“Freedom to Breathe”: Youth Participatory Action Research (YPAR) to Investigate Air Pollution Inequities in Richmond, CA


International  Journal  of

Environmental Research

and Public Health

Article

“Freedom to Breathe”: Youth Participatory Action Research
(YPAR) to Investigate Air Pollution Inequities in Richmond, CA

James E. S. Nolan 1,* , Eric S. Coker 2, Bailey R. Ward 3, Yahna A. Williamson 3 and Kim G. Harley 1

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Citation: Nolan, J.E.S.; Coker, E.S.;

Ward, B.R.; Williamson, Y.A.; Harley,

K.G. “Freedom to Breathe”: Youth

Participatory Action Research (YPAR)

to Investigate Air Pollution Inequities

in Richmond, CA. Int. J. Environ. Res.

Public Health 2021, 18, 554. https://

doi.org/10.3390/ijerph18020554

Received: 28 October 2020

Accepted: 21 December 2020

Published: 11 January 2021

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4.0/).

1 Center for Environmental Research and Children’s Health (CERCH), School of Public Health, University of
California at Berkeley, Berkeley, CA 94704, USA; kharley@berkeley.edu

2 Department of Environmental and Global Health, College of Public Health and Health Professions,
University of Florida, Gainesville, FL 32603, USA; eric.coker@phhp.ufl.edu

3 RYSE Youth Justice Center, Richmond, CA 94805, USA; baileyrward@gmail.com (B.R.W.);
yahna234y.w@gmail.com (Y.A.W.)

* Correspondence: jnolan@berkeley.edu

Abstract: Air pollution is a major contributor to human morbidity and mortality, potentially exac-
erbated by COVID-19, and a threat to planetary health. Participatory research, with a structural
violence framework, illuminates exposure inequities and refines mitigation strategies. Home to
profitable oil and shipping industries, several census tracts in Richmond, CA are among the most
heavily impacted by aggregate burdens statewide. Formally trained researchers from the Center
for Environmental Research and Children’s Health (CERCH) partnered with the RYSE youth jus-
tice center to conduct youth participatory action research on air quality justice. Staff engaged five
youth researchers in: (1) collaborative research using a network of passive air monitors to quantify
neighborhood disparities in nitrogen dioxide (NO2) and sulfur dioxide (SO2), noise pollution and
community risk factors; (2) training in environmental health literacy and professional development;
and (3) interpretation of findings, community outreach and advocacy. Inequities in ambient NO2,
but not SO2, were observed. Census tracts with higher Black populations had the highest NO2.
Proximity to railroads and major roadways were associated with higher NO2. Greenspace was
associated with lower NO2, suggesting investment may be conducive to improved air quality, among
many additional benefits. Youth improved in measures of empowerment, and advanced community
education via workshops, Photovoice, video, and ”zines”.

Keywords: youth empowerment; air pollution; inequity; structural violence

1. Introduction

The field of public health has facilitated major gains in improving societal level health,
especially over the last 100 years. Many of these improvements have been broad strokes
interventions, such as removing lead from gasoline and paint, improvements in occu-
pational health and safety, improving water quality and ensuring food safety, affecting
the majority of people in the US [1,2]. Yet, health disparities persist [3,4], and the field is
increasingly faced with complex challenges of historically rooted structural determinants
of health. These challenges include a lack of socio-historical context, misalignment between
community and researcher goals [5], insufficient data granularity and interventions that
address specific downstream symptoms rather than root causes of problems [4]. Scientific-
grade youth participatory action research (YPAR) studies can help address this gap by
leveraging youth’s experiential expertise to fine tune scientific data collection protocols
for context-specific scenarios, building relationships between researchers and community,
collecting nuanced neighborhood level data responsive to local needs [6], framing findings
in local vernacular and contexts, and disseminating results more effectively. In recruiting
youth from impacted communities and providing them with mentorship, afterschool edu-
cational opportunities, skills development, paid work, college preparation and amplifying

Int. J. Environ. Res. Public Health 2021, 18, 554. https://doi.org/10.3390/ijerph18020554 https://www.mdpi.com/journal/ijerph

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Int. J. Environ. Res. Public Health 2021, 18, 554 2 of 18

their voices, YPAR can help dismantle long-standing power dynamics [7]. The model
prioritizes centering impacted communities, building local capacity and expanding future
opportunities for improved wellbeing [8–10].

From 2017 to 2018, the Richmond Youth Air Quality Initiative utilized YPAR to inves-
tigate air quality and related environmental justice challenges across neighborhoods facing
heightened adversity in Richmond, CA, an industrial community in the San Francisco Bay
Area with high disadvantage and pollution that is situated on Ohlone land [11]. Researchers
from UC Berkeley’s Center for Environmental Research and Children’s Health (CERCH)
partnered with RYSE, a community youth center in Richmond promoting social justice and
development opportunities. The project facilitated empowerment among high school youth
through: (1) training in environmental health literacy (EHL), professional development,
paid employment and college preparation; (2) full partnership in designing and conducting
research on the convergence of structural air pollution and community-level health risk
factors using both quantitative and qualitative methods; and (3) interpretation of findings,
community outreach and advocacy. Youth were facilitated in exploring manifestations of
structural violence, explicitly examining features in the built environment that may affect
pollution levels in correlation with pre-existing socio-economic burdens, monitoring for
disparities in NO2, SO2 and noise pollution and returning results to the community.

2. Background
2.1. Air Pollution

Inequitable distribution of air pollution is a major driver of health disparities. Globally,
it is estimated that air pollution contributes to seven million preventable deaths each year,
largely from respiratory infection, chronic obstructive pulmonary diseases, heart disease,
and cancer [12]. Exposure during pregnancy is associated with low birthweight, premature
birth and infant mortality [13]. The vast majority of those most impacted are low-income
people of color [12]. Air pollution also presents a significant threat to planetary health, with
emissions exceeding earth’s absorption rate, risking global warming, mass extinctions and
ecological collapse. The health effects of air pollutants among sub-groups with heightened
biological susceptibility and vulnerability remains understudied. Susceptible sub-groups
include the very young, the very old, those with respiratory diseases and those who face
high levels of socio-economic disadvantage and other chronic social stressors. Emerging
findings indicate that air pollution may exacerbate both the incidence and harm of COVID-
19 [14,15], a disease that disproportionately affects communities of color [16,17].

Air pollution is classified as outdoor (ambient) or indoor and includes a range of
sources and exposure determinants. Concerning monitoring and human health effects, the
most widely studied air pollutants include particulate matter (PM), ozone (O3), nitrogen
dioxide (NO2), and sulfur dioxide (SO2) [18]. NO2 can contribute to PM2.5 and ozone
air pollution respectively, and is associated with increased risk of pulmonary distress
and asthma symptom exacerbation [18]. SO2 is the leading cause of acid rain, which is
devastating to ecological balance and is associated with respiratory distress, exacerba-
tion of respiratory disease symptoms, increases in overall mortality and cardiac disease
hospitalizations in humans [18]. Emissions generating activities are largely driven by
commodity production, transportation and participation in growth-focused global markets,
and include stationary sources such as heavy production industries and mobile sources
such as trucks and trains. Though mobile sources are transient by nature, they generally
follow well-established routes, resulting in clusters of heightened emissions.

