecasting by better predicting rainfall as an input in the hydrological model. Our findings also indicated a long-lived MCC maintained by back-building mechanisms from night to morning inland as an exceptional MCC, which does not correspond to a previous study.
Highlights
Flash flooding is the most hazardous weather-related event with a tremendous impact on affected areas, leading to infrastructure destruction and loss of life [1,2]
We investigated the hypothesis that sea surface temperature (SST) may control the diurnal rainfall over Sulawesi Island by conducting experiments with two scenarios: (1) the default model is run without updating the SST, which is referred to as the control simulation (CTL), and (2) the model is run with the SST updated every 6 h
FBiMguKFrGeig2stu.a(rtaie)onM2s.a(pb(laou)fetMlhineaeB)pManoKdfGatvshteaertaigoBenMclouKcmaGutiloasnttisavoetivroeanrinSfluaollalcwaamteisooiunInssltaconodvm.ep(rbu)SteCudulaomnwutlehasetiiDvIe0s3rlaadinnofdma.lali(anbm()bolCuacnuktmrlienuceol)radftreiovdmea1tr0Latuionw1fu7all July a20m20o.u(cn)tSrpeactioarl dmeadp aoft tLhue wintuerBpoMlaKteGd csutmatuiolantisve(bdlauiley lrianinef)alalnddataavfreormagseevceuraml BuMlaKtGivsetartaioinnsf.all amount computed on the D03 domain from 10 to 17 July 2020. (c) Spatial map of the interpolated cumulative daily rainfalTl hdiasthaefarvoymrasienvfaelrlaolcBcuMrrKedGinstatmioensso.-low-pressure system with anticyclonic circulation at about 100 km to the south of the equator over the Makassar Strait (Figure 3a)
Summary
Flash flooding is the most hazardous weather-related event with a tremendous impact on affected areas, leading to infrastructure destruction and loss of life [1,2]. We simulated selected episodes of heavy rainfall events from 13 to 14 July 2020 associated with a flash flood in the Luwu region, Sulawesi, Indonesia.
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