2.1. Conceptual framework

The belief-preference conceptual framework we use was first developed by Costanigro and Onozaka (Reference Costanigro and Onozaka2020). Briefly, the framework follows the Lancaster (Reference Lancaster1966) approach and defines quality as a good’s effectiveness in its proposed purpose, and that the utility a consumer derives from a good is from the intrinsic quality of the good, not just the good itself. The quality of a food good is inherently multifaceted, as consumers enjoy a complex combination of qualities such as taste, smell, and nutrition. We can assume that the perceived quality of good j is the summation of a Q-dimensional vector of quality dimensions Q_j= (Q_j ¹,Q_j ²,…Q_j ^Q). If individual i consumes good j, they will realize utility, U_ij = (Q_j,Price_j,γ_i), where Q_j is the perceived quality of the good, γ_i is a vector of consumer specific preference weights, and Price_jis the price paid for good j (Costanigro and Onozaka, Reference Costanigro and Onozaka2020).

To evaluate the quality of a good, the framework assumes that consumers use intrinsic and extrinsic attributes of a good to generate perceived quality (Brunswik, Reference Brunswik1955; Dudycha and Naylor, Reference Dudycha and Naylor1966; Steenkamp, Reference Steenkamp1990). The extent to which a good’s attributes influence quality depends on a consumer’s subjective beliefs about the attribute itself. In other words, beliefs serve to map attributes into perceived quality.

To capture these belief and preference parameters from choice data, the food choice process is separated into two steps. The first step (deemed the quality sorting task) involves asking consumers which good is superior in a given quality dimension conditional on the good’s attributes. In the second step (deemed the product choice task), price information is added to the attributes and consumers are asked to indicate which, if any, good they would purchase. Consider a scenario where consumer i must choose which of good A or good B is superior in terms of quality dimension q. Consumer i’s perceived quality, Q, in dimension q, for alternative j in choice set t, becomes:

(1) $${\rm Q}{{\rm _{ijt}}}^{{\rm q}}={\rm Q}({\bf X}_{{\bf ijt}};{\bf {\unicode{x03B2}}} {{\rm_ i}}^{{\rm q}})+\rm\varepsilon _{{\rm_ {ijt}}}^{{\rm q}}={\bf X}{{\bf _{ijt}}}{\bf \prime}{\bf {\unicode{x03B2}}} {{\rm_ i}}^{{\rm q}}+{{\rm _{ijt}}}^{{\rm q}}$$

Where X_ijt is a vector of good attributes, ${{\boldsymbol \beta} _{\rm i}^{\rm q}}$ is a vector of consumer-specific belief coefficients, and ${ \epsilon _{ ijt}^{q}}$ is the error term. The above equation is framed as quality because the question presented to respondents is to indicate which alternative they believe is superior in terms of the q quality dimension, not which alternative they would purchase. The probability that good A is perceived to be superior to good B in quality dimension q can be written as ${\rm Pr\; ({\rm Q_{iA}^{q}}\gt {\rm Q_{iB}^{q}})=Pr(({\bf X_{iA} - {\bf X _{iB}}})\prime {\bf \beta}_{\rm i}^{\rm q}\gt {\rm \epsilon}_{\rm iB}^{\rm q} - {\rm \epsilon}_{\rm iA}^{\rm q})}$ . Once subjective quality perceptions have been formed, the model for how consumers make choices about food purchases becomes:

(2) $${\rm U}_{{\rm ijt}}={\rm U}({\bf Q}_{{\bf ijt}};{\rm Price};{\bf \gamma} )+{\rm v}_{{\rm ijt}}={\bf Q}_{{\bf ijt}}{\bf \prime}{\bf \gamma} +{\rm Price}_{{\rm j}}\gamma _{{\rm price}}+{\rm v}_{{\rm ijt}}$$