Our research focused on anthropogenic air pollutants, which are readily measurable
and more amenable to mitigation than natural sources such as forest fires, which themselves
may also be increasing in intensity and frequency due to increasing air pollution and
subsequent global warming [19]. Specifically, we measured urban ambient NO2 and SO2
concentrations and studied spatial variability of pollutant concentration within Richmond,
CA. Selection of NO2 and SO2 as study pollutants were determined by the following factors:
(1) a priori relationships with localized traffic and industry-related emissions sources; (2)



Int. J. Environ. Res. Public Health 2021, 18, 554 3 of 18

potential for human health impacts; (3) potential for spatial heterogeneity in concentrations;
(4) potential as a target for future pollutant mitigation efforts; and (5) ability to be reliably
and practicably measured and interpreted using low-cost sampling devices. Spot noise
pollution data was also collected, as some emerging evidence has suggested a negative
relationship with several health outcomes [20,21].

2.2. Structural Violence
2.2.1. Framework

Contextualizing neighborhood level spatial distributions of air pollution data using a
structural violence framework helps illuminate the intrinsically meaningful context within
which pollutant emissions and exposures occur. Structural violence is defined as “the
prevention of individuals or populations from reaching their mental and physical potential
without a specific actor committing the violence; when ’violence is built into the structure
and shows up as unequal power and consequently as unequal life chances.’ It may be
unintended and indirect [22]”. Structural violence analysis unveils clustering of environ-
mental harms, such as the inequitable proportion of hazardous sites in disadvantaged
communities [3]. Implications support centering populations most affected, and social
justice driven pathways for remediation. Here, justice may imply not just the cessation of
harm, but also recompense for harms already done.

2.2.2. Transgenerational Structural Violence

Histories of structural violence precede, and persist in, contemporary injustices, thus
transgenerational violence must be integrated into analysis and intervention. Histori-
cal violence against marginalized communities sculpt “colonial geographies of harm” [23].
Value-laden borders based on social identity manifest in physical space and morph in
response to forces and resistance, fueled by such concepts as “The West”, colonialism and
modernity [23]. These concepts become embedded in contemporary structures, ideological
made physical, and normalized over long periods [24], making them difficult to identify
and even more so to act against. Examples include Western colonist’s attempted genocide
against Native Americans and forced relocation to reservations on “marginal” land [24],
Trans-Atlantic slavery, and racial segregation in the early 20th century. In each instance,
extreme force was used to establish boundaries, cordoning low income and people of
color, and policing behaviors. In the face of resistance, explicit force transitioned to more
insidious mechanisms such as withheld GI-Bill housing and education support for Black
veterans of WWII [25], economic divestment and race-based exclusion via redlining [26],
racially biased federal loan practices favoring white farmers [27], and the mass incarcera-
tion of people of color [28]. Here, the opportunities that groups of people are held back
from, and the spaces they are held in, engrained in replicating and obfuscated structures,
become violence.

2.2.3. Contemporary Structural Violence

Insidious constellations of inequity make it appear as though individuals, not systems
of socio-historical violence, are at fault [29]. Culturally structured white supremacy, coded
with alleged racial identifiers and thus transgenerational, shifted to wealth passed on
in such forms as company ownership, stocks and estate inheritance [30,31], as well as
status, privilege and opportunity access, themselves passed on transgenerationally [32,33].
Neoliberalism accelerated wealth accumulation and eroded social services [34], while fossil
fuels accelerated neoliberalism, and air pollution, on a global scale. In 2019, half of the
world’s top 10 corporations are fossil fuel companies [35], and just three white men control
more wealth than the bottom 50% of US residents combined [36]. Of the 100 wealthiest
people in the US in 2018, 90% were male, the vast majority were white and only 1 was
Black [37]. In 2019, the average white family had roughly 8 times the wealth of the median
Black family, and 5 times that of a Latinx family with little improvement over the last
several years [38]. Those who experience poverty for 50% or more of their childhood have



Int. J. Environ. Res. Public Health 2021, 18, 554 4 of 18

a 35–46% chance of being in poverty themselves as they become middle aged [39]. Income
inequality itself can be a significant cause of health disparities [40].

Inequity tracks with exposure burdens and resultant health impacts along strata of
race, place and class [41–44]. For example, Blacks in the US face roughly 50% more air
pollution relative to their consumption, while whites face 17% less than theirs [45]. Lauren
Berlant’s concept of “slow death”—“the physical wearing out or deterioration of people
that is very nearly a defining condition of their experience and historical existence [46]”—
speaks to an amalgam of socio-economic factors that compound such that a Black child
born in a disadvantaged Oakland neighborhood is expected to have a 15 year shorter life
compared to a white child born in the hills of that same city [47]. Oakland borders Berkeley,
where this paper was originally written, with Berkeley just a few miles from Richmond,
about which this paper is written.

2.2.4. Contemporary Resistance to Symptoms of Structural Violence

Millions in the US have been catalyzed by mass social movements in addressing
symptoms of structural violence. Over the last decade, Occupy/Decolonize Wallstreet,
#MeToo and Black Lives Matter have focused on mitigating harm in relation to economic
disadvantage, gender discrimination and racism respectively. In 2020, George Floyd—
raised in a low-income, single-mother household, and a Black man—was killed by police
in an egregious act of violence [48]. Though complex, research indicates a strong con-
nection between being low income (male) and Black, and higher probability of police
arrest, imprisonment [49], and police violence, with police force being a leading cause
of death for young Black men [50]. Re-energized by the pursuit of justice for Floyd, as
well as for many before and after him, the Black Lives Matter movement has become the
largest US social movement to date [51]. The movement is rooted in resistance throughout
deep histories of slavery and continuing racial injustice. Many such injustices have been
overt and acute for 400 years. With advances in video recording and communications
technology, contemporary manifestations of these historically rooted injustices can now be
transmitted, and better articulated, almost instantaneously across vast networks, perhaps
therefore increasing societal level engagement. The “slow death” of oftentimes invisible,
gradual, and mechanistically complex air pollution exposures, frequently the result of
unintended and indirect forces, oftentimes manifest in a holding back and a holding within
marginalized “geographies of harm”, stand in contrast. Aptly stated by Foucault, in a distinct
but complementary context “... invisibility is a guarantee of order [52].” Noteworthy also,
is that George Floyd, deprived of his “freedom to breathe [53]” by state violence, was also
diagnosed with COVID-19 [48], itself an airborne respiratory disease disproportionately
burdening low income and communities of color in the US, and potentially exacerbated
by air pollution. Implications, including potential synergies between increasing public
awareness around Black Lives Matter, disparities in the effects of COVID-19, and improved
environmental justice are overviewed in the Discussion section.

