Elliott Warren scite author profile

With 69% of the world's population predicted to live in cities by 2050, modification to local climates, in particular Urban Heat Islands (UHIs), have become a well studied phenomenon. However, few studies have considered how horizontal winds modify the spatial pattern in a process named Urban Heat Advection (UHA) and this is most likely due to a lack of highly spatially resolved observational data. For the first time, this study separates the two-dimensional advection-induced UHI component, including its pattern and magnitude, from the locally heated UHI component using a unique dataset of urban canopy temperatures from 29 weather stations (3 km resolution) recorded over 20 months in Birmingham, United Kingdom. The results show that the mean contribution of UHA to the warming of areas downwind of the city can be up to 1.2 • C. Using the inverse Normalized Difference Vegetation Index as a proxy for urban fraction, an upwind distance at which the urban fraction has the strongest correlation with UHA was demonstrated to be between 4 and 12 km. Overall, these findings suggest that urban planning and risk management needs to additionally consider UHA. However, more fundamentally, it highlights the importance of careful interpretation of long-term meteorological records taken near cities when they are used to assess global warming.

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The Birmingham Urban Climate Laboratory: An Open Meteorological Test Bed and Challenges of the Smart City

Chapman

Muller

Young

et al. 2015

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The Birmingham Urban Climate Laboratory (BUCL) is a near-real-time, high-resolution urban meteorological network (UMN) of automatic weather stations and inexpensive, nonstandard air temperature sensors. The network has recently been implemented with an initial focus on monitoring urban heat, infrastructure, and health applications. A number of UMNs exist worldwide; however, BUCL is novel in its density, the low-cost nature of the sensors, and the use of proprietary Wi-Fi networks. This paper provides an overview of the logistical aspects of implementing a UMN test bed at such a density, including selecting appropriate urban sites; testing and calibrating low-cost, nonstandard equipment; implementing strict quality-assurance/quality-control mechanisms (including metadata); and utilizing preexisting Wi-Fi networks to transmit data. Also included are visualizations of data collected by the network, including data from the July 2013 U.K. heatwave as well as highlighting potential applications. The paper is an open invitation to use the facility as a test bed for evaluating models and/or other nonstandard observation techniques such as those generated via crowdsourcing techniques.

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Evaluation of forward-modelled attenuated backscatter using an urban ceilometer network in London under clear-sky conditions

Warren

Charlton‐Perez

Kotthaus

et al. 2018

Atmospheric Environment

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The Birmingham Urban Climate Laboratory—A high density, urban meteorological dataset, from 2012–2014

et al. 2016

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There is a paucity of urban meteorological observations worldwide, hindering progress in understanding and mitigating urban meteorological hazards and extremes. High quality urban datasets are required to monitor the impacts of climatological events, whilst providing data for evaluation of numerical models. The Birmingham Urban Climate Laboratory was established as an exemplar network to meet this demand for urban canopy layer observations. It comprises of an array of 84 wireless air temperature sensors nested within a coarser array of 24 automatic weather stations, with observations available between June 2012 and December 2014. data routinely underwent quality control, follows the ISO 8601 naming format and benefits from extensive site metadata. The data have been used to investigate the structure of the urban heat island in Birmingham and its associated societal and infrastructural impacts. The network is now being repurposed into a testbed for the assessment of crowd-sourced and satellite data, but the original dataset is now available for further analysis, and an open invitation is extended for its academic use.

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Observed aerosol characteristics to improve forward-modelled attenuated backscatter in urban areas

Warren

Charlton‐Perez

Kotthaus

et al. 2020

Atmospheric Environment

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Elliott Warren

Observations of urban heat island advection from a high‐density monitoring network

The Birmingham Urban Climate Laboratory: An Open Meteorological Test Bed and Challenges of the Smart City

Evaluation of forward-modelled attenuated backscatter using an urban ceilometer network in London under clear-sky conditions

The Birmingham Urban Climate Laboratory—A high density, urban meteorological dataset, from 2012–2014

Observed aerosol characteristics to improve forward-modelled attenuated backscatter in urban areas

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