8 results on '"Osorio, Juan Camilo"'
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2. Is technology (still) applied science?
- Author
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Florez, Daian, García-Duque, Carlos Emilio, and Osorio, Juan Camilo
- Published
- 2019
- Full Text
- View/download PDF
3. Building Climate Justice and Reducing Industrial Waterfront Vulnerability
- Author
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Bautista, Eddie, Osorio, Juan Camilo, and Dwyer, Natasha
- Published
- 2015
4. The compound risk of heat and COVID-19 in New York City: riskscapes, physical and social factors, and interventions.
- Author
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Knox-Hayes, Janelle, Osorio, Juan Camilo, Stamler, Natasha, Dombrov, Maria, Winer, Rose, Smith, Mary Hannah, Blake, Reginald A., and Rosenzweig, Cynthia
- Subjects
- *
SOCIAL factors , *COVID-19 , *COVID-19 pandemic , *COMMUNITIES , *HEALTH equity , *DEMOGRAPHIC characteristics , *NEIGHBORHOODS - Abstract
Climate change is disrupting the fundamental conditions of human life and exacerbating existing inequity by placing further burdens on communities that are already vulnerable. Risk exposure varies by where people live and work. In this article, we examine the spatial overlap of the compound risks of COVID-19 and extreme heat in New York City. We assess the relationship between socio-demographic and natural, built and social environmental characteristics, and the spatial correspondence of COVID-19 daily case rates across three pandemic waves. We use these data to create a compound risk index combining heat, COVID-19, density and social vulnerability. Our findings demonstrate that the compound risk of COVID-19 and heat are public health and equity challenges. Heat and COVID-19 exposure are influenced by natural, built, and social environmental factors, including access to mitigation infrastructure. Socio-demographic characteristics are significant indicators of COVID-19 and heat exposure and of where compound vulnerability exists. Using GIS mapping, we illustrate how COVID-19 risk geographies change across the three waves of the pandemic and the particular impact of vaccinations before the onset of the third wave. We, then, use our compound risk index to assess heat interventions undertaken by the City, identify neighborhoods of both adequate and inadequate coverage and provide recommendations for future interventions. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
- View/download PDF
5. Equity, Environmental Justice, and Urban Climate Change
- Author
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Reckien, Diana, Lwasa, Shuaib, Satterthwaite, David, McEvoy, Darryn, Creutzig, Felix, Montgomery, Mark, Schensul, Daniel, Balk, Deborah, Khan, Iqbal Alam, Fernandez, Blanca, Brown, Donald, Osorio, Juan Camilo, Tovar-Restrepo, Marcela, de Sherbinin, Alex, Feringa, Wim, Sverdlik, Alice, Porio, Emma, Nair, Abhishek, McCormick, Sabrina, Bautista, Eddie, Rozenzweig, C., Solecki, W., Romero-Lankao, P., Mehrotra, S., Dhakal, S., Ibrahim, S.A., Digital Society Institute, Faculty of Geo-Information Science and Earth Observation, UT-I-ITC-PLUS, Department of Urban and Regional Planning and Geo-Information Management, and Department of Geo-information Processing
- Subjects
Environmental justice ,Geography ,Equity (economics) ,Urban climate ,Development economics ,Life Science ,22/4 OA procedure - Published
- 2018
6. Predicting subgrain size and dislocation density in machining-induced surface microstructure of Nickel using supervised model-based learning.
- Author
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Abedrabbo, Faruk, Osorio, Juan Camilo, Abolghasem, Sepideh, Valencia, Carlos, and Rojas, Fabio
- Subjects
NICKEL ,MICROSTRUCTURE ,SUPERVISED learning ,X-ray diffraction ,MICROSCOPY - Abstract
Microstructure evolution under interactive effects of severe shear strains, strain-rates and the accompanied temperature rise often follows complex trajectories. Encapsulating the process–structure linkages under these conditions is vital for prediction and control of product outcomes from processes that involve severe plastic deformation. This paper examines the microstructure transformations during severe shear deformation induced by plane strain machining (PSM) on high-purity (99.99%) Nickel. Deformation conditions in both chips and the surface are created using PSM and characterized via in-situ techniques which are then juxtaposed with orientation imaging microscopy (OIM) via electron back scattered diffraction (EBSD). The dislocation densities are quantified using the broadening of X-ray diffraction peaks of crystallographic planes. We capture the variation of microstructure response (subgrain size and dislocation density), by applying the supervised model-based learning techniques combined with physics-based models to enhance the predictions performance. The features involved in the study are cutting speed, rake angle, temperature, strain, strain-rate, in addition to lnZ and a rate parameter R identified from the saturated Microstructure evolution under interactive effects of severe shear strains, strain-rates and the accompanied temperature rise often follows complex trajectories. Encapsulating the process–structure linkages under these conditions is vital for prediction and control of product outcomes from processes that involve severe plastic deformation. This paper examines the microstructure transformations during severe shear deformation induced by plane strain machining (PSM) on high-purity (99.99%) Nickel. Deformation conditions in both chips and the surface are created using PSM and characterized via in-situ techniques which are then juxtaposed with orientation imaging microscopy (OIM) via electron back scattered diffraction (EBSD). The dislocation densities are quantified using the broadening of X-ray diffraction peaks of crystallographic planes. We capture the variation of microstructure response (subgrain size and dislocation density), by applying the supervised model-based learning techniques combined with physics-based models to enhance the predictions performance. The features involved in the study are cutting speed, rake angle, temperature, strain, strain-rate, in addition to lnZ and a rate parameter R identified from the saturated [ABSTRACT FROM AUTHOR]
- Published
- 2021
7. Fugitive Chemicals and Environmental Justice: A Model for Environmental Monitoring Following Climate-Related Disasters.