2.2.5. Structural Violence in Richmond, CA

Our study was conducted in Richmond, land historically occupied by Ohlone Native
Americans and currently occupied by diverse communities of color, including members of
the Ohlone. In early to mid-1900s the city had a booming economy and included a high
proportion of white residents. As those industries, many based on a war effort, became less
profitable, many white residents moved out [54]. Today, 20.6% of residents identify as Black,
and 42% Latinx [55]. As many as 20% of Richmond’s residents are undocumented [56].
The City of Richmond has made significant gains in improving housing stock, reducing
crime [57] and establishing a Health in All Policies campaign for addressing its multifaceted
community health challenges [58] and several personnel have taken notable steps to
support this study, as well as others like it. An array of organizations are confronting
environmental injustice, marginalization of youth, and community violence.



Int. J. Environ. Res. Public Health 2021, 18, 554 5 of 18

Despite progress, Richmond remains an at-risk community due to structural inequities,
including high emissions sources and population-level vulnerabilities [59,60]. Roughly
17,000 people reside in the neighborhoods of Atchison Village and North Richmond, census
tracts ranking in the top 90–95th percentile statewide for combined socio-economic and
pollution burden [60]. The population in these tracts is >92% non-white, with asthma
burdens in the 99–100th percentiles, and diesel burdens in the 84–95th [60]. Richmond
houses the largest oil refinery west of the Mississippi, the cause of several air pollution
emergencies in recent years including one that hospitalized 15,000 residents [61], resulting
in great concern among many in the community. Previous community-based participatory
research revealed that air toxics concentrations, as well as the variety of air toxics, were
substantially higher in Richmond than a neighboring, predominantly white and more
formally educated community [62]. Richmond faces a violent crime rate almost twice as
high as the surrounding county and state as a whole [63]. While 15% of those over 25 years
of age in the US do not have a high school diploma, this proportion is 32% or higher in
impacted Richmond census tracts, as high as 58% [64]. Physical activity and access to
healthy foods are major challenges as well, with nearly half of the population obese or
overweight and nearly a third living in food deserts [65].

2.3. Air Quality Research Gaps in Richmond

Despite regulatory air monitoring networks throughout U.S. cities, major urban air
quality data gaps exist. Because the primary goal of regulatory monitoring is to assess
whether a region’s overall pollution levels fall within air quality standards, these networks
are ill-suited to examine spatial heterogeneity of air pollution levels within cities. Though
several of Richmond’s neighborhoods are impacted by emissions from heavy industry
and multiple highways, the city has just one regulatory air monitoring site that measures
criteria air pollutants regulated by the US EPA (e.g., NO2, SO2, PM2.5, ozone, and carbon
monoxide). Consequently, little is known about differences in air pollution levels between
Richmond neighborhoods. Such limitations leave densely populated areas with potentially
insufficient air quality data, which could otherwise guide policymakers in prioritizing local
air pollution mitigation efforts. The spatially dense network of air samplers implemented
in our study enabled youth researchers to better characterize spatial variability of air pollu-
tant concentrations between Richmond neighborhoods and associate this variability with
features of the built environment, many of which exemplify continuing structural violence.

2.4. Youth Participatory Action Research (YPAR) Model

As nuanced socio-economic factors may affect the likelihood that persons of certain
groups, especially communities of color, are disproportionately exposed to environmental
health challenges such as pesticides [66], poor air quality [67], or impaired drinking wa-
ter [68], and the severity of negative health outcomes, it is important to include members
of impacted communities in the research process. Through lifetimes of experience in af-
fected communities, locals gain invaluable insight into mechanisms behind key challenges,
intersectional harms and assets to address them. This process of engagement frequently
reveals unforeseen synergies between organizations, community members and researchers.
The “gold standard” model for community researcher partnerships is Community Based
Participatory Research (CBPR). CBPR emphasizes strengths-based engagement, equitable
community inclusion in all facets of research, co-learning between academics and com-
munity members, equitable distribution of resources, local capacity building, research
and action, addressing local priorities, and sustained engagement [69]. CBPR improves
“relevance, rigor and reach” [70]. Community input guides study foci and ensures relevance
to community needs. Rigor is improved as residents have experiential expertise and can
highlight contexts affecting local exposure or vulnerability. Locals may be perceived as
more trustworthy than outsider researchers and granted greater access to sensitive infor-
mation or culturally significant locations. CBPR enhances the reach of findings, as locals



Int. J. Environ. Res. Public Health 2021, 18, 554 6 of 18

know how to frame results using appropriate language that appeals to those most affected,
and ideal venues for dissemination [70].

This study used YPAR, a corollary of CBPR with emphasis on youth empowerment
and trajectories of development. There is a great body of research indicating that YPAR
studies can enhance research, and outcomes for youth themselves [71–76]. Some stipulate
that pre-adult years constitute a “sensitive period” where experiences can make dispropor-
tionately positive effects on overall trajectories of identity and civic engagement [69]. Yet,
as they are still learning, youth may be somewhat less able to inform initial study design,
and somewhat less able to engage in advanced facets of data analysis. In balance, youth
bring a fresh perspective and are more prone to unorthodox and real-time problem solving,
often necessary given limited resources.

3. Methods
3.1. YPAR Methods

CERCH engaged youth in harnessing scientific grade technologies for granular quan-
titative data collection, facilitated youth in enriching this data with qualitative data, com-
pensated youth for their time and, on request, provided supplementary skill building
workshops. Detailed in previous publications, the underlying framework, sequence, and
rationale of CERCH’s YPAR approach is summarized elsewhere [77,78]. CERCH staff,
in collaboration with RYSE and with input from Bay Area Air Quality Management Dis-
trict experts, created a YPAR project and accompanying environmental health literacy
curriculum to engage Richmond youth as co-researchers. Curriculum drew from years of
researcher experience and field-tested activities publicly available on UC Berkeley’s YPAR
Hub [79] as well as from nearly 10 years of CERCH YPAR expertise. Youth researchers
were provided a ~150-page reader assembled specifically for this project by staff, which
included self-care tips, background readings, tox-fact sheets, relevant research, conceptual
frameworks, case studies and potential intervention ideas.

Meeting content and study design progressed similar to previous CERCH YPAR
studies. Sequentially, youth built group trust, learned key foundational concepts and
gained increasing control over study activities, engaging in roughly 100+ hours of meetings
and activities and dozens of hours working independently. Meetings were held at RYSE, a
location convenient for the youth and where an array of additional youth opportunities
were available free of charge, including arts, education and justice, organizing, free meals,
and community health. Youth drew upon their personal experiences with air quality
challenges in their daily lives, identifying potential sources of emissions, and brainstorming
risk and protective factors in the vicinity. Youth were paid stipends for their engagement.
Local environmental justice leaders with expertise in air quality, the vast majority of
whom were people of color (and offered an honorarium), informed the youth about key
achievements, lessons learned and community concerns. Speakers included representatives
of CERCH, the Bay Area Air Quality Management District, Greenaction, West Oakland
Environmental Indicators Project, Air Watch Bay Area and Communities for a Better
Environment. Youth did background research on each speaker to shape the discussion,
creating prompts to acquire information relevant to the study.

