2. Materials and Methods

An online survey was conducted between March 23, 2019 and May 5, 2019, targeting residents of the southeastern U.S., including Alabama, Florida, Georgia, Kentucky, Louisiana, Mississippi, North Carolina, South Carolina, and Tennessee. The survey was approved by the University of Georgia Institutional Review Board (ID#STUDY00004769). Toluna, Inc. was contracted with and recruited respondents from their database. A random group of respondents in the Toluna, Inc. database that were 18 years of age or older and resided in one of the targeted states were contacted by Toluna, Inc. via email to request their participation in the survey. Respondents agreeing to participate were directed to the survey. In recruiting respondents, Toluna, Inc. attempted to maintain a representative sample whereby the demographics of the sample were comparable to the demographics of the southeastern U.S. As with any survey mechanism, potential biases may exist. Notably, selection bias could challenge the robustness of the results. For instance, selection bias could be an issue if respondents were selected to participate based on their perceptions about hemp or respondent selection was higher in areas with more anti- or pro-hemp perceptions. In order to minimize the potential for selection bias in the sample, Toluna’s selection process of potential respondents from their database was random, except for state quotas and efforts to maintain a representative sample via age, household income, and race. To further mitigate selection bias, respondents agreed to participate in the survey prior to knowing the exact nature of the survey (i.e., that hemp questions would be asked), therefore, potential biases associated with respondents self-selecting into the survey only due to anti- or pro-perceptions about hemp should be minimized.

The survey asked a myriad of questions about hemp (shown in Appendix A), like “Would you have any concerns about living near a farm or production facility that grows/produces the following? Hemp production only, no processing; Hemp processing (e.g., making of productions from hemp).” Respondents marked their concern level on a 0 (no concern) to 100 (extremely concerned) point scale. Respondents indicating any concern for hemp production only were asked a follow-up question, “What concern would you have about living near a farm or production facility that grows hemp?” A list of seven choices was provided, whereby a respondent could mark any number of the seven choices. The list of choices included, public scrutiny, impact on the air, impact on water, impact on the environment, the potential for illegal activities, overall safety, and others. Similarly, a respondent that indicated any level of concern for hemp processing was shown the same list of choices and asked to indicate which concern they had with a processing facility. Definitions were not provided on the choices of concern, so how each respondent interpreted these were left to the individual. Choices were left general in nature so that a baseline can be formulated as to the overarching issues causing concern. Future research can focus on the specific areas to better understand the causes of concern in each general area (e.g., for air is its smell, potential ozone damage in production, etc.). Providing very specific concerns left the potential to miss important issues that can now be identified via future research guided by results from this paper. Production was also not defined, but processing was defined as “making of products from hemp.”

In addition to understanding concerns related to hemp production and processing, the authors also wanted to gauge the respondent’s awareness of the term hemp. Respondents were asked to classify what they think applies when they hear the term hemp. This included responses such as marijuana, CBD oil, fiber, food, and a variety of other products. Respondents were also allowed to choose they had never heard of hemp. Using these responses, a three-category hemp awareness variable was developed. Those that were not aware of hemp selected “never heard of” as their response. Respondents that thought hemp is the same as marijuana chose that hemp is either recreational marijuana or medical marijuana. Respondents who correctly identified hemp chose other options that included CBD oil and various products made from hemp. Only 44% of respondents were aware of hemp and indicated that it is not marijuana. An additional 44% of respondents thought hemp is marijuana, while 12% had not heard of the term hemp.

After answering the hemp-based questions, respondents were asked to provide demographics (e.g., age, household income, education level, race, etc.) and zip code of their primary residence. The zip codes were then merged with zip code characteristics from the American Community Survey (United States Census Bureau, 2019a) in order to put community-level demographics with each survey respondent. The zip code-level variables included the percentage of males, percentage of different races, education level, median household income, median age, and percentage of persons employed within agriculture with the specific zip code area. Population density and the change in population density between 2012 and 2017 within each zip code were also ascertained. Though similar in nature, using the combination of individual level (i.e., individual-level demographics) and geographic level (i.e., zip code-level data) allows for control of characteristics unique to the individual as well as for controlling of community characteristics. Rather than including state fixed effects, three categories of production levels were specified. The highest level of production occurs in Kentucky, Tennessee, and North Carolina, where over 10,000 acres were reported as planted in 2019. South Carolina and Alabama represent small-scale production with less than 10,000 planted acres. No production is represented by Florida, Georgia, Louisiana, and Mississippi. A total of 2,505 surveys were collected and after eliminating incomplete responses, notably lack of zip codes, 2,108 surveys were utilized in the analysis.