Where U_ijt is the utility consumer i receives from alternative j in choice set t, γ is a Qx1 vector of coefficients that capture the marginal utility of each quality, γ_price captures the marginal disutility of price, and v_ijt is the error term. The probability that good A is purchased rather than good B is given by: Pr (U_iA>U_iB) = Pr ((Q_iA−Q_iB )′γ +(Price_A−Price_B)′γ_price>v_iB−v_iA). As researchers, we do not directly observe Q_ijt. Hence, we can use estimates obtained from the belief model to predict perceived quality: ${\rm U}_{{\rm ijt}}={\rm U}(\widehat{{\bf Q}}_{{\bf ijt}};{\rm Price};{\bf\gamma} )+{\rm v}_{{\rm ijt}}=\widehat{{\bf Q}}_{{\bf ijt}}^{{\rm \prime}}{\bf\gamma} _{1}+{\rm Price}_{{\rm j}}\gamma _{{\rm price}}.$ Furthermore, we can allow for belief heterogeneity by estimating the above belief model using a random parameters (mixed) logit model.

As demonstrated by Costanigro and Onozaka (Reference Costanigro and Onozaka2020), the above specified belief-preference model allows for a decomposition of willingness-to-pay for an attribute via the Q-dimensional pathways of perceived quality. In the traditional utility model, an attribute’s marginal utility can be calculated as ${\partial U_{ij} \over \partial x_{k}}=\delta _{k}$ and the corresponding willingness-to-pay for the k^th attribute is WTP _k = δ _k / − δ _price . In the belief-preference model, we can define the utility garnered from attribute x_k as: ${\partial {\rm U}_{{\rm ijt}} \over \partial {\rm x}_{{\rm k}}}=\sum _{{\rm q}}{\partial {\rm U}_{{\rm ijt}} \over \partial {\rm Q}_{{\rm j}}^{{\rm q}}}\cdot {\partial {\rm Q}_{{\rm ijt}} \over \partial {\rm x}_{{\rm k}}}=\sum _{{\rm q}}{\rm {\rm \gamma}} _{{\rm q}}{\rm \beta} _{{\rm k}}^{{\rm q}}$ , and the part-worth decomposition of the WTP for attribute x_k becomes:

(3) $${\rm WTP}_{{\rm k}}={{\rm \gamma} _{1}{\rm \beta} _{{\rm k}}^{1} \over -{\rm \gamma} _{{\rm price}}}+{{\rm \gamma} _{2}{\rm \beta} _{{\rm k}}^{2} \over -{\rm \gamma} _{{\rm price}}}+\ldots +{{\rm \gamma} _{{\rm q}}{\rm \beta} _{{\rm k}}^{{\rm q}} \over -{\rm \gamma} _{{\rm price}}}$$

There is a summation across multiple belief and preference coefficients because one attribute can influence more than one perceived quality dimension.

2.2. Data and experimental design

An online Qualtrics survey was administered via Toluna Panels the first week of May 2023. Toluna Panels is a market research company that provides a platform for consumers to participate in surveys and other human subjects research. The survey was sent to a panel of U.S. consumers that was designed to be nationally representative according to age, ethnicity, income, and gender (Blakeslee et al., Reference Blakeslee, Caplan, Meyer, Rabe and Roberts2023). Prior to administering the survey, the research protocol was approved by the Institutional Review Board (IRB2023-348). To qualify for the survey, respondents had to be above the age of 18, red meat consumers, and the primary person in their household responsible for purchasing and preparing food. A total of 1,823 responses were collected. To ensure quality responses, participant data was dropped if: 1) attention check questions were answered incorrectly, or 2) the duration of the survey was less than 5 minutes. The descriptive statistics of the 733 participants retained for the analysis are provided in Table 1. The final column of the table lists demographic data collected from the U.S. Census Bureau. The composition of our sample pairs favorably with these estimates. Small deviations exist in terms of our sample containing a higher proportion of African American respondents and female respondents.