CERCH researchers with expertise in air quality research trained youth in the use
of scientific-grade air samplers, including techniques to collect, analyze and interpret air
quality data. Youth used CalEnviroScreen Community Disadvantage maps and, drawing
upon their experiential expertise in these specific neighborhoods, brainstormed key loca-
tions where vulnerable populations may spend time, such as community centers, hospitals,
schools, stores and transit hubs. Visualized through these tools, youth discussed known
factors related to community vulnerability, air quality and other environmental health
threats that could compound the harms of poor air quality, and identified gaps that could
be filled by improved data collection in these spaces. A selection of 12 sites from this larger
pool of options were voted upon, balancing the potential significance of the site with need
for sufficient distance between each sampler to ensure adequate coverage within the target



Int. J. Environ. Res. Public Health 2021, 18, 554 7 of 18

census tracts. Prior to sampler deployment, study personnel and the youth visited the
sites to determine whether they were suitable for sampler installation. Considerations
included whether there were available streetlight poles to attach samplers to, whether
the terrain was safe to use a ladder on for deployment and other physical impediments.
Minor adjustments were made accordingly. A combination of Microsoft Excel, Google
Spreadsheets, Google Docs, Microsoft Powerpoint, Adobe Photoshop and Google Fusion
Tables were used to explore and co-analyze the data with the youth.

The project’s effects on the youth council members was gauged using pre- and post-
test questionnaires that included validated scales [77] coupled with qualitative feedback
via answers to reflection questions. To date, empowerment evaluation tools used for this
study have been used in several YPAR studies conducted by CERCH: Leadership Efficacy,
Resource Mobilization and Leadership Behavior, Community Engagement, Action Self
Efficacy and Socio-Political Skills [80]; Motivation to Control [81] Science Attitude, Self
Esteem and Motivation to Influence; and Participatory Behavior [82].

Data was collected and managed according to a protocol approved by the University
of California Berkeley’s Committee for the Protection of Human Subjects (protocol No.
2017-04-9899), by CITI certified staff trained in public health. Youth empowerment data
collection activities were detailed on approved assent forms (for minors under 18 years
of age), or consent forms for those over 18, which were verbally outlined to youth. It
was clarified that participation in evaluation was completely optional and that youth’s
participation, or lack or participation, in evaluation activities would not affect youth’s
ability to participate in the project overall or to access related opportunities. Youth under
18 years of age acquired parent signatures on a similar consent form, without which no
data would be collected.

3.2. Air Quality Data Collection Methods

With extensive input from the five youth researchers, a cohort limited in size by
funding constraints, our research targeted Richmond census tracts most impacted by en-
vironmental and social burdens. We concentrated sampling efforts in two of the most
socio-economically burdened tracts discussed earlier, due to high population density and
the presence of sensitive subpopulations (e.g., young children, those with asthma) as iden-
tified by the youth researchers. Our project combined scientific methods with community
engagement to: (1) better understand spatial features related to between-neighborhood
differences in outdoor air quality; (2) to investigate whether spatial variability in pollutant
levels contributes to potential population exposure disparities; and (3) to better understand
how spatial variability in multiple outdoor air pollutants correspond with Richmond’s
community-level risk factors. Passive samplers were selected as they are reliable for
gaseous air pollution measurement and well suited for community-involved research.

Youth researchers selected 12 air sampling sites based on knowledge gained from
curriculum on air pollution sources and susceptible sub-populations. Before entering the
field, youth were quizzed on the functions of key materials, and their use. Youth engaged
in adapting a protocol and practiced deployment on a pilot day. Checklists with images
were created to efficiently identify materials, follow the appropriate order of operations
and inventory supplies. Checklists allowed youth to easily double check equipment and
each other, building internal cohesion and teamwork skills. With supervision, youth de-
ployed 12 Ogawa passive samplers in residential neighborhoods in Atchison Village, North
Richmond, and areas south of Atchison in proximity to I-580. Samplers were placed at
each site for three weeks, from mid/late-December to mid-January (see Figure 1. Spot
noise measurements were performed (~10–15 min per sample site) during deployment and
retrieval. Data on community-level risk factors in sampled communities were collected and
analyzed for cumulative neighborhood vulnerabilities. Youth took the lead on Commu-
nity Mapping and PhotoVoice exercises, which helped to further contextualize combined
neighborhood risk factors.



Int. J. Environ. Res. Public Health 2021, 18, 554 8 of 18

Int. J. Environ. Res. Public Health 2021, 18, x 8 of 18 
 

 

levels contributes to potential population exposure disparities; and (3) to better under-
stand how spatial variability in multiple outdoor air pollutants correspond with Rich-
mond’s community-level risk factors. Passive samplers were selected as they are reliable 
for gaseous air pollution measurement and well suited for community-involved research. 

Youth researchers selected 12 air sampling sites based on knowledge gained from 
curriculum on air pollution sources and susceptible sub-populations. Before entering the 
field, youth were quizzed on the functions of key materials, and their use. Youth engaged 
in adapting a protocol and practiced deployment on a pilot day. Checklists with images 
were created to efficiently identify materials, follow the appropriate order of operations 
and inventory supplies. Checklists allowed youth to easily double check equipment and 
each other, building internal cohesion and teamwork skills. With supervision, youth de-
ployed 12 Ogawa passive samplers in residential neighborhoods in Atchison Village, 
North Richmond, and areas south of Atchison in proximity to I-580. Samplers were placed 
at each site for three weeks, from mid/late-December to mid-January (see Figure 1. Spot 
noise measurements were performed (~10–15 min per sample site) during deployment 
and retrieval. Data on community-level risk factors in sampled communities were col-
lected and analyzed for cumulative neighborhood vulnerabilities. Youth took the lead on 
Community Mapping and PhotoVoice exercises, which helped to further contextualize 
combined neighborhood risk factors. 

3.3. Data Analysis 
Sample sites were mapped (Figure 1) and statistical and spatial analyses of air quality 

and noise data were performed. Analyses were informed based on research questions 
from youth researchers. Together, we determined the following air quality and emissions 
source indicators: neighborhood differences in NO2 and SO2 concentrations; major road-
way density for 250 and 500 m circular buffers around each sampling site; roadway den-
sity and pollutant concentrations around sampling sites; railway density in 250 and 500 
m circular buffers; greenspace (normalized differential vegetation index (NDVI)) in 250 
and 500 m buffers; and federally regulated air emissions site density in 250 and 500 m 
buffers. To assess possible differences in cumulative impacts of air and noise pollution 
measurements, and emissions sources, summary scores were computed for the different 
indices. For example, the summary score for emissions sources was computed by first 
computing a Z-score for the density of each type of emission source indicator and sum-
ming these values for each sampling site. Univariable and multivariable linear regressions 
were used to determine the relationships between emission source indicators (e.g., road-
way density within 250 m) and air pollutant concentrations. 

