Atmospheric Contributors to Heavy Rainfall Events in the Arkansas-Red River Basin

This study analyzed the top 1% 24-hour rainfall events from 1994 to 2013 at eight climatological sites that represent the east to west precipitation gradient across the Arkansas-Red River Basin in North America. A total of 131 cases were identified and subsequently classified on the synoptic-scale, mesoscale, and local-scale to compile a climatological analysis of these extreme, heavy rainfall events based on atmospheric forcings. For each location, the prominent midtropospheric pattern, mesoscale feature, and predetermined thermodynamic variables were used to classify each 1% rainfall event. Individual events were then compared with other cases throughout the basin. The most profound results were that the magnitudes of the thermodynamic variables such as convective available potential energy and precipitable water values were poor predictors of the amount of rainfall produced in these extreme events. Further, the mesoscale forcings had more of an impact during the warm season and for the westernmost locations, whereas synoptic forcings were extremely prevalent during the cold season at the easternmost locations in the basin. The implications of this research are aimed at improving the forecasting of heavy precipitation at individual weather forecasts offices within the basin through the identified patterns at various scales.

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Diverse synoptic weather patterns of warm-season heavy rainfall events in South Korea

Monthly Weather Review ◽

10.1175/mwr-d-20-0388.1 ◽

2021 ◽

Author(s):

Chanil Park ◽

Seok-Woo Son ◽

Joowan Kim ◽

Eun-Chul Chang ◽

Jung-Hoon Kim ◽

...

Keyword(s):

North Pacific ◽

Moisture Transport ◽

Heavy Rainfall ◽

Eastern China ◽

Warm Season ◽

Sea Level Pressure ◽

Rainfall Events ◽

Weather Patterns ◽

Synoptic Weather ◽

Heavy Rainfall Events

AbstractThis study identifies diverse synoptic weather patterns of warm-season heavy rainfall events (HREs) in South Korea. The HREs not directly connected to tropical cyclones (TCs) (81.1%) are typically associated with a midlatitude cyclone from eastern China, the expanded North Pacific high and strong southwesterly moisture transport in between. They are frequent both in the first (early summer) and second rainy periods (late summer) with impacts on the south coast and west of the mountainous region. In contrast, the HREs resulting from TCs (18.9%) are caused by the synergetic interaction between the TC and meandering midlatitude flow, especially in the second rainy period. The strong south-southeasterly moisture transport makes the southern and eastern coastal regions prone to the TC-driven HREs. By applying a self-organizing map algorithm to the non-TC HREs, their surface weather patterns are further classified into six clusters. Clusters 1 and 3 exhibit frontal boundary between the low and high with differing relative strengths. Clusters 2 and 5 feature an extratropical cyclone migrating from eastern China under different background sea-level pressure patterns. Cluster 4 is characterized by the expanded North Pacific high with no organized negative sea-level pressure anomaly, and cluster 6 displays a development of a moisture pathway between the continental and oceanic highs. Each cluster exhibits a distinct spatio-temporal occurrence distribution. The result provides useful guidance for predicting the HREs by depicting important factors to be differently considered depending on their synoptic categorization.

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Capturing the signature of heavy rainfall events using the 2-d-/4-d water vapour information derived from GNSS measurement in Hong Kong

10.5194/angeo-2018-76 ◽

2018 ◽

Author(s):

Qingzhi Zhao ◽

Yibin Yao ◽

Wanqiang Yao

Keyword(s):

