Sensitivity of Midlatitude Heavy Precipitation to SST: A Case Study in the Sea of Japan Area on 9 August 2013

Iizuka, Satoshi; Nakamura, Hisashi

doi:10.1029/2018jd029503

Cited by 22 publications

(21 citation statements)

References 38 publications

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“…Episodes involving ≥ 100 mm in 24 h are more frequent but sometimes have no direct impact or quite a negligible effect, because other factors are the main drivers of floods, e.g. precipitation duration (Jang, 2015), initial soil moisture conditions and hydrological parameters (Norbiato et al, 2008;Martina et al, 2009). Furthermore, the area affected by episodes of ≥ 100 mm in 24 h is sometimes local and is therefore not easily associated with advective synoptic patterns (Gilabert and Llasat, 2018).…”

Section: Selection Of Torrential Eventsmentioning

confidence: 99%

“…Seawater constitutes an energy store, i.e. recharge areas, which can influence water vapour content and can intensify precipitation episodes (Pastor et al, 2018;Iizuka and Nakamura, 2019) by means of a sea-atmosphere moisture exchange. Furthermore, a significant release of latent heat occurs during atmospheric convection over a warm sea like the Mediterranean at the end of summer and the beginning of autumn (Pastor et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Intra-annual variability of the Western Mediterranean Oscillation (WeMO) and occurrence of extreme torrential precipitation in Catalonia (NE Iberia)

López-Bustins

Arbiol-Roca

Martín‐Vide

et al. 2020

Nat. Hazards Earth Syst. Sci.

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Abstract. In previous studies the Western Mediterranean Oscillation index (WeMOi) at daily resolution has proven to constitute an effective tool for analysing the occurrence of episodes of torrential precipitation over eastern Spain. The western Mediterranean region is a very sensitive area, since climate change can enhance these weather extremes. In the present study we created a catalogue of the extreme torrential episodes (≥200 mm in 24 h) that took place in Catalonia (NE Iberia) during the 1951–2016 study period (66 years). We computed daily WeMOi values and constructed WeMOi calendars. Our principal result reveals the occurrence of 50 episodes (0.8 cases per year), mainly concentrated in the autumn. We confirmed a threshold of WeMOi ≤ −2 to define an extreme negative WeMO phase at daily resolution. Most of the 50 episodes (60 %) in the study area occurred on days presenting an extreme negative WeMOi value. Specifically, the most negative WeMOi values are detected in autumn, from 11 to 20 October, coinciding with the highest frequency of extreme torrential events. On comparing the subperiods, we observed a statistically significant decrease in WeMOi values in all months, particularly in late October and in November and December. No changes in the frequency of these extreme torrential episodes were observed between both subperiods. In contrast, a displacement of the extreme torrential episodes is detected from early to late autumn; this can be related to a statistically significant warming of sea temperature.

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Section: Selection Of Torrential Eventsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Intra-annual variability of the Western Mediterranean Oscillation (WeMO) and occurrence of extreme torrential precipitation in Catalonia (NE Iberia)

López-Bustins

Arbiol-Roca

Martín‐Vide

et al. 2020

Nat. Hazards Earth Syst. Sci.

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“…Particular attention has been devoted to the role that SST structures have on heavy precipitation events in the Mediterranean, where widespread coastal urbanisation leads to large exposure of population and infrastructure to intense weather events. While the total amount of rain is not influenced much by the spatial resolution of the SST forcing field (Millán et al ., ; Pastor et al ., ; Lebeaupin et al ., ; Cassola et al ., ), numerical studies show that the spatial structure of the heat fluxes and the position of the rain bands can be influenced (Katsafados et al ., ; Ricchi et al ., ; Rainaud et al ., ; Meroni et al ., ; Iizuka and Nakamura, ). The landward moisture fluxes can also be influenced by the mesoscale SST structures on seasonal scales, as shown by the numerical work of Desbiolles et al .…”

