2.1. Study Area

This study was conducted in the CWD-impacted region of Tennessee, USA. The study area included two categories of counties: counties with a confirmed case of CWD (i.e., positive counties) and neighboring counties located 10 miles away from the location of confirmed CWD cases (i.e., high-risk counties). The CWD-positive counties included Fayette, Hardeman, and Madison. The neighboring high-risk counties were Chester, Haywood, McNairy, Shelby, and Tipton. However, CWD was identified in deer herds of other counties after the data collection for the study was implemented in 2019 (Figure 1). CWD is also presented in adjoining states in the region including Arkansas, Mississippi, Missouri, and Virginia.

Figure 1. Chronic wasting disease (CWD) positive (counties with confirmed cases) and high-risk counties (neighboring counties located 10 miles away from location of confirmed cases) of Tennessee in the Map of USA as of January 2021.

Since the first detection of CWD in 2018, the TWRA has implemented several programs to prevent its spread. Some of those initiatives include the change from general surveillance to intensive monitoring efforts to determine the spatial distribution and prevalence of CWD, collecting testing samples from hunters and local game processors, making CWD testing free for deer hunted in CWD counties, launching a public information campaign to educate the hunters, changing hunting seasons and bag limit to incentivize harvest, placing restriction on carcass movement or transportation, and enforcing a feeding/mineral ban (TWRA, 2021). In CWD-positive and high-risk counties, TWRA provided additional deer harvest opportunities to hunters through the Fight CWD Incentive Program, replacement buck, and earn-a-buck programs (Adhikari et al., Reference Adhikari, Poudyal, Muller and Yoest2022). On top of the bag limits, hunters would receive a replacement buck if they harvested a CWD-positive antlered deer, or they could earn an additional antlered deer for every antlerless deer harvested and submitted for CWD testing. Similarly, the Fight CWD Incentive Program provides a $75 voucher to hunters who harvest a CWD-positive deer redeemable for processing fees on their next harvest at participating processors. This program also incentivizes hunters with an annual sportsman license for next season if a hunter kills two or more CWD-positive deer during the season.

2.2. Survey Design

The survey instrument was developed based on inputs from TWRA officials, human dimension experts, and a few active deer hunters. Especially, their input helped make the survey questions simple, practical, and easy to understand by respondents. The survey instrument included questions related to hunting experience, awareness about CWD, and socioeconomic characteristics.

A mixed-mode survey of Tennessee hunters was conducted in August and September 2019, following a modified tailored design method (Dillman, Smyth, and Christian, Reference Dillman, Smyth and Christian2014). Survey participants were contacted several times using email and or mail (mixed mode). First, hunters who had email addresses were sent a personalized email message with a Qualtrics survey link. If hunters did not respond, they then received up to three reminder emails. The survey was mailed to hunters who did not have email addresses or who did not respond to the email survey. The mail survey included two contact attempts made a week apart: a personalized cover letter with the survey questionnaire and then a follow-up letter with the survey questionnaire. For this study, survey participants were selected from license holders who reside in CWD counties (positive and high-risk counties) or reported having harvested at least one deer in these CWD counties during the 2018–2019 season. In total, 16,741 hunters met this selection criterion in the TWRA license database. A total of 5,000 hunters were selected from the TWRA license database, and a stratified random sampling method was used to ensure representation from both CWD-positive and high-risk counties. Thus, there were two sampling strata, i.e., CWD-positive and high-risk counties, which were mutually exclusive.

It should be noted that disease testing services possess the characteristics of market goods (rather than nonmarket goods), and the design of value elicitation questions slightly differed from those typically used in nonmarket valuation studies. Furthermore, to account for the current context of testing arrangement in the study area, hunter WTP for the CWD testing fee was obtained using the two-stage question format as below:

The laboratory fee for testing a deer for CWD costs the TWRA $18 and the agency currently pays this fee for all deer submitted for sampling within the CWD-impacted counties. If TWRA is unable to cover this cost due to lack of funding in the future, are you willing to pay this amount if TWRA continues coordinating the submission of samples for testing for hunters?

• Yes, go to Section C

• No, continue below

If you said “No” above, are you willing to share a part of this cost with TWRA or other institutions to have your deer tested?