Table 1. Sample descriptive statistics

Notes: U.S. Age and Gender information from (US Census Bureau, n.d.) Income from (Guzman and Kollar, Reference Guzman and Kollar2023).

The questionnaire portion of the survey included demographic questions, questions about perceptions of the importance of environmental, animal welfare, and food safety concerns, and how conventional and organic beef cattle production impact these concerns. Interestingly, while most respondents indicated that the way beef cattle are raised significantly impacts the safety of beef products and the health of the environment, most were unsure if their food choices influence the way in which food animals are raised. The experimental portion of the survey included two discrete choice experiments intended to illicit respondents’ beliefs and preferences.

Given the importance of beef to the diet of U.S. consumers, ground beef was selected as the good of interest for the choice experiments. According to the Beef Research Center, over two-thirds of U.S. consumers eat beef on at least a weekly basis and 2021 per capita net beef consumption was 58.0 pounds (Beef Research, 2022). Beef production is also inherently tied to the health of the environment, humans, and cattle themselves through One Health challenges such as greenhouse gas emissions, antimicrobial resistance, and animal health and welfare. Correspondingly, we anticipated consumers to possess strong beliefs regarding the impact of beef cattle production on these holistic health challenges.

Following the approach of Costanigro and Onozaka (Reference Costanigro and Onozaka2020), the core of the survey included two discrete choice experiments. The first experiment, the quality sorting task, asked respondents to determine which ground beef option (if any) was superior (A, B, or “there is no difference”) in a specific quality dimension. The three quality dimensions (Q = 3) considered were environmental friendliness, animal welfare, and food safety. These quality dimensions were chosen based on previous literature exploring non-economic factors that are important to consumers when selecting to purchase organic or non-organic products (Danner and Menapace, Reference Danner and Menapace2020; Yiridoe et al., Reference Yiridoe, Bonti-Ankomah and Martin2005). The two attributes included were organic status and percent lean. The organic status included two levels (yes or no) and was the attribute of interest for this study. Percent lean included three levels (70 – 79%, 80 – 89%, >90%) and has been shown to be an important factor in consumer preferences for ground beef (Lusk and Parker, Reference Lusk and Parker2009). An example of the quality sorting task is presented in Figure 1.

Figure 1. Example choice set in discrete choice experiment 1 (Quality sorting task).

Notes: In the quality sorting task, respondents were asked to indicate which ground beef option they thought was superior in three quality dimensions: environmental friendliness, animal welfare, and food safety.

In the second experiment (product choice task), price information was added to the attributes described above and respondents were asked to indicate which option, if any, they would purchase. Price levels were based on the USDA Agricultural Marketing Service’s weekly advertised retail prices for ground beef from January – November 2022 for 70 – 79%, 80 – 89%, and 90% + lean ground beef (USDA-AMS 2023). From this data, a national weighted average retail price of $4.50. Variations in price were established by allowing for up to 33% deviation from the mean at $0.50 increments. For the experiment, therefore, the price per pound of ground beef varied from $3 to $6 in 50 cent increments. An example of the product choice task is presented in Figure 2.

Figure 2. Example choice set in discrete choice experiment 2 (Product choice task).

For both choice experiments, an orthogonal, efficient fractional factorial design was used to generate choice sets. For the quality sorting choice experiment, the design resulted in 16 alternatives randomly assigned into eight choice sets. The eight choice sets were then randomly allocated into two blocks, resulting in respondents receiving four choice scenarios for each of the three quality dimensions. For the second choice experiment, the design resulted in 52 alternatives, which would have required 26 choice sets. To ensure an even number of blocks and reasonable number of choices per participant, an optimal design was generated under the constraint of 50 alternatives in 25 randomly assigned choice sets. Those 25 choice sets were randomly allocated to five blocks, with each respondent receiving five choice scenarios for the product choice experiment.

