2.1. Consumer Sample

This paper makes use of the same CE data in Lusk (Reference Lusk2018) but augments the CE data with data on beliefs and data from a best-worst task. In 2017, a national survey of US chicken consumers was delivered online to a panel maintained by Survey Sampling Inc. To screen for chicken consumers, the initial question was “Do you eat chicken (e.g., breasts, thighs, wings, nuggets, tenders)?”. Three percent of respondents were removed from the analysis as they failed to answer “yes” to this question and were directed to the end of the survey. In total, 2,049 responses were collected. At the end of the survey, the respondents answered demographic questions. The sample demographic characteristics reflected the US Census population in general. The few exceptions are that the sample collected is a bit younger than average and has fewer respondents in the highest income category of $160,000/year or more than does the general population.

2.2. Choice Experiment

The study used a CE method to elicit consumer preferences for labels. CEs are commonly used in meat and general food demand analysis (e.g., Lusk, Roosen, and Fox, Reference Lusk, Roosen and Fox2003; Mennecke et al., Reference Mennecke, Townsend, Hayes and Lonergan2007). The CE used in this study varied the presence or absence of five labels: organic, no antibiotics ever (NAB), no hormones added, slow growth, and non-GMO. In addition, products had one of two popular chicken brands displayed prominently on the packages. Prices of choices varied from $1.99 to $5.99 in $0.50 increments as per price data from the US Bureau of Labor Statistics.

A D-optimal design was created consisting of 12 choice questions using the software Ngene. An image of one of the CE questions is Figure 1. To analyze the effect of information on choices, respondents were randomly assigned to one of three different information treatments. The first (a control) did not provide any additional information. Another treatment (pro-slow growth) was shown two excerpts from news articles from the New York Times (Strom, Reference Strom2017) and the National Public Radio (Charles, Reference Charles2016) which provided information favorable to slow growth chickens. The last (anti-slow growth) showed a graphic of information from the National Chicken Council that was critical of slow growth production practices (National Chicken Council, 2017). See Lusk (Reference Lusk2018) for more details.

Figure 1. Choice experiment.

After the CE was completed, the participants were asked a series of questions pertaining to their beliefs about the aforementioned labels. Respondents were asked “How healthy or unhealthy do you consider chicken sold with each of the labels shown below?”, and then they were shown each of the seven labels/brands, and for each they responded on a scale of 1 = very unhealthy to 5 = very healthy. Other questions were “How tasty or un-tasty do you consider chicken sold with each of the labels shown below?”, “How safe or risky in terms of food safety, do you consider chicken sold with each of the labels shown below?”, and “How high or low a level of chicken animal welfare is associated with each of the labels shown below?”. Each of the questions was answered according to a five-point Likert scale with one being the lowest and five as the highest. An image of the belief questions is seen in Figure 2.

Figure 2. Example belief question.

2.3. Direct Elicitation of Preferences

Respondents were presented with a single variant of a best-worst-type question related to “food values” (Lusk and Briggeman, Reference Lusk and Briggeman2009). In particular, respondents were asked, “How important are the following items to you when deciding whether to buy chicken?”. Thirteen items were shown and respondents had to pick four items and click and drag them into a box labeled “most important” and pick four other items and click and drag them into a box labeled “least important.” Each attribute was listed with a short definition, for example, “Taste, the flavor of food in your mouth.” An image of the food values question is in Figure 3. To be clear, this is not a full best-worst questioning approach as only a single question was asked, where respondents provided a crude ranking of 13 food values: most important, neither most nor least important, or least important.

Figure 3. Food values question.

2.4. Econometric Methods

Our primary objective in this study is to determine the effect of consumer’s beliefs about health, safety, taste, and animal welfare on chicken purchasing and estimated WTP for a label. We use a similar approach to Malone and Lusk (Reference Malone and Lusk2018) who examined how valuable taste is compared to health or safety; our approach differs in that our beliefs related to product labels, and each choice option may have one or more labels. As such we must aggregate beliefs over labels to infer an overall belief about the safety or health of a choice option.