• Yes, I am willing to share $_______per deer

• No

This question format was based on a real-world example, and it was not a hypothetical question. This question was for an understanding of whether a hunter was interested to change in the existing flow of private goods, i.e., disease testing or not (Carson and Groves, Reference Carson and Groves2007). The above two-stage question format was less susceptible to some of the biases of traditional double-bounded question format, for example, starting point bias and serial dependence, because all respondents received a fixed bid level in first stage question and they would not need to answer second stage question if he or she selected “yes” in the first stage (Kim, Petrolia, and Interis, Reference Kim, Petrolia and Interis2012). Moreover, most hunters were familiar with the CWD testing fee, which was currently paid by TWRA, and the benefits of CWD testing. Although the WTP questions were presented as an advisory referendum, the consent form of the survey incorporated the following statement to increase hunter belief in consequentiality (Parthum and Ando, Reference Parthum and Ando2020; Vossler and Holladay, Reference Vossler and Holladay2018): “You are one of the few randomly selected deer hunters in the region to participate in this survey. Your response will help TWRA, and other stakeholders understand hunters’ perception of CWD risk and inform their management decisions.” To reveal the accuracy of WTP estimates, several ex-post analysis related to data problems and survey errors was conducted such as nonresponse bias, response mode bias, and multicollinearity test.

2.3. Econometric Modeling

Empirical modeling used survey responses to particular questions regarding testing fees. Hunters reported $18 or less as their WTP for a testing fee, and their WTP was assigned zero if they declined to answer the second stage question. Therefore, hunter WTP for the CWD testing fee was observed between $0 and $18. As ordinary least squares would result in asymptotic bias of the model coefficients because WTP values were not continuous but bounded or censored by 0 (lower) and 18 (upper), a maximum likelihood procedure was followed (Stewart, Reference Stewart1983). Thus, the two-limit Tobit model was deemed suitable for estimating the hunter WTP function because of double limits. The general form of the two-limit Tobit model can be presented as follows:

(1) $${WTP}_{i}^{*}={{ X}_{{ i}}^{{ '}}{ \beta }}+\varepsilon$$

where WTP _i * is the unobserved latent variable; X _i is a vector of independent variables represented by hunting and processing characteristics, psychosocial factors, including perceived risk of CWD, trust, and confidence in wildlife agency, and socioeconomic characteristics; β is a vector of parameters; and ϵ is error terms, which is distributed normally N (0, σ² I). If the observed dependent variable (WTP) is denoted by WTP _i , the model for observation i is defined as below:

(2) $$WT{P_i} = \left\{ {\matrix{ {{L_i}\,if\,WTP_i^* \le {L_i}} \cr {WTP_i^*\,if\,{L_i} \lt WTP_i^* \lt {R_i}} \cr {{R_i}\,if\,WTP_i^* \ge {R_i}} \cr } } \right.$$

In equation (2), L _i and R _i denote censoring thresholds for the lower and upper tails, which were 0 and 18 in this study.

With the model censored on both lower and upper limits, it can be estimated by maximizing the following log-likelihood function (Bradt, Reference Bradt2019):

(3) $$\begin{gathered}\ln L\left( {\beta ,\sigma \left| {WT{P_i},{X_i},{L_i},{R_i}} \right.} \right) = \sum\limits_{i \in \left\{ {WT{P_i} = {L_i}} \right\}} {ln} \left[ {\Phi \left( {\frac{{{L_i} - X_i^{^\prime }\beta }}{\sigma }} \right)} \right] \\ \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,+ \sum\limits_{i \in \left\{ {{L_i} < {\text{ }}WT{P_i} < {R_i}} \right\}} {ln} \left[ {\frac{1}{\sigma }\phi \left( {\frac{{WT{P_i} - X_i^{^\prime }\beta }}{\sigma }} \right)} \right] \\ \,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,\,+ \sum\limits_{i \in \left\{ {WT{P_i} = {R_i}} \right\}} {ln} \left[ {\Phi \left( { - \frac{{{R_i} - X_i^{^\prime }\beta }}{\sigma }} \right)} \right] \\\end{gathered}$$

where σ is the error variance, Φ(·) is the standard normal cumulative density function, and ϕ(·) is the standard normal probability density function.