 
Figure 1. Map of sample sites for Atchison Village, South of Atchison (along I-580), and North 
Richmond. Darker red colors of sample sites indicate higher NO2 concentrations. 
Figure 1. Map of sample sites for Atchison Village, South of Atchison (along I-580), and North
Richmond. Darker red colors of sample sites indicate higher NO2 concentrations.

3.3. Data Analysis

Sample sites were mapped (Figure 1) and statistical and spatial analyses of air quality
and noise data were performed. Analyses were informed based on research questions from
youth researchers. Together, we determined the following air quality and emissions source
indicators: neighborhood differences in NO2 and SO2 concentrations; major roadway
density for 250 and 500 m circular buffers around each sampling site; roadway density and
pollutant concentrations around sampling sites; railway density in 250 and 500 m circular
buffers; greenspace (normalized differential vegetation index (NDVI)) in 250 and 500 m
buffers; and federally regulated air emissions site density in 250 and 500 m buffers. To
assess possible differences in cumulative impacts of air and noise pollution measurements,
and emissions sources, summary scores were computed for the different indices. For
example, the summary score for emissions sources was computed by first computing a
Z-score for the density of each type of emission source indicator and summing these values
for each sampling site. Univariable and multivariable linear regressions were used to
determine the relationships between emission source indicators (e.g., roadway density
within 250 m) and air pollutant concentrations.

4. Results
4.1. Air Quality Results

A summary of measured NO2 and SO2 concentrations and noise levels are in Table 1.
A detailed summary of pollution levels for each site is in the Supplement (Table S1). For
context, during the same timeframe of our study, the average NO2 concentration measured
in our study (12.09 ppb) is similar to the average measurements made at the nearest U.S.
EPA monitoring station (13.24 ppb) that is located in the neighboring City of San Pablo.
For SO2, however, measurements made in our study were not similar to the nearest US
EPA ambient SO2 monitoring station (see Table 1). Figure 1 displays spatial locations of
each of the 12 air sampling sites. Significant differences in neighborhood ambient NO2
concentrations were observed (Figure 2), with a significantly lower level of NO2 observed
for sites in North Richmond. Linear regression models indicated higher levels of greenspace
(NDVI) were significantly associated with lower concentrations of NO2 (Supplement;
Figure S3). Greenspace within 250–500 m of sites explained 73% (p-value < 0.001) and 71%



Int. J. Environ. Res. Public Health 2021, 18, 554 9 of 18

(p-value < 0.001) of NO2 variability, respectively. The spatial density of railroads within
250 m (R2 = 0.45; p-value = 0.02) and major roadway density within 500 m (R2 = 0.32;
p-value = 0.055) were associated with higher NO2 concentrations. Noise levels were also
positively associated with NO2 concentrations (R2 = 0.30, p-value = 0.08). While aggregate
NO2 concentrations showed little correlation with the density of industrial emissions
sites, the site with the highest concentrations of NO2 (14.9 ppb) was closest to a major
oil refinery and was 12% higher than the NO2 measurements from the nearest U.S. EPA
ambient air quality monitoring station in San Pablo. Concentrations of SO2 did not show
significant associations with spatial features, with noise levels, or between neighborhoods.
As suggested in Figure 3, census tracts with the highest Non-Hispanic Black populations
(south of Atchison) experienced the highest NO2 concentrations, the highest levels of
cumulative air and noise pollution levels, and the highest cumulative density of emissions
sources. In addition, tracts south of Atchison with the highest proportion of non-Hispanic
Blacks had the lowest levels of neighborhood greenness (Supplement Figure S3). Refer to
the Supplement (Supplement Figures S1–S3) for further spatial distributions of densities
and built environment features considered. We note that although we conducted only
spot measurements of sound levels at our monitoring sites, the average site decibel levels
recorded in our study exceeded the City of Richmond’s noise ordinance limits for exterior
noise for every zoning type except for Heavy and Marine Industrial Zones (the highest
zoned area for noise). The average noise measurement detected in our study reached the
Heavy and Marine Industrial Zone ordinance threshold of 75 decibels [83].

Table 1. Average air pollution and noise pollution measurement results.

NO2 SO2 Noise (Decibels)

Average (standard deviation) 12.09 (1.97) 0.06 (0.05) 74.64 (5.34)
Average air pollution measurements for NO2 and SO2 and decibel levels across all 12 sample sites in Richmond,
CA. During the same time period, the averages from the nearest US EPA monitor is 13.24 ppb for NO2 and for
SO2 is 0.430 ppb.

Int. J. Environ. Res. Public Health 2021, 18, x 9 of 18 
 

 

4. Results 
4.1. Air Quality Results 

A summary of measured NO2 and SO2 concentrations and noise levels are in Table 1. 
A detailed summary of pollution levels for each site is in the Supplement (Table S1). For 
context, during the same timeframe of our study, the average NO2 concentration meas-
ured in our study (12.09 ppb) is similar to the average measurements made at the nearest 
U.S. EPA monitoring station (13.24 ppb) that is located in the neighboring City of San 
Pablo. For SO2, however, measurements made in our study were not similar to the nearest 
US EPA ambient SO2 monitoring station (see Table 1). Figure 1 displays spatial locations 
of each of the 12 air sampling sites. Significant differences in neighborhood ambient NO2 
concentrations were observed (Figure 2), with a significantly lower level of NO2 observed 
for sites in North Richmond. Linear regression models indicated higher levels of green-
space (NDVI) were significantly associated with lower concentrations of NO2 (Supple-
ment; Figure S3). Greenspace within 250–500 m of sites explained 73% (p-value < 0.001) 
and 71% (p-value < 0.001) of NO2 variability, respectively. The spatial density of railroads 
within 250 m (R2 = 0.45; p-value = 0.02) and major roadway density within 500 m (R2 = 0.32; 
p-value = 0.055) were associated with higher NO2 concentrations. Noise levels were also 
positively associated with NO2 concentrations (R2 = 0.30, p-value = 0.08). While aggregate 
NO2 concentrations showed little correlation with the density of industrial emissions sites, 
the site with the highest concentrations of NO2 (14.9 ppb) was closest to a major oil refinery 
and was 12% higher than the NO2 measurements from the nearest U.S. EPA ambient air 
quality monitoring station in San Pablo. Concentrations of SO2 did not show significant 
associations with spatial features, with noise levels, or between neighborhoods. As sug-
gested in Figure 3, census tracts with the highest Non-Hispanic Black populations (south 
of Atchison) experienced the highest NO2 concentrations, the highest levels of cumulative 
air and noise pollution levels, and the highest cumulative density of emissions sources. In 
addition, tracts south of Atchison with the highest proportion of non-Hispanic Blacks had 
the lowest levels of neighborhood greenness (Supplement Figure S3). Refer to the Supple-
ment (Supplement Figures S1–S3) for further spatial distributions of densities and built 
environment features considered. We note that although we conducted only spot meas-
urements of sound levels at our monitoring sites, the average site decibel levels recorded 
in our study exceeded the City of Richmond’s noise ordinance limits for exterior noise for 
every zoning type except for Heavy and Marine Industrial Zones (the highest zoned area 
for noise). The average noise measurement detected in our study reached the Heavy and 
Marine Industrial Zone ordinance threshold of 75 decibels [83]. 