Hong Kong ◽

Water Vapour ◽

Heavy Rainfall ◽

Precipitable Water ◽

Atmospheric Water ◽

Precipitable Water Vapour ◽

Rainfall Events ◽

Atmospheric Water Vapour ◽

Tomographic Technique ◽

Heavy Rainfall Events

Abstract. Apart from the well-known applications like positioning, navigation and timing (PNT), Global Navigation Satellite System (GNSS) has manifested its ability in many other areas that are vital to society largely. With the dense setting of the regional continuously operating reference station (CORS) networks, monitoring the variations in atmospheric water vapour using a GNSS technique has become the focus in the field of GNSS meteorology. Most previous studies mainly concentrate on the analysis of relationship between the two-dimensional (2-d) Precipitable Water Vapour (PWV) and rainfall while the four-dimensional (4-d) variations of atmospheric water vapour derived from the GNSS tomographic technique during rainfall events are rarely discussed. This becomes the focus of this work, which investigates the emerging field of GNSS technology for monitoring changes in atmospheric water vapour during rainfall, especially in the vertical direction. This paper includes an analysis of both 2-d, and 4-d, precipitable water vapour profiles. A period with heavy rainfall events in this study was selected to capture the signature of atmospheric water vapour variation using the ground-based GNSS tomographic technique. GNSS observations from the CORS network of Hong Kong were used. Analysed results of the 2-d PWV/4-d water vapour profiles change during the arrival, occurrence, and depression of heavy rainfall show that: (i) the PWV time series shows an increasing trend before the arrival of heavy rainfall and decreases to its average value after the depression of rainfall; (ii) rainfall leads to an anomalous variation in relative humidity and temperature while their trends are totally opposite and show daily periodicity for periods without rain (this is highly correlated with the changes in solar radiation); (iii) atmospheric water vapour presents unstable conditions with intense vertical convective motion and hydrometeors are formed before the arrival of rainfall while returning to relatively stable conditions during heavy rainfall. This study indicates the potential for using GNSS-derived 2-d PWV and 4-d profiles to monitor spatio-temporal variations in atmospheric water vapour during rainfall, which provides a better understanding of the mechanism of convection and rainfall induced by the extreme weather events.

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Characteristics of warm season precipitating storms in the Arkansas–Red River basin

Journal of Geophysical Research Atmospheres ◽

10.1029/2008jd011093 ◽

2009 ◽

Vol 114 (D13) ◽

Cited By ~ 9

Author(s):

Donna F. Tucker ◽

Xingong Li

Keyword(s):

River Basin ◽

Warm Season ◽

Red River ◽

Red River Basin

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Variability and Trends of Daily Heavy Rainfall Events over Niger River Basin Development Authority Area in Nigeria

American Journal of Climate Change ◽

10.4236/ajcc.2014.31001 ◽

2014 ◽

Vol 03 (01) ◽

pp. 1-7 ◽

Cited By ~ 6

Author(s):

Joseph Sunday Babatolu ◽

Rufus Temidayo Akinnubi ◽

Akintade Taiwo Folagimi ◽

Omosuyi Oluwayemisi Bukola

Keyword(s):

River Basin ◽

Heavy Rainfall ◽

Rainfall Events ◽

Basin Development ◽

River Basin Development ◽

Authority Area ◽

Niger River ◽

Heavy Rainfall Events

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Heavy Rainfall Events over Central Oahu under Weak Wind Conditions during Seasonal Transitions

Monthly Weather Review ◽

10.1175/mwr-d-19-0358.1 ◽

2020 ◽

Vol 148 (10) ◽

pp. 4117-4141

Author(s):

Feng Hsiao ◽

Yi-Leng Chen ◽

David Eugene Hitzl

Keyword(s):

Mixed Layer ◽

Land Surface ◽

Heavy Rainfall ◽

Large Scale ◽

Subsequent Development ◽

Precipitable Water ◽

Trade Wind ◽

Heavy Rainfall Event ◽

Rainfall Events ◽

Heavy Rainfall Events

AbstractShort-lived afternoon heavy rainfall events may form over central Oahu during seasonal transition periods (June and October) under favorable large-scale settings. These include a deep moist layer with relatively high precipitable water (>40 mm), blocking pattern in midlatitudes with a northeast–southwest moist tongue from low latitudes ahead of an upper-level trough, absence of a trade wind inversion, and weak (<3 m s−1) low-level winds. Our high-resolution (1.5 km) model results show that immediately before the storm initiation, daytime land surface heating deepens the mixed layer over central Oahu and the top of the mixed layer reaches the lifting condensation level. Meanwhile, the development of onshore/sea-breeze flows, driven by land–sea thermal contrast, brings in moist maritime air over the island interior. Finally, convergence of onshore flows over central Oahu provides the localized lifting required for the release of instability. Based on synoptic and observational analyses, nowcasting with a lead time of 2–3 h ahead of this type of event is possible. In the absence of orographic effects after removing model topography, processes that lead to heavy rainfall are largely unchanged, and subsequent development of heavy showers over central Oahu are still simulated. However, when surface heat and moisture fluxes are turned off, convective cells are not simulated in the area. These results indicate that daytime heating is crucial for the development of this type of heavy rainfall event under favorable large-scale settings.

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