Above, all the equations including the log-likelihood function are relevant for a two-limit censored model. When the dependent variable is censored only by a lower or upper limit, these equations are still relevant because when the probability of observation for any censored observation becomes zero, the equation becomes relevant for the lower or upper limit Tobit model. The mean of true WTP distribution was computed by using equation (1) and regression coefficients were directly used as marginal effects. The two-limit Tobit model was estimated using the command tobit in STATA/SE 16.1 (StataCorp, 2019).

2.4. Description of Variables

Four categories of independent variables were used to model hunter’s WTP for the CWD testing fee. Those included hunting and processing characteristics, perceived risk of CWD, trust, and confidence in wildlife agencies, and socioeconomic characteristics (Table 1). The selection of variables in the model was guided by recent literature on WTP and psychosocial constructs such as risk perception and trust (Lim et al., Reference Lim, Hu, Maynard and Goddard2014; Oh and Hong, Reference Oh and Hong2012; Wang et al., Reference Wang, Jin, He, Gong and Tian2018; C. E. Watkins and Poudyal, Reference Watkins and Poudyal2021). Explanatory variables related to hunting and processing characteristics included years of hunting (EXPERIENCE), ownership of hunting property in CWD counties (LEASE), hunting in CWD-positive counties (POSITIVE), days spent hunting in CWD counties (DURATION), and use of processing services (PROCESSING). These independent variables were selected to control the effects of hunting characteristics on the hunter’s WTP for CWD testing.

Table 1. Description of variables used in the two-limit Tobit model to estimate hunter’s willingness to pay (WTP) a laboratory fee for chronic wasting disease (CWD) testing in Tennessee in 2019

^a These variables were originally measured on a 5-point Likert scale: 1 = very disagree, 2 = slightly disagree, 3 = neutral, 4 = slightly agree, and 5 = very agree. It was recoded into binary variable where “slightly agree,” and “very agree” were coded as 1 (agree), and “very disagree,” “slightly disagree,” and “neutral” coded as 0 (otherwise).

Perceived risks affect hunter WTP depending on whether wildlife management actions increase or decrease the risk levels (Ufer et al., Reference Ufer, Christensen, Ortega, Pinizzotto and Schuler2022; Watkins and Poudyal, Reference Watkins and Poudyal2021). Meeks et al. (Reference Meeks, Poudyal, Muller and Yoest2022) found that hunter acceptability of CWD management actions was influenced by specific concerns associated with CWD. Assuming CWD risks can affect hunter WTP for disease surveillance, hunter risk perception was measured by hunter concern about CWD spreading throughout Tennessee (SPREAD), the safety of eating deer meat (MEAT), deer population decline (POPULATION), and not having enough mature bucks to hunt (BUCKS).

When citizens’ trust in the government increases, their WTP for government efforts increases because the trust indicates the government’s past behavior and reputation (Oh and Hong, Reference Oh and Hong2012). In the case of CWD management, Schroeder et al. (Reference Schroeder, Landon, Cornicelli, Fulton and McInenly2021) found that the perceived effectiveness of management actions was influenced by trust in the wildlife agency. Similarly, Watkins and Poudyal (Reference Watkins and Poudyal2021) found that hunters with high levels of trust and confidence in wildlife agencies were likely to pay more for conservation efforts, e.g., elk reintroduction. Thus, trust variables were used to explain hunter WTP for disease surveillance and measured agency trust in the specific context of CWD rather than general institutional trust. Variables related to trust and confidence in wildlife agency included hunter opinions on “I trust TWRA officials to have an appropriate plan for CWD in Tennessee” (PLAN), “TWRA has made a reasonable effort to educate the public about CWD” (PUBLIC), and “CWD information provided by TWRA is clear” (INFORMATION).

Independent variables related to risk perception, trust, and confidence (7 variables) might be endogenous in the econometric model due to omitted variables (Lundhede et al., Reference Lundhede, Jacobsen, Hanley, Strange and Thorsen2015). However, it was not possible to check the endogeneity problem due to a lack of valid instrumental variables. We tried to test for endogeneity bias of those attitudinal variables in the econometric model using socioeconomic factors (instruments) by following Interis and Petrolia (Reference Interis and Petrolia2014) but failed to report results due to an under-identification problem. Four socioeconomic characteristics included hunter age (AGE), landownership in CWD counties (OWNERSHIP), number of people living in the household (HOUSEHOLD), and annual household income (INCOME).