Our goal in this paper is to examine whether there are similar
patterns in the distribution of tree canopy by Home Owners’ Loan
Corporation (HOLC) graded neighborhoods across 37 cities. A pre-print
of the paper can be found here:
https://osf.io/preprints/socarxiv/97zcs
This data packages contains:
1. City-specific file geodatabases with features classes of the HOLC
polygons obtained from the Mapping Inequality Project
https://dsl.richmond.edu/panorama/redlining/,
and tables summarizing tree canopy, and in some cases other land cover
classes.
2. An *.R script that replicates all of the analyses, graphs, and
tables in the paper. Other double checks, exploratory, and
miscellaneous outputs are created by the script too as a bonus.
Everything in the paper can be done with the script; additional work
outputs are also created.
3. A *.csv file containing city, the HOLC grade, and the percent tree
canopy cover. This can be used to create the main findings of the
paper and this flat file is provided as an alternative to running the
R script to extract information from the geodatabases, combine, and
analyze them. The intention is that this file is more widely
accessible; the underlying information is the same.
Redlining was a racially discriminatory housing policy established by
the federal government’s Home Owners’ Loan Corporation (HOLC) during
the 1930s. For decades, redlining limited access to homeownership and
wealth creation among racial minorities, contributing to a host of
adverse social outcomes, including high unemployment, poverty, and
residential vacancy, that persist today. While the multigenerational
socioeconomic impacts of redlining are increasingly understood, the
impacts on urban environments and ecosystems remains unclear. To begin
to address this gap, we investigated how the HOLC policy administered
80 years ago may relate to present-day tree canopy at the neighborhood
level. Urban trees provide many ecosystem services, mitigate the urban
heat island effect, and may improve quality of life in cities. In our
prior research in Baltimore, MD, we discovered that redlining policy
influenced the location and allocation of trees and parks. Our
analysis of 37 metropolitan areas here shows that areas formerly
graded D, which were mostly inhabited by racial and ethnic minorities,
have on average ~23% tree canopy cover today. Areas formerly graded A,
characterized by U.S.-born white populations living in newer housing
stock, had nearly twice as much tree canopy (~43%). Results are
consistent across small and large metropolitan regions. The ranking
system used by Home Owners’ Loan Corporation to assess loan risk in
the 1930s parallels the rank order of average percent tree canopy
cover today.
more »
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Black Gold, White Power: Mapping Oil, Real Estate, and Racial Segregation in the Los Angeles Basin, 1900-1939
In 1923, Southern California produced over twenty percent of the world’s oil. At the epicenter of an oil boom from 1892 to the 1930s, Los Angeles grew into the nation’s fifth largest city. By the end of the rush, it had also become one of the most racially segregated cities in the country. Historians have overlooked the relationship between industrialists drilling for oil and real estate developers codifying a racist housing market, namely through “redlining” maps and mortgage lending. While redlining is typically understood as a problem of horizontal territory, this paper argues that the mapping of the underground—the location and volume of subterranean oil fields, in particular—was a crucial technique in underwriting urban apartheid. Mapping technologies linked oil exploitation with restrictive property rights, constructing oil as a resource and vertically engineering a racialized housing market. By focusing on petro-industrialization interlocked with segregationist housing, this article reveals an unexamined chapter in Los Angeles’s history of resource exploitation and racial capitalism. Moreover, it contributes to a growing literature on the social production of resources, extractive technology and political exclusion, and the technoscientific practices used by states and corporations to mine the underground while constructing metropolitan inequality above ground.
more »
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- Award ID(s):
- 1827951
- NSF-PAR ID:
- 10110580
- Date Published:
- Journal Name:
- Engaging Science, Technology, and Society
- Volume:
- 4
- ISSN:
- 2413-8053
- Page Range / eLocation ID:
- 85; 110
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Abstract Redlining was a racially discriminatory housing policy established by the federal government’s Home Owners’ Loan Corporation (HOLC) during the 1930s. For decades, redlining limited access to homeownership and wealth creation among racial minorities, contributing to a host of adverse social outcomes, including high unemployment, poverty, and residential vacancy, that persist today. While the multigenerational socioeconomic impacts of redlining are increasingly understood, the impacts on urban environments and ecosystems remain unclear. To begin to address this gap, we investigated how the HOLC policy administered 80 years ago may relate to present-day tree canopy at the neighborhood level. Urban trees provide many ecosystem services, mitigate the urban heat island effect, and may improve quality of life in cities. In our prior research in Baltimore, MD, we discovered that redlining policy influenced the location and allocation of trees and parks. Our analysis of 37 metropolitan areas here shows that areas formerly graded D, which were mostly inhabited by racial and ethnic minorities, have on average ~23% tree canopy cover today. Areas formerly graded A, characterized by U.S.-born white populations living in newer housing stock, had nearly twice as much tree canopy (~43%). Results are consistent across small and large metropolitan regions. The ranking system used by Home Owners’ Loan Corporation to assess loan risk in the 1930s parallels the rank order of average percent tree canopy cover today.
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Micromodels with simplified porous microfluidic systems are widely used to mimic the underground oil‐reservoir environment for multiphase flow studies, enhanced oil recovery, and reservoir network mapping. However, previous micromodels cannot replicate the length scales and geochemistry of carbonate because of their material limitations. Here a simple method is introduced to create calcium carbonate (CaCO3) micromodels composed of in situ grown CaCO3. CaCO3nanoparticles/polymer composite microstructures are built in microfluidic channels by photopatterning, and CaCO3nanoparticles are selectively grown in situ from these microstructures by supplying Ca2+, CO32−ions rich, supersaturated solutions. This approach enables us to fabricate synthetic CaCO3reservoir micromodels having dynamically tunable geometries with submicrometer pore‐length scales and controlled wettability. Using this new method, acid fracturing and an immiscible fluid displacement process are demonstrated used in real oil field applications to visualize pore‐scale fluid–carbonate interactions in real time.
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- Free Publicly Accessible Full Text
-
Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.17351/ests2018.212