Section: Introductionmentioning

confidence: 98%

Observational evidence of the preferential occurrence of wind convergence over sea surface temperature fronts in the Mediterranean

Meroni

Giurato

Ragone

et al. 2020

Quart J Royal Meteoro Soc

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Air and sea interact on a wide range of scales, shaping climate and influencing weather. The direct effect of sea surface temperature (SST) structures on the extratropical atmosphere at the daily time-scale is generally masked by the large variability associated with atmospheric dynamics. With 25 years of daily SST and surface wind observational products, obtained with data from buoys, satellite and atmospheric analysis in the Mediterranean, we show that strong surface wind convergence preferentially occurs when the air encounters a cold SST front. The mechanism responsible for the influence of ocean fronts on surface winds is rooted in the thermal disequilibrium that emerges at the air-sea interface, where cold water enhances the stability of the boundary layer, decoupling surface winds from the stronger winds aloft. Surface convergence drives upward motion which, under appropriate conditions, favours cloud formation. Thus, these results suggest that weather forecast models need to properly represent the small-scale ocean thermal structures, which could affect rainfall. K E Y W O R D Sair-sea interactions, climatology, wind response

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“…Recent studies have shown that the midlatitude ocean, especially the Kuroshio Current, is critical to the occurrence of heavy rainfall events around Japan (Miyama et al 2012;Manda et al 2014;Iizuka and Nakamura 2019;Sekizawa et al 2019;Yamamoto 2020). Miyama et al (2012) examined a convective rainband that developed along the Kuroshio Current over the East China Sea in May 2010 and found that the high sea surface temperature (SST) of the Kuroshio Current intensified the rainband by decreasing static stability.…”

Section: Introductionmentioning

confidence: 99%

Kuroshio-Enhanced Convective Rainband Associated with an Extratropical Cyclone in the Cold Season

Hirata

Kawamura

Nonaka

et al. 2021

Journal of the Meteorological Society of Japan

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This study examined the roles of heat fluxes from the Kuroshio Current in enhancing a frontal convective rainband associated with an extratropical cyclone that brought record-breaking heavy rainfall to Miyake Island, Japan, in January 2017. A simulation of the rainband (control experiment) and sensitivity experiments without the sensible and latent heat fluxes from the Kuroshio Current were conducted using a regional cloud-resolving model. The rainband developed along a non-classic front (outer front), which formed to the north of a warm front associated with the cyclone. The control experiment reproduced the intensity and migration of the rainband well. As the rainband developed, the heat fluxes from the Kuroshio Current became evident around the cold conveyor belt of the cyclone to the south of the rainband. The latent heat fluxes were ~2.3 times larger than the sensible heat fluxes. Comparisons between the control and sensitivity experiments demonstrated that the heat fluxes, especially the latent heat fluxes, enhanced the rainband. The sensible heat fluxes slightly intensified convective instability in the lower troposphere, whereas the latent heat fluxes significantly increased the near-surface moisture content and the convective instability. A frontal updraft along the outer front released the increased convective instability, which intensified the moisture convergence, condensation, and updraft, enhancing the rainband. The findings show that the heat fluxes from the Kuroshio Current, especially the latent 3 heat fluxes, enhanced the heavy rainfall-producing rainband by increasing the moisture content and the convective instability.

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Sensitivity of Midlatitude Heavy Precipitation to SST: A Case Study in the Sea of Japan Area on 9 August 2013

Cited by 22 publications

References 38 publications

Intra-annual variability of the Western Mediterranean Oscillation (WeMO) and occurrence of extreme torrential precipitation in Catalonia (NE Iberia)

Intra-annual variability of the Western Mediterranean Oscillation (WeMO) and occurrence of extreme torrential precipitation in Catalonia (NE Iberia)

Observational evidence of the preferential occurrence of wind convergence over sea surface temperature fronts in the Mediterranean

Kuroshio-Enhanced Convective Rainband Associated with an Extratropical Cyclone in the Cold Season

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