 
Figure 2. Boxplots displaying measured concentrations. (A) NO2 and (B) SO2 for each Richmond neighborhood monitored 
in our study (21 December–15 January 2018). Asterisk (*) indicates that North Richmond had significantly lower (p < 0.05) 
NO2 concentrations compared to all other monitored neighborhoods. Unfilled circles indicate outliers. 

Figure 2. Boxplots displaying measured concentrations. (A) NO2 and (B) SO2 for each Richmond neighborhood monitored
in our study (21 December–15 January 2018). Asterisk (*) indicates that North Richmond had significantly lower (p < 0.05)
NO2 concentrations compared to all other monitored neighborhoods. Unfilled circles indicate outliers.



Int. J. Environ. Res. Public Health 2021, 18, 554 10 of 18

Int. J. Environ. Res. Public Health 2021, 18, x 10 of 18 
 

 

 
Figure 3. Boxplots of air and noise pollution, sources and demographics. (A) Neighborhood-level summary scores for air 
and noise pollution measurements (sum of NO2 + SO2 + noise Z-scores); (B) neighborhood-level summary scores for air 
pollution sources (sum of major roadway density + railway density + regulated site density Z-scores), Asterisk (*) indicates 
that North Richmond had significantly lower (p < 0.05) NO2 concentrations compared to all other monitored neighbor-
hoods; (C) proportion of census tract that are Non-Hispanic Black; and (D) proportion in census tract that are Hispanic. 
Unfilled circles indicate outliers. 

Table 1. Average air pollution and noise pollution measurement results. 

 NO2 SO2 Noise (Decibels) 
Average (standard deviation) 12.09 (1.97) 0.06 (0.05) 74.64 (5.34) 

Average air pollution measurements for NO2 and SO2 and decibel levels across all 12 sample sites 
in Richmond, CA. During the same time period, the averages from the nearest US EPA monitor is 
13.24 ppb for NO2 and for SO2 is 0.430 ppb. 

4.2. YPAR Results 
Results are drawn from a very small sample size, n = 5, limited due to funding con-

straints. Though there were no exclusion criteria for participation other than being of high 
school age and residing in the Richmond area, no youth who remained committed 
throughout the entire project year identified as white, and all identified as female. Similar 
to previous CERCH YPAR studies, limited resources meant that extensive qualitative data 
could not be collected. However, results parallel those of previous CERCH YPAR evalu-
ations that had greater sample sizes. Of 68 total fields, and despite relatively high baseline 
measurements in many fields, results improved in nearly every category. The 11 most 
notable improvements appeared to be patterned in fields related to youth’s community 
engagement, attitudes towards one’s neighborhood and voicing one’s opinions (Table 2). 

Table 2. Validated empowerment measures with strongest pre-post improvement. 

Prompt (Some Abbreviated) Baseline Post-Test 
I can make a “real difference” in improving my city 40% strongly agreed 100% 
I can “use research results to come up with realistic recommendations.” 40% strongly agreed 100% 
“If I want to improve a problem in my city, I know how to gather useful data about the issue.” 20% strongly agreed 80% 
“I am inclined to feel like a failure.” 20% strongly disagreed 80% 
“I am satisfied with myself.” 20% strongly agreed 60% 
“I want to have as much say as possible in making decisions in my school.” 60% strongly agreed 100% 
“My neighborhood has lots of things I can use to help make my neighborhood better.” 0% strongly agreed 60% 
“I like my neighborhood.” 20% strongly agreed 100% 

Figure 3. Boxplots of air and noise pollution, sources and demographics. (A) Neighborhood-level summary scores for air
and noise pollution measurements (sum of NO2 + SO2 + noise Z-scores); (B) neighborhood-level summary scores for air
pollution sources (sum of major roadway density + railway density + regulated site density Z-scores), Asterisk (*) indicates
that North Richmond had significantly lower (p < 0.05) NO2 concentrations compared to all other monitored neighborhoods;
(C) proportion of census tract that are Non-Hispanic Black; and (D) proportion in census tract that are Hispanic. Unfilled
circles indicate outliers.

4.2. YPAR Results

Results are drawn from a very small sample size, n = 5, limited due to funding con-
straints. Though there were no exclusion criteria for participation other than being of
high school age and residing in the Richmond area, no youth who remained committed
throughout the entire project year identified as white, and all identified as female. Similar
to previous CERCH YPAR studies, limited resources meant that extensive qualitative data
could not be collected. However, results parallel those of previous CERCH YPAR evalua-
tions that had greater sample sizes. Of 68 total fields, and despite relatively high baseline
measurements in many fields, results improved in nearly every category. The 11 most
notable improvements appeared to be patterned in fields related to youth’s community
engagement, attitudes towards one’s neighborhood and voicing one’s opinions (Table 2).

Personal responses to qualitative reflection prompts indicated youth’s successful ac-
quisition of knowledge related to key concepts, that the project was perceived as impactful
and that youth improved in environmental health literacy. Youth’s successful completion
of data collection and peer education activities is also indicative of project success, as is
their library of ~1500 high resolution photographs of assets and challenges in the com-
munity, their “zine”, a short video they made about youth’s engagement in science and
several successful presentations. Anecdotally, staff observed an exceptionally high degree
of team building, and an overwhelmingly positive and collegial atmosphere between youth
themselves and with staff during meetings and project tasks.

Beyond the scope of the project, steps were taken to ensure that youth’s needs were
met, supporting their access to opportunities. As youth were applying to college, extra
workshops were offered on college application personal statement writing, key dates,
and application tips. Youth were given the option of submitting their statements to staff
for review and provided with extensive feedback. Youth were also invited to tour UC
Berkeley and attended a panel with UC Berkeley undergraduate students of color who



Int. J. Environ. Res. Public Health 2021, 18, 554 11 of 18

spoke about their experiences and provided tips. All youth were accepted to, and attended,
leading universities. Verbally, 60% expressed that because of this program they would
major in environmental studies or environmental science. The remaining 40% expressed
they planned to integrate lessons learned about environmental health into their fields
of study. 100% applied to external summer employment opportunities that related to
environmental health and 40% were able to secure paid employment, directly addressing
air quality concerns. To date, staff have been able to support 40% of youth in obtaining
additional paid placements with environmental health organizations and 60% in presenting
to graduate level classes. Though these were not explicit study objectives, they reflect the
spirit of participatory research, where researchers take measures to support capacity and
facilitate opportunities to access important resources. We recommend that researchers
engaging in participatory research take similar measures to ensure organic and iterative
support beyond explicit study aims, especially those with the privileges associated with
being part of an academic institution, with advanced credentials or with otherwise high
socio-economic status.