- Author
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Madrigano, Jaime, Osorio, Juan Camilo, Bautista, Eddie, Chavez, Ryan, Chaisson, Christine F., Meza, Erika, Shih, Regina A., and Chari, Ramya
- Subjects
ENVIRONMENTAL protection ,POPULATION & economics ,CLIMATE change - Abstract
The combination of population growth in areas of mixed (residential, commercial, and industrial) land use along U.S. waterfronts and the increasing frequency of devastating hurricanes and storm surges has led to community fears of widespread toxic chemical contamination resulting from accidental industrial or small business releases, particularly in the aftermath of an extreme weather event, such as a hurricane. Industrial waterfront communities, which are frequently environmental justice communities, contain numerous toxic chemical sources located in close proximity to residential housing, schools, daycare centers, playgrounds, and healthcare centers. Despite the longstanding concerns of community activists and researchers about the potential for “fugitive” chemicals to be released into floodwaters, there has been little coordinated research or action to develop environmental monitoring programs for disaster-affected communities. In the aftermath of Superstorm Sandy, a community-academic partnership was formed between the New York City Environmental Justice Alliance, UPROSE, The LifeLine Group, and the RAND Corporation. The collaboration, known as Grassroots Research to Action in Sunset Park (GRASP) has focused on identifying possible sources of chemical contamination, modeling the potential for chemical release into community areas and resulting exposure risks, and proactively developing actions for mitigating or preventing adverse community impacts. Through our ongoing work, we have identified barriers and drivers for community-based environmental monitoring, and in doing so, we have developed a framework to overcome challenges. In this article, we describe this framework, which can be used by waterfront communities bracing to deal with the effects of future devastating weather disasters. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
8. New York City Environmental Justice Alliance Waterfront Justice Project.
- Author
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Bautista, Eddie, Hanhardt, Eva, Osorio, Juan Camilo, and Dwyer, Natasha
- Subjects
ENVIRONMENTAL justice associations ,ENVIRONMENTALISM ,WATERFRONTS ,NEIGHBORHOODS ,CLIMATE change ,CITIES & towns & the environment - Abstract
This paper reviews key challenges and opportunities addressed by the New York City Environmental Justice Alliance's (NYC-EJA) Waterfront Justice Project, a citywide campaign to promote climate resilience and sustainability in urban industrial waterfront communities of New York City. NYC-EJA is a non-profit membership-driven network linking grassroots organisations from low-income neighbourhoods and communities of colour in their struggle for environmental justice. The Waterfront Justice Project is documenting community vulnerability in the context of climate change impacts, sources of industrial pollution, and demographic and socio-economic trends. This campaign is enabling community-based organisations, environmental justice communities, city planners, local and state government agencies, local business-owners, and other stakeholders to work in partnership to achieve community resilience while advocating for local jobs and promoting best practices in pollution prevention. New York City's waterfront policies ease the siting and clustering of public infrastructure, water pollution control plants, waste transfer stations, energy facilities, and heavy manufacturing uses in six areas designated as Significant Maritime and Industrial Areas (SMIAs). The SMIAs are located in environmental justice communities, largely low-income communities and communities of colour, in the South Bronx, Brooklyn, Queens, and Staten Island. New York City's local waterfront land use and zoning policies create cumulative risk exposure not only to residents and workers in the host waterfront communities, but also, in the event of storm surge or sea-level rise, to neighbouring, upland communities. [ABSTRACT FROM AUTHOR]
- Published
- 2015
- Full Text
- View/download PDF
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