In order to assess the malleability of beliefs, the following five information treatments were introduced: Organic Positive, Organic Negative, Neutral, Conventional Positive, and Conventional Negative. Respondents were randomly assigned to one of five information treatments, where they received written information that presented organic or conventional beef production in either a positive or negative light within each of the three quality dimensions (environmental friendliness, animal welfare, and food safety). Information was selected from news outlets that consumers would be likely to see and used language that would be understandable to the average consumer. The information treatments are provided in the Appendix (Rocha, Reference Rocha2023; TCFA n.d.; Mayo Clinic, 2023; Animal Welfare Institute n.d.). The Neutral information treatment was included to serve as a reference for potential movement of beliefs due to respondent attrition, and only presented general information about beef cattle with no reference to either organic or conventional production. Differences in the composition of respondents in each information treatment was assessed using the Kruskal–Wallis One-Way ANOVA. No statistically significant differences were found in terms of age (χ ² = 2.06, P = 0.73), gender (χ ² = 0.62, P = 0.96), income (χ ² = 0.39, P = 0.98), or race (χ ² = 0.78, P = 0.94). The composition and number of respondents in each information treatment group is provided in the Appendix. Briefly, the organic positive, organic negative, neutral, conventional positive, and conventional negative information groups contained 144, 150, 140, 150, and 149 respondents, respectively.

Sequentially, respondents first completed the belief choice experiment. Second, respondents were randomly allocated to one of the information treatments. Third, respondents were asked to complete the belief choice experiment again, but this time they received the alternative belief choice block. For example, respondent i was assigned to Block 1 Belief choice set, then received organic positive information, then was asked to complete Block 2 Belief choice set. Lastly, respondents completed the preference choice sets. Figure 3 presents a flow chart of the survey.

Figure 3. Flow chart of survey for one respondent.

2.3. Belief models

The respondent belief coefficients were obtained from the first choice experiment (quality sorting task). According to the conceptual model, this choice experiment provided respondent i’s perceived quality in quality dimension q of alternative j in choice set t ( ${\rm Q _{ijt}^{\rm q}}$ ). Respondents were asked to indicate which alternative they believe is superior in terms of a specific quality dimension. An “opt out” option that indicated “there is no difference in quality” was also included. For each quality dimension (environmental friendliness, animal welfare, food safety), respondent i’s perceived quality was a function of the good attributes, X_ijt, and an alternative specific constant, ASC_ijt. The coefficients ${\boldsymbol \beta _{ki}^{\rm q}}$ , are respondent-specific beliefs that map the attributes of an alternative into perceived quality. To assess whether the belief coefficient for the organic status changed after receiving the information treatment, the pre and post belief choice experiments were grouped to estimate the model. We interacted the organic status with a dummy variable that indicates if the choice set was presented before or after the information treatment (P_t = 1if choice set was presented after information treatment, 0 if otherwise). The belief model becomes:

(4) $$ {\rm Q}_{{\rm ijt}}^{{\rm q}}=({\bf X}_{{\bf ijt}}^{{\bf \prime}}{\bf \beta} _{{\bf i}}^{{\bf q}})+{\bf e}_{{\rm ij}}^{{\rm q}}={\rm \beta} _{1{\rm i}}^{{\rm q}}{\rm Org}_{{\rm ijt}}+{\rm \beta} _{2{\rm i}}^{{\rm q}}{\rm PL}80_{{\rm ijt}}+{\rm \beta} _{3{\rm i}}^{{\rm q}}{\rm PL}90_{{\rm ijt}}+{\rm \beta} _{4{\rm i}}^{{\rm q}}{\rm ASC}_{{\rm ijt}}+{\rm \delta} _{{\rm i}}^{{\rm q}}{\rm Org}_{{\rm ijt}}\times {\rm P}_{{\rm t}}+{\rm e}_{{\rm ij}}^{{\rm q}} $$