Table 2. Validated empowerment measures with strongest pre-post improvement.

Prompt (Some Abbreviated) Baseline Post-Test

I can make a “real difference” in improving my city 40% strongly agreed 100%
I can “use research results to come up with realistic recommendations.” 40% strongly agreed 100%
“If I want to improve a problem in my city, I know how to gather useful data about the issue.” 20% strongly agreed 80%
“I am inclined to feel like a failure.” 20% strongly disagreed 80%
“I am satisfied with myself.” 20% strongly agreed 60%
“I want to have as much say as possible in making decisions in my school.” 60% strongly agreed 100%
“My neighborhood has lots of things I can use to help make my neighborhood better.” 0% strongly agreed 60%
“I like my neighborhood.” 20% strongly agreed 100%
“I try to help people in my neighborhood when they are in need.” 0% strongly agreed 60%
“If issues come up that affect students at my school, we do something about it.” 40% strongly agreed 80%
“If issues come up that affect youth in my city, we do something about it.” 0% strongly agreed 80%

5. Discussion
5.1. Air Quality

Findings show that multiple features of the built environment were significantly
associated with NO2 concentrations. These correlations were in the expected directions
(e.g., railways were positively correlated with NO2). Possible cumulative impacts were also
observed in our study. Noise levels were correlated with higher levels of NO2, suggesting
that communities experiencing higher NO2 levels are doubly burdened with noise pollution.
Sampled census tracts with the highest proportion of Non-Hispanic Blacks experienced
the highest levels of NO2. Again, this suggests that Non-Hispanic Blacks, a historically
marginalized group, may be doubly exposed to higher levels of air pollution and social
stressors compared to other Richmond communities monitored in our study. Greenspace
was significantly associated with lower NO2 concentrations and was also the strongest
predictor of NO2. This suggests that greenspace may mitigate some air quality concerns.
Moreover, greenspace has been shown in other studies to be conducive to improvements in
physical activity [84,85] and real estate value [86,87], thus investment may address multiple
symptoms of structural violence. Research further indicates that greenspace may have
positive impacts on a range of human health factors [88,89]. A final report was submitted
to the funder, the Bay Area Air Quality Management District. When published, this paper
will also be submitted to BAAQMD, as well as personnel at the California Air Resources
Board, the National Institutes of Environmental Health Sciences and additional colleagues.

Evidence indicates that remedial air quality policies backed by enforcement can yield
high socio-economic gains. For example, while it is estimated that actions needed to
meet US Clean Air Act benchmarks would require USD 65 billion from 1990 to 2020, the
positive economic value of air improvements over those 30 years was projected to be
USD 2 trillion, a return of more than 30 to 1 [90]. It has been estimated that the economic



Int. J. Environ. Res. Public Health 2021, 18, 554 12 of 18

value of eliminating health disparities more broadly is in the trillions of dollars [91] with
savings from eliminating racial health disparities specifically estimated in the hundreds
of billions to trillions over time [92]. These gains do not account for qualitative gains in
human well-being or in overall community level justice. Sustainable improvements must
address aspects of exposure risk, the natural and built environments, government and
social change [93]. More so, they must be conducive to an accessible and shared humanity.

5.2. Community Science

Though baseline responses from youth in this project were somewhat high overall,
likely due to self-selection bias wherein already motivated youth had a higher likelihood
of seeking out and enrolling in the program, improvements were apparent. The successful
completion of major scientific grade tasks by youth in this and several of CERCH’s prior
YPAR studies solidifies the assertion that community members and youth specifically
should be meaningfully integrated into all feasible aspects of study design, implementation,
analysis, and dissemination of results.

Though CERCH staff supervised all work extensively, their primary role became
technical consultant rather than relying on a top-down chain of command. This approach is
reflective of a commitment to fostering flat hierarchies and inclusivity across study activities.
In early stages, youth continually turned to staff for advice, who in turn facilitated Freirean
dialogue within the group, with the aim of helping the youth better harness their own
collective assets and build a community of practice. As sampling progressed, youth
increasingly consulted with each other, drawing on their “experiential expertise” to execute
the majority of tasks without staff assistance. In longer term projects, this may make
research processes more efficient, reducing the workloads of senior researchers and creating
new opportunities for community members to build skills and meaningful opportunities
for promotion.

Central tenets of YPAR draw from emancipatory pedagogy, seeking to dismantle
systems of structural violence discussed and aimed at dissipating hierarchy between
researchers with advanced credentials and members of communities unable to access
those opportunities, outlined by Freire’s Critical Pedagogy [94]. Integrating “experiential
expertise” of those with lived experiences into scientific research study design and protocols
mirrors Black feminist Standpoint Theory [95], where personal experiences illuminate larger
societal patterns of violence and resistance. Combined, aspects of CBPR resonate with
the concept of Strong Objectivity [96], that scientific fields require increased, and innately
subjective, reflection and diverse inclusion in order to acknowledge, address, and control
for, human researcher’s implicit biases, thus improving aggregate objectivity. Greater
diversity fosters a broader variety of subjectivities that can then cancel out, acknowledge,
or balance biases implicit in demographics currently overrepresented in STEM fields. Each
line of thought emphasizes the underutilization of diverse “everyday” knowledge or
“experiential expertise”, asserting multiple ways of knowing, with academic knowledge
being just one among many others yet also potentially benefiting from each.

Voices often excluded from decision-making processes are incorporated with CBPR.
Community-researcher collaborations foster constructive conditions that extend far beyond
data, expanding the perspectives of researchers as they conduct subsequent work and
create long term opportunities for communities to access and adapt rigorous research
methods, technologies and institutions. YPAR can improve local capacity to conduct
research, better garner public interest in sciences and create desirable local employment
or educational opportunities as well as provide an enriching venue for youth to engage
their local community, spend time constructively, socialize with other youth and build
team-work skills.

CERCH takes special measures to support youth in college preparation such as panels
with youth of color enrolled in top universities, admissions counselor meetings, personal
statement workshops and deadline reminders. The work herein may also be a boon to
youth’s resumes as they apply for said positions. Thus, YPAR can create pathways to



Int. J. Environ. Res. Public Health 2021, 18, 554 13 of 18

college success, which may help diversify public health program enrollment and workforce.
Diversification of STEM adds a multitude of perspectives and approaches, increasing the
probability that new and effective interventions will be developed. Inclusion of marginal-
ized folks may lend a more nuanced understandings of how structural violence and social
determinants of health function, as these populations have familiarity with their impacts.
Fostering marginalized group’s attainment of educational and employment opportunities
remediates factors associated with increased chances of bearing environmental burdens.
Thus, diversification is both a means to better data and interventions, and end in itself,
reducing the probability of structural harm and improving the probability of developmen-
tal success. Several youth involved in this study actively continue community outreach
efforts, and are pursuing or have already engaged in STEM careers. Several have also
worked to foster youth mentorship, college preparedness and diversifying STEM fields for
the next generation.

