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1. Heat exposure and resilience planning in Atlanta, Georgia

   https://doi.org/10.1088/2752-5295/ac78f9  

   Muse, Nkosi; Iwaniec, David M; Wyczalkowski, Chris; Mach, Katharine J (July 2022, Environmental Research: Climate)

   Abstract The City of Atlanta, Georgia, is a fast-growing urban area with substantial economic and racial inequalities, subject to the impacts of climate change and intensifying heat extremes. Here, we analyze the magnitude, distribution, and predictors of heat exposure across the City of Atlanta, within the boundaries of Fulton County. Additionally, we evaluate the extent to which identified heat exposure is addressed in Atlanta climate resilience governance. First, land surface temperature (LST) was mapped to identify the spatial patterns of heat exposure, and potential socioeconomic and biophysical predictors of heat exposure were assessed. Second, government and city planning documents and policies were analyzed to assess whether the identified heat exposure and risks are addressed in Atlanta climate resilience planning. The average LST of Atlanta’s 305 block groups ranges from 23.7 °C (low heat exposure) in vegetated areas to 31.5 °C (high heat exposure) in developed areas across 13 summer days used to evaluate the spatial patterns of heat exposure (June–August, 2013–2019). In contrast to nationwide patterns, census block groups with larger historically marginalized populations (predominantly Black, less education, lower income) outside of Atlanta’s urban core display weaker relationships with LST (slopes ≈ 0) and are among the cooler regions of the city. Climate governance analysis revealed that although there are few strategies for heat resilience in Atlanta ( n = 12), the majority are focused on the city’s warmest region, the urban core, characterized by the city’s largest extent of impervious surface. These strategies prioritize protecting and expanding the city’s urban tree canopy, which has kept most of Atlanta’s marginalized communities under lower levels of outdoor heat exposure. Such a tree canopy can serve as an example of heat resilience for many cities across the United States and the globe. 

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2. Multiscale dynamic human mobility flow dataset in the U.S. during the COVID-19 epidemic

   https://doi.org/10.1038/s41597-020-00734-5  

   Kang, Yuhao; Gao, Song; Liang, Yunlei; Li, Mingxiao; Rao, Jinmeng; Kruse, Jake (December 2020, Scientific Data)

   null (Ed.)

   Abstract Understanding dynamic human mobility changes and spatial interaction patterns at different geographic scales is crucial for assessing the impacts of non-pharmaceutical interventions (such as stay-at-home orders) during the COVID-19 pandemic. In this data descriptor, we introduce a regularly-updated multiscale dynamic human mobility flow dataset across the United States, with data starting from March 1st, 2020. By analysing millions of anonymous mobile phone users’ visits to various places provided by SafeGraph, the daily and weekly dynamic origin-to-destination (O-D) population flows are computed, aggregated, and inferred at three geographic scales: census tract, county, and state. There is high correlation between our mobility flow dataset and openly available data sources, which shows the reliability of the produced data. Such a high spatiotemporal resolution human mobility flow dataset at different geographic scales over time may help monitor epidemic spreading dynamics, inform public health policy, and deepen our understanding of human behaviour changes under the unprecedented public health crisis. This up-to-date O-D flow open data can support many other social sensing and transportation applications. 

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3. Estimating the structure by age and sex of the US sexually active population

   https://doi.org/10.1080/08898480.2024.2301868  

   Bustamante Orellana, Carlos; Lyerla, Jordan; Martin, Aaron; Milner, Fabio; Smith, Elisha (January 2024, Mathematical Population Studies)

   A model combines demographic data provided by the United States Census Bureau for 2021 with survey data on sexual activity from the Centers for Disease Control and Prevention to estimate the structure by age and sex of the sexually active population in the United States. It also provides the proportions of newly sexually active people by age and sex. The model is based on percentages of sexually active people by age and sex, and on an ordinary differential equation formalizing a “learning process” for the years 2009 to 2019. The data produced fit well with the empirical data for each age and sex. 

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4. Mapping Social Vulnerability to Air Pollution in Philadelphia, PA

   Conway, Meghan (September 2020, Veritas)

   null (Ed.)

