Urban intensification of convective rainfall over the <scp>Singapore</scp> – <scp>Johor Bahru</scp> region

Simón-Moral, Andrés; Dipankar, Anurag; Doan, Quang‐Van; Sánchez, Claudio; Roth, Matthias; Becker, Erik; Huang, Xiang‐Yu

doi:10.1002/qj.4147

Cited by 12 publications

(6 citation statements)

References 60 publications

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“…Note that precipitation, especially that in midlatitude regions, is caused by the interaction of multiscale atmospheric phenomena, making the respective urban signal is difficult to detect (Oke et al., 2017). It is in contrast to the urban effect found for tropical cities (Argüeso et al., 2016; Doan et al., 2021; Simón‐Moral et al., 2021; Wang et al., 2015). Also, because the urban signal is relatively small, usually falling into the uncertainty range of the global warming effect, detecting its change in the global warming context is considerably more difficult.…”

Section: Resultscontrasting

confidence: 67%

Identifying a New Normal in Extreme Precipitation at a City Scale Under Warmer Climate Regimes: A Case Study of the Tokyo Metropolitan Area, Japan

et al. 2022

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Densely populated cities with high wealth concentration are particularly vulnerable to weather hazards, such as extreme precipitation (EP). EP causes urban flooding, which results in tremendous socio-economic losses (IPCC AR6, 2022). Understanding the nature of EP and its potential changes in the future is essential to identify the respective risks in achieving the Sustainable Development Goals (UNDRR, 2019; United Nations, 2015). The Assessment Report six issued by the Intergovernmental Panel on Climate Change indicated strong evidence on modifications in extreme weather patterns, including heavy precipitation in every region worldwide. The emphasized requirement lies in identifying the change in EP events at the city scale under the "new normal" of warmer climates.

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Section: Resultscontrasting

confidence: 67%

Identifying a New Normal in Extreme Precipitation at a City Scale Under Warmer Climate Regimes: A Case Study of the Tokyo Metropolitan Area, Japan

et al. 2022

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“…The rainfall anomalies over this quadrant are statistically different from the other three quadrants (based on the Student's t test, P = 0.05, Figure S5a in Supporting Information ). The positive rainfall anomalies over the city (79.2% above the domain‐average, Figure S5a in Supporting Information ) might be partially associated with the enhanced convection driven by the elevated surface temperature within the urban canopy (e.g., Harnack & Landsberg, 1975; Shepherd, 2006; Simón‐Moral et al., 2021; Yuan et al., 2020). The second cluster of positive rainfall anomalies is associated with the mechanic perturbations of urban canopy through enhanced surface roughness (i.e., buildings) that leads to decelerated flows.…”

Section: Resultsmentioning

confidence: 99%

Divergent Urban Signatures in Rainfall Anomalies Explained by Pre‐Storm Environment Contrast

Shen

Yang

2023

Geophysical Research Letters

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Understanding urban impacts on hydrometeorological processes is becoming an emergent issue under the context of soaring urban population globally (UNPD, 2019). This is accompanied by ample evidence of elevated extreme rainfall and flood hazards under a changing climate, with urban areas most vulnerable (IPCC, 2021). Empirical and modeling analyses reveal notable urban-induced rainfall anomalies over a collection of worldwide cities, including the pioneering

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“…This case is a typical rainstorm concentrated in the urban. Many studies have analyzed the causes of this and its impact on surrounding areas (Simón‐Moral et al., 2021; Y. Yuan et al., 2020; Yue et al., 2021). The surface pressure gradient, driven by the thermal contrast between urban areas and their suburban/rural counterparts, intensifies and focuses rainfall in urban regions.…”

Section: Discussionmentioning

confidence: 99%

“…This case is a typical rainstorm concentrated in the urban. Many studies have analyzed the causes of this and its impact on surrounding areas (Simón-Moral et al, 2021;Y. Yuan et al, 2020;Yue et al, 2021).…”

Section: Case Studymentioning

confidence: 99%

The Spatiotemporal Clustering of Short‐Duration Rainstorms in Shanghai City Using a Sub‐Hourly Gauge Network

Lei,

Gao,

Liu

et al. 2024

Earth and Space Science

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Impacted by both the large‐scale climate change and the local hydrometeorological atmosphere, the spatiotemporal structure and properties of short‐duration extreme rainfall events in urban areas remain a complex issue. This study explores the spatiotemporal pattern variability of short‐duration rainstorm events using an exceptional sub‐hourly gauge network in Shanghai, China. A catalog of 207 “independent” rainstorms is extracted. The hierarchical clustering method is used to examine the spatial and temporal features including rainfall duration, intensity, and coverage for each district with different degrees of urbanization in the 2014–2018 period. The results point to a pronounced spatial heterogeneity with heavier rainfall magnitude in the north. In the urban core area, intensive short‐duration rainstorms hit more frequently than in other districts. Rainstorms can be divided into three types from the spatiotemporal process: Type delayed‐slow, Type advanced‐fast, and Type advanced‐slow. The delayed‐peak with a higher slope occurs more in the west and the advanced‐peak more along the coastal line. The other type of advanced‐peak storm with a reverse trend of intensity and coverage concentrates in June–August of the year and the 16:00–20:00 of the day. While 65.6% of the delayed‐peak storms only occur in one district, more than half of the advanced‐peak appear without other types at the same time. These findings show the importance of observation‐based analysis in understanding the spatiotemporal pattern of short‐duration storms and provide a reference for storm design of sub‐regions in urban areas.

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Urban intensification of convective rainfall over the Singapore – Johor Bahru region

Cited by 12 publications

References 60 publications

Identifying a New Normal in Extreme Precipitation at a City Scale Under Warmer Climate Regimes: A Case Study of the Tokyo Metropolitan Area, Japan

Identifying a New Normal in Extreme Precipitation at a City Scale Under Warmer Climate Regimes: A Case Study of the Tokyo Metropolitan Area, Japan

Divergent Urban Signatures in Rainfall Anomalies Explained by Pre‐Storm Environment Contrast

The Spatiotemporal Clustering of Short‐Duration Rainstorms in Shanghai City Using a Sub‐Hourly Gauge Network

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