Short study duration and limited funding were impediments to meaningful and long
term community action in the study outlined here. Drawing upon the precedent set by
this study, a new grant was submitted with more than double the budget and duration.
This grant includes twice the formally trained research personnel and supports a cohort
of youth researchers twice as large. The new study focuses on real time measurements
of indoor air pollution in relation to gas stove use in residences that include a child with
asthma. This more targeted focus is more directly amenable to individual intervention
and may have more immediate and observable impacts than the previous outdoor study
overviewed here. The study focus is also complimentary to specific regional regulations
regarding indoor air pollution that are in development, including gas stoves. An iterative,
and community informed, learning process has led to a new project wherein potential
policy implications are more cohesive and streamlined, a challenge faced by the study
outlined in this paper.

Renewed interest in addressing structural racism, catalyzed by the murder of George
Floyd, has also prompted the City of Richmond to deepen their commitment to racial
justice. Much of the current focus regards police violence and incarceration inequities. We
hope that our research findings, framed in the context of structural violence and indicating
patterns wherein low income and people of color bear disproportionate air quality burdens,
coupled with the exacerbated impacts of COVID-19, may help illuminate larger policies
and systems of resource distribution that center marginalized communities, and a “freedom
to breathe”.

5.3. Limitations of Environmental Monitoring Data

Despite our community science findings, several limitations are notable. First, our air
sampling took place during a three-week period starting 21 December 2017 and ending
in mid-January 2018. Therefore, our findings are generalizable only to the time period
sampled and do not capture seasonal variations of air pollutant levels. That being said,
we note that NO2 concentrations measured with the Ogawa samplers were very similar
when compared against NO2 measurements made at the nearest US EPA ambient air
quality-monitoring site (see Table 1). This finding gives added external validity to our
NO2 measurements. We are less confident about the external validity for SO2 since SO2
levels measured were at least an order of magnitude lower than the nearest US EPA air
monitoring site. We note that the two Ogawa samplers in closest proximity to the US EPA
monitoring site were at least at the same order of magnitude of SO2 concentrations (0.12 ppb
versus 0.43 ppb). However, SO2 observations made in our study must be interpreted with
caution. Further, due to lack of resources, noise measurements were made using spot
checks only and do not represent 24 h measurements, as is typically done. However, our
spot measurements indicated rather high levels of ambient noise at each site location. These
preliminary findings warrant further investigation and follow up.



Int. J. Environ. Res. Public Health 2021, 18, 554 14 of 18

6. Conclusions

Made overt by mass social movements such as Black Lives Matter, communities
continue to resist at the crux of structural racism and environmental injustice. By further
naming, contextualizing, and quantifying deleterious patterns of environmental disparities,
these phenomena are more clearly revealed to be artificial, abnormal, and requiring redress.
It is our hope that environmental health disparities, and broader awareness of intersectional
structural violence, may be increasingly incorporated into social movements, as well
as policy decisions. The imperative nature of issues discussed is exacerbated by the
devastation COVID-19 has had, and continues to have, especially on communities of color,
and especially among communities exposed to air pollution. In this regard, we encourage
researchers to expand their commitment to community based participatory research and
contextualize findings within historical and contemporary violence. Participatory models
help generate more granular data and more efficiently render meaningful results that are
actionable for multidimensional interventions, informed by deeper understandings of
how structural violence, and eco-apartheid interact to probabilistically determine built
and social environments that deeply affect community member’s health. Through YPAR,
youth bring a fresh, often marginalized, perspective and hope, helping researchers and
communities reify why efforts for improved health equity are of paramount importance,
beyond data and abstraction. If properly conducted, the practice of community inclusion
helps erode unbalanced power dynamics and socio-economic inequities, improves the
long-term sustainability of actions within affected communities, and bolsters capacity to
push for a healthier future. Exceeding public health as it is often bound, this may be more
conducive to a collective belonging and public healing.

Supplementary Materials: The following are available online at https://www.mdpi.com/1660-460
1/18/2/554/s1.

Author Contributions: Formal analysis, E.S.C.; investigation, E.S.C., B.R.W. and Y.A.W.; methodol-
ogy, E.S.C., project administration, E.S.C. and K.G.H.; writing—original draft, J.E.S.N. and E.S.C.;
writing—review and editing, B.R.W., Y.A.W. and K.G.H. All authors have read and agreed to the
published version of the manuscript.

Funding: The author(s) disclosed receipt of the following financial support for the research, au-
thorship, and/or publication of this article: This research was funded by the Bay Area Air Quality
Management District, Grant No. PP14316.

Institutional Review Board Statement: The study was conducted according to the guidelines of
the Declaration of Helsinki. Data was collected and managed according to a protocol approved
on 08/07/2017 by the University of California Berkeley’s Committee for the Protection of Human
Subjects (protocol No. 2017-04-9899), by CITI certified staff trained in public health.

Informed Consent Statement: Informed consent was obtained from all subjects involved in the
study, and from their parents if the subject was under the age of 18 years old.

Data Availability Statement: Non-human subjects raw data is included in this paper as a supple-
mental table.

Acknowledgments: Authors thank the RYSE center, including Bailey Ward, Yahna Williamson,
Melissa Merino, Dashia Wright, Maxine Dimalanta, Dan Reilly, Tara Malik, Francisco Rojas, Andrew
Yeung and Randy Joseph for their support of this project, meetings and an array of materials, trainings
and expertise. We also thank Regan Patterson (BAAQMD), and Margaret Gordan (West Oakland
Environmental Indicators Project) for informing curriculum materials and outreach. We thank
Brenda Eskenazi and Asa Bradman for their work supporting the original CHAMACOS YCC model
and Daniel Madrigal for his extensive work developing foundational curriculum and processes
for CERCH’s YPAR. Additional thanks to Jordyn Wallenborn and Lucia Calderon at CERCH for
suggesting edits.

Conflicts of Interest: The authors declare no conflict of interest.

https://www.mdpi.com/1660-4601/18/2/554/s1
https://www.mdpi.com/1660-4601/18/2/554/s1


Int. J. Environ. Res. Public Health 2021, 18, 554 15 of 18

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	Introduction 
	Background 
	Air Pollution 
	Structural Violence 
	Framework 
	Transgenerational Structural Violence 
	Contemporary Structural Violence 
	Contemporary Resistance to Symptoms of Structural Violence 
	Structural Violence in Richmond, CA 

	Air Quality Research Gaps in Richmond 
	Youth Participatory Action Research (YPAR) Model 

	Methods 
	YPAR Methods 
	Air Quality Data Collection Methods 
	Data Analysis 

	Results 
	Air Quality Results 
	YPAR Results 

	Discussion 
	Air Quality 
	Community Science 
	Limitations of Environmental Monitoring Data 

	Conclusions 
	References