   Environmental stresses borne of population growth, consumerism and industrialization have subjected many populations worldwide to elevated air pollution. Philadelphia, a historically industrial city in Northeastern United States, is ranked in the top 25 cities in the country for harmful air pollutants (PM2.5, ozone). Philadelphia also experiences 􀁋􀁖􀁉􀁅􀁘􀀄 􀆼􀁒􀁅􀁒􀁇􀁍􀁅􀁐􀀄 􀁗􀁘􀁖􀁅􀁘􀁍􀆼􀁇􀁅􀁘􀁍􀁓􀁒􀀄 􀁅􀁒􀁈􀀄 􀁉􀁒􀁚􀁍􀁖􀁓􀁒􀁑􀁉􀁒􀁘􀁅􀁐􀀄 􀁖􀁅􀁇􀁍􀁗􀁑􀀐􀀄 􀁛􀁌􀁍􀁇􀁌􀀄 􀁓􀁊􀁘􀁉􀁒􀀄 􀁙􀁒􀁊􀁅􀁍􀁖􀁐􀁝􀀄 􀁅􀁗􀁗􀁉􀁖􀁘􀁗􀀄 􀁘􀁌􀁉􀀄 􀁔􀁅􀁍􀁒􀁗􀀄 􀁓􀁊􀀄 􀁉􀁒􀁚􀁍􀁖􀁓􀁒􀁑􀁉􀁒􀁘􀁅􀁐􀀄 pollution & associated health effects on socioeconomically disadvantaged communities. This study seeks to succinctly 􀁕􀁙􀁅􀁒􀁘􀁍􀁊􀁝􀀄􀁛􀁌􀁍􀁇􀁌􀀄􀁔􀁓􀁔􀁙􀁐􀁅􀁘􀁍􀁓􀁒􀁗􀀄􀁑􀁅􀁝􀀄􀁆􀁉􀀄􀁅􀁘􀀄􀁖􀁍􀁗􀁏􀀄􀁊􀁓􀁖􀀄􀁌􀁉􀁅􀁐􀁘􀁌􀀄􀁉􀁊􀁊􀁉􀁇􀁘􀁗􀀄􀁅􀁗􀁗􀁓􀁇􀁍􀁅􀁘􀁉􀁈􀀄􀁛􀁍􀁘􀁌􀀄􀁅􀁍􀁖􀀄􀁔􀁓􀁐􀁐􀁙􀁘􀁍􀁓􀁒􀀄􀀌􀁗􀁔􀁉􀁇􀁍􀆼􀁇􀁅􀁐􀁐􀁝􀀄􀁅􀁗􀁘􀁌􀁑􀁅􀀐􀀄􀁇􀁌􀁖􀁓􀁒􀁍􀁇􀀄 obstructive pulmonary disease) through a suite of census-derived attributes. Using ArcMap Geographical Information System software (ESRI), attributes, categorized as promoting vulnerability or adaptability, are combined with air pollution data collected in summer 2019 to form a non-weighted ‘Social Vulnerability Index’ (SVI) at a census-tract level for Philadelphia. SVI demonstrated several clusters of neighborhoods with great disparities in socioeconomic factors. The census tracts with higher SVI tended to have higher levels of asthma and COPD (and vice versa). With improvements and acknowledgement of Philadelphia’s uniqueness, SVI of this kind may be used to inform policymakers on city planning (e.g. placement of future highways, industrial centers, etc.) to alleviate compounded respiratory/ pulmonary-related stresses on disadvantaged communities. Future analysis including green space coverage, other 􀁊􀁓􀁖􀁑􀁗􀀄􀁓􀁊􀀄􀁅􀁍􀁖􀀄􀁔􀁓􀁐􀁐􀁙􀁘􀁍􀁓􀁒􀀐􀀄􀁅􀁒􀁈􀀓􀁓􀁖􀀄􀁅􀀄􀁕􀁙􀁅􀁒􀁘􀁍􀆼􀁇􀁅􀁘􀁍􀁓􀁒􀀄􀁓􀁊􀀄􀁗􀁓􀁇􀁍􀁅􀁐􀀄􀁇􀁓􀁒􀁒􀁉􀁇􀁘􀁍􀁚􀁍􀁘􀁝􀀄􀁑􀁅􀁝􀀄􀁌􀁉􀁐􀁔􀀄􀁘􀁓􀀄􀁍􀁑􀁔􀁖􀁓􀁚􀁉􀀄􀁊􀁙􀁖􀁘􀁌􀁉􀁖􀀄􀁙􀁒􀁈􀁉􀁖􀁗􀁘􀁅􀁒􀁈􀁍􀁒􀁋􀀄􀁓􀁊􀀄􀁘􀁌􀁉􀀄 intersection between socioeconomic factors, air pollution, and health in Philadelphia, PA. 

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5. Integrated urban land cover analysis using deep learning and post‐classification correction

   https://doi.org/10.1111/mice.13277  

   Techapinyawat, Lapone; Timms, Aaliyah; Lee, Jim; Huang, Yuxia; Zhang, Hua (May 2024, Computer-Aided Civil and Infrastructure Engineering)

   Abstract The quantification of urban impervious area has important implications for the design and management of urban water and environmental infrastructure systems. This study proposes a deep learning model to classify 15‐cm aerial imagery of urban landscapes, coupled with a vector‐oriented post‐classification processing algorithm for automatically retrieving canopy‐covered impervious surfaces. In a case study in Corpus Christi, TX, deep learning classification covered an area of approximately 312 km²(or 14.86 billion 0.15‐m pixels), and the post‐classification effort led to the retrieval of over 4 km²(or 0.18 billion pixels) of additional impervious area. The results also suggest the underestimation of urban impervious area by existing methods that cannot consider the canopy‐covered impervious surfaces. By improving the identification and quantification of various impervious surfaces at the city scale, this study could directly benefit a variety of environmental and infrastructure management practices and enhance the reliability and accuracy of processed‐based models for urban hydrology and water infrastructure. 

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