Quantifying Local and Mesoscale Drivers of the Urban Heat Island of Moscow with Reference and Crowdsourced Observations

Varentsov, Mikhail; Fenner, Daniel; Meier, Fred; Samsonov, Timofey; Demuzere, Matthias

doi:10.3389/fenvs.2021.716968

Cited by 20 publications

(16 citation statements)

References 115 publications

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“…We chose to perform this simplification to avoid losing additional data after performing our quality-check and filtering. Nevertheless, micro-and mesoscale effects are known to affect measurements in air temperature at local scales (Fenner et al 2017, Skarbit et al 2017, Quanz et al 2018, Varentsov et al 2021-something that has to be kept in mind in our further analysis. Besides, we normalize the temperature observations by height, following Potgieter et al (2021), to get rid of the vertical thermal gradient.…”

Section: Air Temperature Measurements: Netatmo Citizen Weather Stationsmentioning

confidence: 99%

“…High degrees of intra-LCZ variability under different wind conditions are thus observed, meaning that while the median anomaly can be positive, certain CWS in an area with similar land-use land-covers will measure a negative anomaly. This could potentially be explained by important micro-scale effects, undetected by the simplified LCZ classification (Fenner et al 2017, Skarbit et al 2017, Varentsov et al 2021. Highest degrees of intra-LCZ variability are observed in open low-rise (LCZ 6), and more natural LCZ, like sparsely built (LCZ 9), dense trees (LCZ A), sparse trees (LCZ B) and low vegetation (LCZ D).…”

Section: Influence Of Wind Regime On Urban Heat Heterogeneity and Hea...mentioning

confidence: 99%

“…For example, recent studies (e.g. Fenner et al 2017, Potgieter et al 2021, Varentsov et al 2021 have used CWS to improve our understanding of the impact of landuse and land-cover on urban temperatures through the perspective of Local Climate Zones (LCZ; Stewart and Oke 2012)-a land-use and land-cover classification specifically developed for urban climate studies. Others have used CWS to validate urban climate simulations (Hammerberg et al 2018), drive indoortemperatures in urban climate simulations (Jin et al 2021), and model air temperatures in European cities using machine learning (Venter et al 2020, 2021, Vulova et al 2020, Zumwald et al 2021.…”

Section: Introductionmentioning

confidence: 99%

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Evidence of horizontal urban heat advection in London using six years of data from a citizen weather station network

Brousse

Simpson

Walker

et al. 2022

Environ. Res. Lett.

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Recent advances in citizen weather station (CWS) networks, with data accessible via crowd-sourcing, provide relevant climatic information to urban scientists and decision makers. In particular, CWS can provide long-term measurements of urban heat and valuable information on spatio-temporal heterogeneity related to horizontal heat advection. In this study, we make the first compilation of a quasi-climatologic dataset covering 6 years (2015–2020) of hourly near-surface air temperature measurements obtained via 1560 suitable CWS in a domain covering south-east England and Greater London. We investigated the spatio-temporal distribution of urban heat and the influences of local environments on climate, captured by CWS through the scope of Local Climate Zones (LCZ) – a land-use land-cover classification specifically designed for urban climate studies. We further calculate, for the first time, the amount of advected heat captured by CWS located in Greater London and the wider south east England region. We find that London is on average warmer by about 1.0 °C to 1.5 °C than the rest of south-east England. Characteristics of the southern coastal climate are also captured in the analysis. We find that on average, urban heat advection (UHA) contributes to 0.22±0.96 °C of the total urban heat in Greater London. Certain areas, mostly in the centre of London are deprived of urban heat through advection since heat is transferred more to downwind suburban areas. UHA can positively contribute to urban heat by up to 1.57 °C, on average and negatively by down to -1.21 °C. Our results also show an important degree of inter- and intra-LCZ variability in UHA, calling for more research in the future. Nevertheless, we already find that UHA can impact green areas and reduce their cooling benefit. Such outcomes show the added value of CWS when considering future urban design.

