Defining local extreme heat thresholds and Indoor Cooling Degree Necessity for vulnerable residential dwellings during the 2020 summer in Ankara – Part I: Air temperature

AbstractExtreme heat is a leading cause of weather-related human mortality. The urban heat island (UHI) can magnify heat exposure in metropolitan areas. This study investigates the ability of a new MODIS-retrieved near-surface air temperature and humidity dataset to depict urban heat patterns over metropolitan Chicago, Illinois, during June–August 2003–13 under clear-sky conditions. A self-organizing mapping (SOM) technique is used to cluster air temperature data into six predominant patterns. The hottest heat patterns from the SOM analysis are compared with the 11-summer median conditions using the urban heat island curve (UHIC). The UHIC shows the relationship between air temperature (and dewpoint temperature) and urban land-use fraction. It is found that during these hottest events 1) the air temperature and dewpoint temperature over the study area increase most during nighttime, by at least 4 K relative to the median conditions; 2) the urban–rural temperature/humidity gradient is decreased as a result of larger temperature and humidity increases over the areas with greater vegetation fraction than over those with greater urban fraction; and 3) heat patterns grow more rapidly leading up to the events, followed by a slower return to normal conditions afterward. This research provides an alternate way to investigate the spatiotemporal characteristics of the UHI, using a satellite remote sensing perspective on air temperature and humidity. The technique has potential to be applied to cities globally and provides a climatological perspective on extreme heat that complements the many case studies of individual events.

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Comparisons of the Circulation Anomalies Associated with Extreme Heat in Different Regions of Eastern China

Journal of Climate ◽

10.1175/jcli-d-14-00818.1 ◽

2015 ◽

Vol 28 (14) ◽

pp. 5830-5844 ◽

Cited By ~ 32

Author(s):

Ruidan Chen ◽

Riyu Lu

Keyword(s):

Air Temperature ◽

North China ◽

Eastern China ◽

Lower Troposphere ◽

Circulation Pattern ◽

Extreme Heat ◽

Typical Pattern ◽

Upper Troposphere ◽

Anomalous Anticyclone ◽

The Many

Abstract The circulation associated with extreme heat (EH) typically shows an anomalous anticyclone that enhances temperature through adiabatic heating, but this study indicates obvious spatial variation in eastern China. The EH-related circulation pattern in eastern China can be classified into three categories: typical extratropical pattern, monsoonal pattern, and foehn pattern. EH over northeastern China and eastern north China is characterized by a typical pattern involving an anomalous anticyclone and subsidence, and the air temperature increases throughout almost the entire troposphere. In contrast, EH over the Yangtze River valley and south China is associated with the monsoonal pattern. Over these regions, the air temperature only increases in the lower troposphere as a result of anomalous subsidence and lower humidity that has resulted from a farther north transportation of water vapor by a stronger monsoonal southwesterly. Meanwhile, the air temperature decreases in the upper troposphere because of the decrease of latent heat caused by suppressed precipitation. On the other hand, western north China, with most of its stations located on the eastern leeside of mountains, is obviously influenced by the foehn effect on EH days. The foehn-related northwesterly anomalies bring drier and warmer air from the mountains to sink on the leeside and greatly increase the air temperature in the lower troposphere, particularly near the surface. Therefore, the impacts of monsoon and topography should be taken into consideration when EH-related circulations are discussed over the many regions of eastern China. As a result, the reliable projection of air temperature in these regions under global warming is a challenging problem.

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Changes in the Compound Drought and Extreme Heat Occurrence in the 1961–2018 Period at the European Scale

Water ◽

10.3390/w12123543 ◽

2020 ◽

Vol 12 (12) ◽

pp. 3543

Author(s):

Nejc Bezak ◽

Matjaž Mikoš

Keyword(s):