The equation has quality as the dependent variable, not utility, because respondents were asked to indicate which ground beef option is superior in quality dimension q, not which ground beef option they would buy. Hence, the alternative’s attributes and the respondent’s beliefs about how attributes inform quality will dictate which option they think is superior in terms of quality. In order to allow for heterogeneity of beliefs, the model was estimated using a mixed logit model simulated from 500 Halton draws and applied to each of the three quality dimensions. The results from the environmental friendliness belief model is presented in Table 2, and results from the animal welfare and food safety belief models are presented in Table 3 and 4, respectively. The coefficient, ${\rm \beta _{1i}^{\rm q}}$ , represents the mean of the belief distribution of how the Organic status influences perceived quality within quality dimension q prior to receiving information. The coefficient, ${\rm \delta _{i}^{\rm q}}$ , represents the average change in beliefs about the Organic status after receiving the information treatment. The sum of the two coefficients, ${\rm \beta _{\rm 1i}^{q}}+ {\rm \delta _{i}^{\rm q}}$ represent the mean of the updated beliefs after receiving the information treatment within each quality dimension.

Table 2. Belief mixed logit regression results: environmental friendliness

Notes: Mixed logit using 500 Halton draws. ASC = alternative specific constant. *** indicates significance at the 1% level, ** indicates significance at the 5% level, * indicates significance at the 10% level. Values in parentheses indicate the standard errors.

Table 3. Belief mixed logit regression results: animal welfare

Notes: Mixed logit using 500 Halton draws. ASC = alternative specific constant. *** indicates significance at the 1% level, ** indicates significance at the 5% level, * indicates significance at the 10% level. Values in parentheses indicate the standard errors.

Table 4. Belief mixed logit regression results: food safety

Notes: Mixed logit using 500 Halton draws. ASC = alternative specific constant. *** indicates significance at the 1% level, ** indicates significance at the 5% level, * indicates significance at the 10% level. Values in parentheses indicate the standard errors.

2.4. Preference models

As indicated in the conceptual model, Q_ijt is not directly observable. Hence, we used the respondent-specific organic belief coefficients obtained from the mixed logit belief models to predict an individual’s perceived quality of the alternatives in the preference choice experiment (quality sorting task) $(\widehat{{\rm Q}}_{{\rm ijt}}^{{\rm q}}={\rm X}_{{\rm ijt}}{\rm ^\prime}{\rm \beta} _{{\rm ij}}^{{\rm q}}$ ). Respondent-specific organic belief coefficients were obtained from the mixed logit regression outputs from the three belief models (environmental friendliness, animal welfare, and food safety). These coefficients were then multiplied by the presence or absence of the organic status of alternatives in the preference choice experiment. The predicted quality scores were then used as regressors in the preference model. To assess if the marginal utility of the perceived quality changed after receiving information, the perceived quality score was constructed using the organic coefficients both before and after receiving the information treatment. While constructing perceived quality scores for each quality dimension, it became clear that the organic status uniformly influenced perceived quality across all dimensions. Hence, including an explanatory variable for each perceived quality dimension would have resulted in multicollinearity. To overcome this problem, we used the approach of Costanigro and Onozaka (Reference Costanigro and Onozaka2020), and constructed a composite quality score, which was simply the average of the three quality dimension scores.

To assess whether the marginal utility of the composite quality score changed depending on if it was constructed using baseline belief coefficients or post information belief coefficients, we interacted the composite quality score with a dummy variable that indicated if the score was constructed using baseline or post information beliefs (P _t = 1if constructed using post-information beliefs, 0 if otherwise). The preference model can be defined as:

(5) $$ {\rm U}_{{\rm ijt}}={\rm U}({\bf Q}_{{\bf ijt}};{\rm Price};{\rm \gamma} )+{\rm v}_{{\rm ijt}}\\={\rm \gamma} _{{\rm Q}}\widehat{{\rm Qual}}_{{\rm ijt}}+{\rm \gamma} _{2}{\rm PL}80_{{\rm ijt}}+{\rm \gamma} _{3}{\rm PL}90_{{\rm ijt}}+{\rm \gamma} _{{\rm Price}}{\rm Price}_{{\rm ijt}}+{\rm \gamma} _{4}{\rm ASC}_{{\rm ijt}}+{\rm \delta} _{{\rm Q}}\widehat{{\rm Qual}}_{{\rm ijt}}\times {\rm P}_{{\rm t}}+{\rm v}_{{\rm ijt}} $$

With γ_k being interpreted as the marginal utility of attribute k. The above preference model was estimated using a multinomial logit model. The results are presented in Table 5.

Table 5. Multinomial logit preference regression results

Notes: ASC = alternative specific constant. *** indicates significance at the 1% level, ** indicates significance at the 5% level, * indicates significance at the 10% level. Values in parentheses indicate the standard errors. Composite Quality = (Environment + Animal Welfare + Food Safety)/3.

2.5. Decomposition of willingness-to-pay

Perhaps the most useful quality of the Costanigro and Onozaka (Reference Costanigro and Onozaka2020) belief-preference model is that it allows for a part-worth decomposition of willingness-to-pay for an attribute via the Q-dimensional pathways of perceived qualities. This approach allows for a tangible assessment of how each quality dimension (credence attribute) contributes to the overall willingness-to-pay for a credence attribute-indicating label. In our case, it also provides a mechanism to measure how willingness-to-pay changes given the altering of beliefs and preferences.

We perform a decomposition of baseline willingness-to-pay for the organic status using the means of the distributions of organic belief coefficients obtained from the belief models prior to implementing the information treatment. In this context, total willingness-to-pay for the organic status prior to receiving information can be defined as:

(6) $${\rm WTP}_{{\rm organic}\_ {\rm baseline}}={\{[1/3({\rm \beta} _{{\rm org}}^{{\rm env}}+{\rm \beta} _{{\rm org}}^{{\rm anwf}}+{\rm \beta} _{{\rm org}}^{{\rm fdsf}})]\times {\rm \gamma} _{{\rm Q}}\} \over -({\rm \gamma} _{{\rm Price}})}$$

The premiums that the organic status generates due to a specific quality dimension, q, is $\text{1}/{3} \Big[ \big( \beta_{\text{org}}^{q} \times {\gamma_{Qual}} \big)/- (\gamma_{\text{price}}) \Big]$ . The above equation is analogous to equation (3), where the belief coefficients for the organic status, β_org ^q, are obtained from each belief model for a given information treatment. They are then multiplied by the preference parameter for quality, γ_Q, and divided by the parameter for price, − (γ_Price, both of which come from the single preference model for the information treatment. Again, our hypothesis is that after receiving the information treatment, beliefs were modified, leading to a shift in willingness-to-pay. The updated willingness-to-pay for the organic status can be estimated using the same model above, but now including the interaction terms which captures the shift in beliefs, ${\rm \delta _{org}^{\rm q}}$ , and preference, δ_Q, values:

(7) $$ {\rm WTP}_{{\rm organic}\_ {\rm updated}}={\left\{\left[1/3\left(\left\{{\rm \beta} _{{\rm org}}^{{\rm env}}+{\rm \delta} _{{\rm org}}^{{\rm env}}\right\}+\left\{{\rm \beta} _{{\rm org}}^{{\rm anwf}}+{\rm \delta} _{{\rm org}}^{{\rm anwf}}\right\}+ \left\{{\rm \beta} _{{\rm org}}^{{\rm fdsf}}+{\rm \delta} _{{\rm org}}^{{\rm fdsf}} \right\}\right)\right]\times \left({\rm \gamma} _{{\rm Q}}+{\rm \delta} _{{\rm Q}}\right) \right\} \over -\left({\rm \gamma} _{{\rm Price}}\right)} $$

Where − (γ_Price) is obtained from the single preference model for the given information treatment.