Overall, the sample was representative of the Southeast on several characteristics (Table 1). Survey respondents had a lower median household income ($37,500) compared to the census estimates for the Southeast ($53,065) (United States Census Bureau, 2019b). However, the sample’s median age was 42, which is slightly higher than the census estimates of 38 (United States Census Bureau, 2019c). Eliminating persons under 18 years of age from the census estimates would move the sample in-line with the Southeast region. With respect to race, the sample is made up of 69% Caucasian (non-Hispanic or Latino), 22% African American, and 3% Hispanic/Latino. These demographics are in-line with Census estimates for the Southeast region, 66% Caucasian (non-Hispanic or Latino), 25% African American, and 8% Hispanic/Latino. The overall zip code characteristics from respondents are summarized in Table 2. As with any survey, the results are only generalizable to populations outside the sample if the sample is representative to the population of interest. Though our sample appears to be representative across several parameters (e.g., age, race, etc.), there are other parameters that are less representative (i.e., household income).

Table 1. Descriptive statistics of survey respondents’ demographics

Table 2. Descriptive statistics of survey respondents zip code characteristics

The central focus of this paper was to understand the magnitude of concern associated with living near a hemp production or processing facility. We assessed concern using a 0–100 scale where 0 = no concern, 50 = somewhat concerned, 100 = extremely concerned, or respondents could mark anywhere in between. The respondent concern could be due to a plethora of perceived issues, both accurate and inaccurate. Using the 100-point scale, respondents could better indicate their concern level compared to a simple yes/no question. However, this presents a censoring of the data at the two extreme points (0 and 100). Utilizing ordinary least squares (OLS) in this case results in biased and inconsistent parameter estimates. Thus, the two-limit Tobit model developed by Rossett and Nelson (Reference Rossett and Nelson1975) was used. The model can be represented as:

(1) $$\eqalign{ y_i^* = \beta^\prime {x_i}\, + \,{\varepsilon _i}\left( {i\, = \,1,{\rm{ }} \ldots ,n} \right)}{ \hskip 65.5pty_i = \left\{ {\matrix{\, 0\;\;\;\;\; if\;y_i^{\rm *} \le 0 \hfill \cr \ y_i^{\rm *}\;\;\; if\;0 \lt y_i^{\rm *} \lt 100\;\;\;( i = \,1, \ldots ,n ) \cr 100\;\; if\;y_i^{\rm *} \ge 100\hfill }} \right.}$$

where $y_i^{\rm{*}}$ is a latent variable not observed for values below 0 and above 100 on the scale, x is a matrix of explanatory variables, β is a vector of coefficients, and ϵ is an independently and normally distributed error term with zero mean and variance σ ². Davidson and McKinnon (Reference Davidson and McKinnon1993, p. 541) note that the likelihood function in Equation (2) can be maximized to obtain coefficient estimates:

(2) $$\mathop \sum \limits_{y_t^L \le y_t^* \le y_t^U} {\rm{log}}\left\{\left{\frac{1}\over{\sigma }}{\emptyset \left[ {\frac{1}\over{\sigma }}\left( {{y_t} - {x_t}\beta } \right)} \right]}\right\}\right + \mathop \sum \limits_{y_t^* \lt y_t^L} {\rm{log}}\left\{ {\phi \left[ {\frac{1}\over{\sigma }}\left( {y_t^L - {x_t}\beta}\right) \right]} \right\} + \mathop \sum \limits_{y_t^* \gt y_t^U} {\rm{log}}\left\{ {\phi \left[ { -{ \frac{1}\over{\sigma }}}\left( {y_t^U - {x_t}\beta}\right) \right]}\right\}$$

whereby the first term corresponds to the non-limit observations, term two the lower limit $y_t^L\;$ observations, and term three the upper limit $y_t^U\;$ observations. However, the estimated β-coefficients are not interpretable as the marginal effect of a unit change in an independent variable (Gould, Saupe, and Klemme, Reference Gould, Saupe and Klemme1989). An extension of the McDonald and Moffitt decomposition for two-limit censoring to obtain the unconditional and conditional marginal effects and the corresponding probabilities of being uncensored (McDonald and Moffitt, Reference McDonald and Moffitt1980) was used.

With respect to the issues driving concern levels, we asked respondents to check the issues driving their concern from a predefined list (i.e., impact on the air, impact on water, impact on the environment, public scrutiny, the potential for illegal activity, overall safety, and other). Concerns across perceptions of hemp (i.e., not aware of the correct definition of hemp, hemp = marijuana, hemp is not marijuana) were visually compared to determine if the type of concern varied if a respondent understood that hemp is not marijuana. Next, histograms were used in order to better understand how the varying issues driving concern changed as concern level increased.