Eastern Europe ◽

Air Temperature ◽

Western Europe ◽

Balkan Peninsula ◽

Extreme Heat ◽

Extreme Weather Events ◽

Economic Damage ◽

Precipitation Trend ◽

Total Precipitation ◽

Continental Scale

Compound extreme weather events can cause large economic damage and endanger human lives. Therefore, identification of changes in such compound event frequency and magnitude is important information that could be useful for decision makers and practitioners in water management and agriculture sector. This is especially the case for dry hazards that can be significantly influenced by the increasing air temperature and can have significant impact on water availability and consumption as well as on agricultural production. This study investigated changes in the compound occurrence of drought and extreme heat at the European scale using Uncertainties in Ensembles of Regional Reanalyses (UERRA) regional reanalysis data for the 1961–2018 period. The effective drought index (EDI) and the air temperature percentile threshold were used for the identification of the compound events at the catchment scale where entire Europe was divided into more than 4000 catchments. The results revealed multiple hotspots of compound drought and extreme heat events such as parts of Western Europe, Italy, Balkan Peninsula and Northern and Eastern Europe. At the continental scale, no uniform trend pattern could be detected. However, multiple areas with either positive or negative changes were identified. A positive change was characteristic for parts of Western Europe, Italy, Balkan Peninsula, etc. In these cases, the trend was mostly driven by the decreasing total precipitation trend and was not directly affected by the increasing air temperature trend. Areas with negative changes include parts of Northern and Eastern Europe and British Isles. In these cases, the detected trend was mostly driven by an increasing total precipitation trend. However, local drivers could be different.

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Spatial Distribution of Air Temperature during an Extreme Heat Period in Daegu Metropolitan Area in 2016

Journal of Environmental Science International ◽

10.5322/jesi.2017.26.9.1023 ◽

2017 ◽

Vol 26 (9) ◽

pp. 1023-1029 ◽

Cited By ~ 1

Author(s):

Ji-Hye Kim ◽

Hae-Dong Kim

Keyword(s):

Spatial Distribution ◽

Air Temperature ◽

Metropolitan Area ◽

Extreme Heat ◽

Heat Period

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Local Extreme Heat Planning: an Interactive Tool to Examine a Heat Vulnerability Index for Philadelphia, Pennsylvania

Journal of Urban Health ◽

10.1007/s11524-020-00443-9 ◽

2020 ◽

Vol 97 (4) ◽

pp. 519-528

Author(s):

Jason Hammer ◽

Dominique G. Ruggieri ◽

Chad Thomas ◽

Jessica Caum

Keyword(s):

Vulnerability Index ◽

Extreme Heat ◽

Interactive Tool ◽

Heat Vulnerability ◽

Heat Vulnerability Index ◽

Local Extreme

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Increased Frequency of Summer Extreme Heat Waves over Texas Area Tied to the Amplification of Pacific Zonal SST Gradient

Journal of Climate ◽

10.1175/jcli-d-17-0554.1 ◽

2018 ◽

Vol 31 (14) ◽

pp. 5629-5647 ◽

Cited By ~ 12

Author(s):

Kaiqiang Deng ◽

Mingfang Ting ◽

Song Yang ◽

Yaheng Tan

Keyword(s):

Air Temperature ◽

General Circulation ◽

Heat Waves ◽

Linear Trend ◽

Surface Air Temperature ◽

Circulation Model ◽

Summer Precipitation ◽

Extreme Heat ◽

Vapor Flux ◽

Sst Gradient

Abstract Summer extreme heat waves (EHWs) over the Texas area and their trend are investigated using observations and atmospheric general circulation model (AGCM) output. There is a positive linear trend in Texas EHW days for the period 1979–2015. While the interannual variability of the Texas EHWs is linked to ENSO conditions, the upward trend in Texas EHWs is found to be significantly associated with the tropical Pacific zonal SST gradient (PZSSTG). The amplification of PZSSTG leads to both enhanced convection in the western Pacific and suppressed convection in the central-eastern Pacific (i.e., La Niña–like pattern), both of which can induce anomalous anticyclones over the Texas area through two distinct planetary wave trains in the antecedent spring. As a result, anomalously sinking motions and divergent water vapor flux appear over the Texas area, which reduce precipitation and increase downward solar radiation, leading to dry and hot soil that favors the occurrence of Texas summer EHWs. In addition, all AGCMs using observed SSTs as boundary conditions were able to simulate the observed decreasing trend in Texas summer precipitation and the observed increasing trend in Texas summer surface air temperature. The observed relationships between winter PZSSTG and the following spring–summer Texas precipitation/temperature were also reproduced by these models, where the intensified PZSSTG tended to reduce the Texas precipitation while increasing the surface air temperature.

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