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Section: Air Temperature Measurements: Netatmo Citizen Weather Stationsmentioning

confidence: 99%

Section: Influence Of Wind Regime On Urban Heat Heterogeneity and Hea...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Evidence of horizontal urban heat advection in London using six years of data from a citizen weather station network

Brousse

Simpson

Walker

et al. 2022

Environ. Res. Lett.

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show abstract

“…All CWS available in the ROI were considered in the application of CrowdQC and CrowdQC+. For comparison between CWS and PRWS, an LCZ was assigned to each station following Fenner et al (2017) and Varentsov et al (2021), using the geographical position of each station and the LCZ maps. First, the nearest-pixel LCZ value was assigned to each station.…”

Section: Classification Of Stations To Local Climate Zonesmentioning

confidence: 99%

“…Second, for a buffer with a radius of 250 m around each station, the surface-cover fraction of the modal LCZ was calculated (using pixels of the LCZ map). Third, a weighted surface-cover LCZ fraction in the same buffer was calculated (Varentsov et al, 2021), applying "similarity weights" (Figure 3B in Bechtel et al, 2020) between the modal LCZ and all other grid points (LCZ pixels) within the buffer.…”

Section: Classification Of Stations To Local Climate Zonesmentioning

confidence: 99%

CrowdQC+—A Quality-Control for Crowdsourced Air-Temperature Observations Enabling World-Wide Urban Climate Applications

Fenner

Bechtel

Demuzere

et al. 2021

Front. Environ. Sci.

Self Cite

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In recent years, the collection and utilisation of crowdsourced data has gained attention in atmospheric sciences and citizen weather stations (CWS), i.e., privately-owned weather stations whose owners share their data publicly via the internet, have become increasingly popular. This is particularly the case for cities, where traditional measurement networks are sparse. Rigorous quality control (QC) of CWS data is essential prior to any application. In this study, we present the QC package “CrowdQC+,” which identifies and removes faulty air-temperature (ta) data from crowdsourced CWS data sets, i.e., data from several tens to thousands of CWS. The package is a further development of the existing package “CrowdQC.” While QC levels and functionalities of the predecessor are kept, CrowdQC+ extends it to increase QC performance, enhance applicability, and increase user-friendliness. Firstly, two new QC levels are introduced. The first implements a spatial QC that mainly addresses radiation errors, the second a temporal correction of the data regarding sensor-response time. Secondly, new functionalities aim at making the package more flexible to apply to data sets of different lengths and sizes, enabling also near-real time application. Thirdly, additional helper functions increase user-friendliness of the package. As its predecessor, CrowdQC+ does not require reference meteorological data. The performance of the new package is tested with two 1-year data sets of CWS data from hundreds of “Netatmo” CWS in the cities of Amsterdam, Netherlands, and Toulouse, France. Quality-controlled data are compared with data from networks of professionally-operated weather stations (PRWS). Results show that the new package effectively removes faulty data from both data sets, leading to lower deviations between CWS and PRWS compared to its predecessor. It is further shown that CrowdQC+ leads to robust results for CWS networks of different sizes/densities. Further development of the package could include testing the suitability of CrowdQC+ for other variables than ta, such as air pressure or specific humidity, testing it on data sets from other background climates such as tropical or desert cities, and to incorporate added filter functionalities for further improvement. Overall, CrowdQC+ could lead the way to utilise CWS data in world-wide urban climate applications.

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A country scale assessment of the heat hazard-risk in urban areas

Cheval

Dumitrescu

Amihăesei

et al. 2023

Building and Environment

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Quantifying Local and Mesoscale Drivers of the Urban Heat Island of Moscow with Reference and Crowdsourced Observations

Cited by 20 publications

References 115 publications

Evidence of horizontal urban heat advection in London using six years of data from a citizen weather station network

Evidence of horizontal urban heat advection in London using six years of data from a citizen weather station network

CrowdQC+—A Quality-Control for Crowdsourced Air-Temperature Observations Enabling World-Wide Urban Climate Applications

A country scale assessment of the heat hazard-risk in urban areas

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