Previous studies

Location, data, and descriptive statistics

The setting for this study is in Seattle, WA, which is often characterized by extreme economic inequalities across neighborhoods (Drewnowski, Rehm, and Solet Reference Drewnowski, Rehm and Solet2007). In the State of Washington, there are 10 counties whose minority population exceeds 25 percent of their total population. Eight of these counties are located in Eastern Washington, where agriculture has a significant presence. The other two counties with greater than 25 percent minority populations are King and Pierce counties, where the large metropolitan areas of Seattle, WA, and Tacoma, WA, respectively, are located. Seattle, WA, has a distinct race/ethnicity contrast with the 68.7 percent of residents identifying as white in 2010. This percentage has fallen slightly to 67.3 percent in the 2019 census estimate, while the overall population in Seattle, WA, increased by 23 percent to over 750,000. Seattle, WA, also has the largest Asian, African American, and Hispanic populations of any city in the Pacific Northwest. The city has seen a major increase in immigration in recent decades. The foreign-born population has increased by 40 percent between the 1990 and the 2010 censuses.

In 2010, 9.5 percent of the total Seattle, WA population was African American. This has fallen to 6.8 percent in 2020, which is the lowest in 50 years. Balk (Reference Balk2020) argues that gentrification and skyrocketing costs of living in Seattle, WA, had implications for the drop in the percentage of African American residents. The Hispanic population represented 8.6 percent of the total population in 2010. They had been the most rapidly growing population group in Washington State, with an estimated increase of 71.2 percent between 2000 and 2010. However, the percentage of the population in Seattle, WA, who is Hispanic also fell in the 2019 census estimates to 6.7 percent. The Asian population represented 14.4 percent of the total Seattle, WA, population in 2010. This population experienced a 48.9 percent growth between the years 2000 and 2010. The Asian population in Seattle, WA, grew further to a 2019 estimate percentage of 15.4 percent. Note that these percentages do not include multiracial residents who constituted 6.9 percent in the 2019 census estimate.

We examine whether racial disparities exist in access to grocery stores in the Seattle, WA, metropolitan area in terms of travel distance and travel time. Since we are interested in the association between the access to grocery retailers and race/ethnicity, poverty, and other demographic factors, we combine sociodemographic data from the 2020 census tract level for Seattle, WA, to characterize the neighborhoods. Missing values of some variables were filled using the 2019 American Community Survey under the assumption that the sociodemographic characteristics of a census tract do not change drastically in a year.

The database includes a large number of variables that are relevant for understanding socioeconomic factors for race/ethnicity comparisons. It is impossible to accurately analyze the role of race without regarding poverty or analyze poverty without considering the role of race. It would depict an inaccurate measurement of socioeconomic status factors in determining the spatial accessibility of grocery retailers. This is particularly important given the history of racial segregation and economic restructuring in low-income neighborhoods in Seattle, WA. For example, Figure 1 depicts how the median household income has a negative association with the percentage of minority populations in Seattle, WA. Figure 2 shows how the SNAP-recipient households have a positive correlation with the percentage of minority residents. Therefore, we include both racial and income-related variables in the analysis. Consistent with the literature, we parsimoniously choose racial composition, vehicle access, education, income, employment, property values, and population density (e.g., Amin, Badruddoza, and McCluskey Reference Amin, Badruddoza and McCluskey2021).

Figure 1. Median Household Income and Racial Composition of Census Tracts in Seattle. Source: Authors’ Calculation Using the U.S. Census 2020 and American Community Survey 2019 Data.

Figure 2. SNAP-Recipient Population and Racial Composition of Census Tracts in Seattle. Source: Authors’ Calculation Using the U.S. Census 2020 and American Community Survey 2019 Data.

The response variables: (1) road distance to the nearest grocery store (in meters) and (2) driving time to the nearest grocery store (in seconds) from the center of the census tract were calculated by the authors. Grocery retailers are defined as supercenters (e.g., Sam's Club, Walmart, and Costco) and full-line grocery retailers (e.g., Albertson's, Fred Meyer, Safeway, QFC, Trader Joe's, Whole Foods, and others) associated with a national or regional grocery chain or an independent full-service grocery store. To identify grocery retailers, we utilize the Reference USA 2010 database of grocery stores in Washington State. In addition, we utilize GIS data from the City of Seattle government website, as well as the Google online directory search, to verify the addresses of these grocery retailers and to identify additional grocery retailers. Figure 3 provides a detailed map for Seattle grocery stores and tract centroids.

Figure 3. Seattle Full-Service Grocery Stores and Tract Centroids Used in the Data.

Source: Authors’ Calculation Using the ArcGIS Software.