Our analysis is based on the commonly used random utility model. The indirect utility V participant i derives from chicken breast option j in treatment t is

(1) $$\eqalign{V_{ijt} \, = \, \beta _{tji} + \alpha _{ti} \cdot Price_j + \mathop \sum \limits_{k = 1}^7 \vartheta _{ti}^k \cdot d_j^k + \tau _{1ti} \cdot {\overline {Health} _{ij}} + \tau _{2ti} \cdot {\overline {Taste} _{ij}} \cr \quad + \tau _{3ti} \cdot {\overline {Safety} _{ij}} + \tau _{4ti} \cdot {\overline {Welfare} _{ij}}}$$

In this function, ${\beta _{tj}}$ is an alternative-specific constant indicating the utility of chicken breast j in treatment t relative to the “no purchase” option; $Pric{e_j}$ is price of chicken breast package j; α_ti is the marginal disutility of price; $d_j^k$ represent dummy variables indicating whether option j has the k ^th label present (organic, no antibiotics, no added hormones, slow growth, non-GMO and the brands Tyson versus Perdue); $\vartheta _t^k$ represents a portion of the utility associated with each label; and, ${\overline {Health} _{ij}}$ , ${\overline {Taste} _{ij}}$ , ${\overline {Safety} _{ij}}$ , and ${\overline {Welfare} _{ij}}$ are individual i’s average belief of the health, taste, safety, and animal welfare of option j, which was obtained from the Likert scale belief questions in Figure 2. The average health belief, for example, of option j is

(2) $${\overline {Health} _{ij}} = {{\sum\limits_{k = 1}^7 {} d_j^k \cdot Health_i^k} \over {\sum\limits_{k = 1}^7 {} d_j^k}}$$

where the indicator variable for each label is multiplied by the corresponding health belief associated with the label, $Health_i^k$ indicating the individual i’s belief about the healthiness of label k.

The coefficients ${\tau}$ represent the marginal utilities from changes in perceived health, taste, safety, and animal welfare. Thus, the coefficients represent the consumers’ preferences for health, taste, safety, and animal welfare. Because preferences for and beliefs about, health, taste, safety, and welfare are controlled for in the utility function, $\vartheta _{ti}^k$ reflects the utility derived from label k that cannot be explained by health, taste, safety, and animal welfare. Adding an iid extreme value error term to the aforementioned utility function and assuming all respondents share the same preference parameters results in the multinomial logit (MNL) model, where the probability of choice is given by:

(3) $${\rm{Probability}}\left( {i\,{\rm{chooses}}\,j\,{\rm{in}}\,{\rm{treatment}}\,t} \right) = {{{e^{{V_{ijt}}}}} \over {\sum\limits_{k = 1}^k {{e^{{V_{ikt}}}}} }}.$$

To allow for additional heterogeneity in individual preferences, a random parameter logit (RPL) model was also estimated (Train, Reference Train2009). The RPL model was estimated using simulated maximum likelihood with 500 Halton draws assuming all non-price coefficients are normally distributed. The price coefficient was assumed to be a constant term.

WTP for individual i for the presence of label k (versus no label) is

(4) $$WT{P^k}_i = {{{\vartheta _k} + {\tau _1}\cdot Healt{h_{ik}} + {\tau _2}\cdot Tast{e_{ik}} + {\tau _3}\cdot Safet{y_{ik}} + {\tau _4}\cdot Welfar{e_{ik}}} \over { - {\alpha _t}}}$$

In addition, we obtained so-called individual-specific estimates of each person’s preferences using the estimated parameter distribution as the prior and update these with the individual’s choices (see Train, Reference Train2009). These are parameter means conditional on each individual’s 12 choices, which converge to individual’s preferences as the number of choice questions grows (Sarrias, Reference Sarrias2020). Because the $\alpha $ parameter is a constant term, WTP is normally distributed. The WTP estimates are calculated through a Krinsky and Robb simulation (Krinsky and Robb, Reference Krinsky and Robb1986).

Another key objective of this study is to explore how preferences for, for example, health, from the CE, ${\tau _{i1}},\;$ compare with an alternative measure of preferences of health from our food values ranking. Are people who tend to demonstrate high preferences for safety in the CE also the same ones who tend to indicate safety as one of the most important food values? To explore this matter of convergent validity, we calculate the correlations between the individual-specific preferences for safety, taste, health, and animal welfare and the corresponding responses to the best-worst “food values” question. The food value questions were coded as follows: 1 if the respondent placed the value in the “most important” category, −1 if the value was placed in the “least important” category, and 0 if it was in neither category. In addition to the correlations, we compared the mean $\;\tau $ ’s for people who rated each food value as “most important,” “least important,” or “neither” using an ANOVA test. The mean coefficient values were calculated for each belief value and separated based on their placement in the “food values” category. The ANOVA tested for any significant differences between the belief means by food value placement. This was repeated for each treatment.