We confirmed the addresses of additional grocery retailers not included in the Reference USA database or the food facilities database of the GIS department of the Seattle government. There are 112 full-service grocery retailers included in the Seattle metropolitan area within a 15-mile buffer of King County. The additional 15-mile buffer helped to ensure that grocery retailers for the sample neighborhoods are included. We linked the locations of all of the grocery retailers to the 2020 U.S. Census tract file for the Seattle metropolitan area based on location points.

The descriptive statistics for all variables are presented in Table 1. The mean travel distance to the nearest supermarket is about 1,060 m (with a mean of 1,277 m and a range of 32.33–3,668 m), and the median driving time is about 80 s (with a mean of 95 s  and a range of 2.9–823 s, i.e., 13.7 min). The mean of the population within the census tracts is white with 61.16 percent, followed by Asian (17.26 percent), Hispanic (8.24 percent), black (6.89 percent), and others. The median household income is about $94,045, with a standard deviation of $33,803. The population density is calculated as the total population per square mile. The mean population density in the census tracts is 1,616 people per square mile, with a standard deviation of 1,550. The mean unemployment rate was 4 percent and, on average, about 5.5 percent people in a census tract received SNAP benefits. Median house values are about $675,000.

Table 1. Descriptive statistics

Source: American Community Survey 2019 and U.S. Census 2020 for demographic data. Travel time and distance were calculated by authors using ArcGIS software.

Figure 4 provides simple nonparametric representation of the association between access to the nearest grocery retailer and tract characteristics. The distance is measured by the travel distance in meters. We use a log transformation of the income variable to remove the effects of extreme observations. Tracts with greater income and SNAP recipients, respectively, show positive and negative relationships with the travel distance to the nearest full-service grocery store. The white population shows almost zero correlation with the distance, whereas the Asian population, no-vehicle households, and the education variable show a negative correlation. The figure also implies that tracts with other minorities, especially Hispanics and African Americans, have a greater travel distance to grocery stores than other tracts. However, we want to check if the mean distance to grocery stores varies by the presence of minorities, holding other variables constant. The following section discusses econometric techniques required to further understand how healthful food access differs across neighborhoods.

Figure 4. The Relationship Between Distance to the Nearest Grocery Measured by Road Length (Meters) and Tract Characteristics in Seattle. Note: Figures Show Scatterplots of the Raw Data and Linear Fit with 95 Percent Confidence Interval.

Econometric methods

Amin, Badruddoza, and McCluskey (Reference Amin, Badruddoza and McCluskey2021) discuss two common measures of food access in the literature: (1) distance-based measure that uses the distance from household or tract location to the healthful food retailers and (2) density-based measure that uses the percentage of healthful food retailers in an area. The former primarily is used to define food deserts and is common in small-scale localized studies because measuring the distance at a large scale has an additional cost. The latter is used by several studies, including Amin, Badruddoza, and McCluskey (Reference Amin, Badruddoza and McCluskey2021), to measure food access at the national level. The distance can be used as a proxy for access, but it is only one factor. Access to healthful food retailers depends on many additional factors, including income, vehicle access, ease of use of public transportation, density of traffic, travel time, and travel route. Consumers’ distance to a large grocery store is often used as a proxy for better access to a good selection of high-quality, lower-cost healthy foods. Drewnowski et al. (Reference Drewnowski, Aggarwal, Hurvitz, Monsivais and Moudon2012), for example, found that the distance to the nearest grocery store is a good predictor of healthier eating and lower risk of obesity and chronic disease. Much of the literature uses some form of distance, and it is one objective measure for which data are available.

Direct measurement and comparison of the availability of items in grocery retailers could have generated the best possible dataset. However, such a survey would have been prohibitively expensive. The time needed to travel from one's residence to the grocery store is another informative indicator of accessibility in addition to physical distance. Given that a significant proportion of the population living in poverty is concentrated in the more densely populated central district of Seattle, WA, travel times to grocery retailers are likely longer for those living in poverty, and the implication is that the findings of differences in accessibility by race/ethnicity and proportion of the population living in poverty are progressing. Understanding the complexity of the issue, we choose both distance-based and time-based measures as factors that represent access to grocery retailers. The distance of residents to grocery retailers was measured using (1) the length of the road grocers need to travel to go to the nearest grocery retailer and (2) the time required to travel to go to the nearest grocery retailers. We also control for access to a private vehicle.

Apparicio, Cloutier, and Shearmur (Reference Apparicio, Cloutier and Shearmur2007) show geographic accessibility of residential areas to selected healthcare services using different distance types. The centroids (geometric centers) of those neighborhoods served as proxies of the locations. Therefore, the grocery retailer's accessibility is represented by the distance to the nearest supermarket for a resident positioned in the middle of the neighborhood (census tract). To develop an understanding of access to healthful foods, we follow Zenk et al.'s (Reference Zenk, Schulz, Israel, James, Bao and Wilson2005) methods with some deviation and with a focus on racial composition. The objective is to assess whether the percentage of different races/ethnicities in the neighborhoods of Seattle, WA, affects the location of grocery stores. As a proxy for poverty, we use SNAP-recipient status. There are two standard hypotheses for the models in this study.

We begin with a simple linear equation:

(1) $$\matrix{ {d_i = {\rm \alpha } + \mathop \sum \limits_{\,p = 1}^k x_{ip}{\rm \beta }_{ip} + {\rm \epsilon }_i\;} \cr } $$

where d _i is the distance to the nearest grocery retailer from the census tract centroid—measured by road length and travel time, x _ip is a socioeconomic factor associated with the distance, α is the intercept, β _ip is the parameter of interest, and ε _i represents the error term. We take the log of the response variables for two reasons. First, to lessen the effects of extreme observations. The variables are not normally distributed; the Shapiro–Wilk W statistic is rejected at the 1 percent level for road length and travel time. Second, the above association may not be linear. We use a left-hand Box–Cox specification to find the appropriate functional form. That is, we use a maximum likelihood (ML) approach and iteratively solve for the power of d _i . The estimated powers approach zero for both road length and travel time, and we reject the null hypothesis of the power being −1 or 1 at the 1 percent level of significance. Hence, we choose a log-linear specification for the model above.

Another concern of estimation is spatial autocorrelation. The spatial data are frequently characterized by positive spatial autocorrelation or the tendency for neighborhoods that are near each other in space to share similar attributes. Ignoring spatial interlinkages may lead to an overestimation of the true disparities. Following Wang et al. (Reference Wang, Tao, Qiu and Lu2016), we apply an SAR model defined as

(2) $$\matrix{ {d_i = {\rm \alpha } + \mathop \sum \limits_{\,p = 1}^k x_{ip}{\rm \beta }_{ip} + {\rm \lambda }\mathop \sum \limits_{\,j = 1}^J w_{ij}d_i + {\rm \epsilon }_i\;} \cr } $$

where the term w _ij is an element of the spatial neighborhood matrix that takes 1 for neighboring census tracts and zero otherwise, and the parameter λ represents the spatial influence of neighboring access on the access of the ith track. The SAR model extends linear regression by allowing outcomes in one area to be affected by outcomes in nearby areas or errors from nearby areas. However, the SAR model is more appropriate for the current exercise because the spatial-error model only allows for spatial dependence among unobserved disturbances and ignores spatial spillover effects.

Applying simple ordinary least squares (OLS) on the model above would yield inconsistent estimates and biased coefficients for λ. There are two ways to estimate the SAR model: a ML estimator as proposed by Anselin (Reference Anselin1988) and the generalized method of moments instrumental variables (GS2SLS) (Kelejian and Prucha Reference Kelejian and Prucha1998). Discussing the econometric derivation of these models is beyond the scope of the article, so we refer interested readers to Gibbons and Overman (Reference Gibbons and Overman2012). We present the results from both methods for completeness.

Limitations and future directions

There are several limitations to the study. For instance, we do not consider social barriers (such as crime) or other nonspatial factors (e.g., operating hours) that affect accessibility, nor do we consider individual access to grocery retailers, which will show a discrepancy by residents’ locations within neighborhoods and by individual opportunity costs such as time, access to a car, income, and physical functioning. Behavior and choices cannot be homogeneous for race/ethnicity or for the proportion of the population living in poverty. Future studies should include cultural differences in diet, and preferences for food in stores to properly measure the difference between Hispanic and Asian populations’ access to supermarkets.

The cross-sectional nature of the study precludes the definitive establishment of causal ordering among neighborhood race/ethnicity, the proportion of the population living in poverty, and grocery retailer accessibility. Some of the grocery retailers were built in the past 10 years, but many were built much longer ago. The characteristics of neighborhoods today and especially historically have shaped the accessibility of grocery retailers across metropolitan Seattle, WA. Establishing detailed longitudinal analyses, similar to Drewnowski et al. (Reference Drewnowski, Aggarwal, Hurvitz, Monsivais and Moudon2012), would help to clarify the dynamic relationships between race/ethnicity and the proportion of the population living in poverty, and supermarket accessibility, while gaining insights into the subcategories of the different races. Since 2010, five of the current chain grocery retailers in the City of Seattle have opened, and only three local supermarkets had closed temporarily due to renovation and expanding their business.

An additional consideration is the proliferation of fast-food restaurants in a neighborhood, which is not considered in this analysis. Fast-food restaurants are often marketed with “value menus” that offer inexpensive but high-calorie food items. Residents in neighborhoods with many fast-food restaurants, food swamps, may choose this option more often. In fact, Cooksey-Stowers, Schwartz, and Brownell (Reference Cooksey-Stowers, Schwartz and Brownell2017) find evidence that food swamps are a distinct and separate phenomenon to food deserts as they predict adult obesity rates better than food deserts in the United States.