Sampling and data collection

During March and May 2014 we administered a written questionnaire in Basic English to 406 foreign tourists. The Annapurna Circuit trekking route was followed in a clockwise direction from Lower Mustang in the west to Manang in the east. Traveling the circuit in this direction meant we encountered new tourists on a daily basis, as the majority of trekkers follow the circuit in an anti-clockwise direction. We used cluster sampling of 33 hotels within villages along the route to identify a random sample of visitors. We selected 1–6 hotels randomly by lottery each day and approached tourists staying in these hotels after obtaining permission from the owners. Surveys were carried out in the evenings, when tourists spent time relaxing or waiting for meals. We used 20 questionnaires printed on a four-page booklet of laminated A3 paper and added the relevant bid amounts in permanent marker before distribution to minimize the amount of paper used. We shuffled the surveys before distribution to ensure a random distribution of bids. Prospective respondents were given a short briefing on the research project and then verbal consent was taken if they showed interest in participating. We provided participants with markers to complete their responses, which took 22.6 minutes on average (SD = 9.5; range = 12–55 minutes; n = 58), and remained nearby so that respondents were able to clarify any questions with us. After entering the data, and before wiping out the writing on the questionnaire sheet, we photographed all questionnaires and catalogued them for future reference. The questionnaires were cleaned and then re-used the following evening with the next set of random bids. Out of a total of 572 questionnaire completion requests, 406 were returned, giving a response rate of 71.0%. Of the 47 who gave their reason for not participating in the exercise 57.4% stated they were not interested in taking part, 14.9% mentioned language difficulties, 10.6% were too tired, 6.4% did not have time, 4.3% felt they did not know much about snow leopards, 4.3% stated that there was no point in this type of research and 2.1% were not allowed to write at that time because of their religious practices.

Contingent valuation

The contingent valuation method relies on surveys to estimate the value of environmental goods and services that are not traded in the conventional market (Arrow et al., Reference Arrow, Solow, Portney, Leamer, Radner and Schuman1993; Carson, Reference Carson2000). By creating a hypothetical marketplace, people are asked to report their willingness to pay to obtain or forgo a specified product or service, rather than inferring it from observed behaviours in the regular market (Venkatachalam, Reference Venkatachalam2004). The contingent valuation method has been used frequently to assess the willingness to pay of various types of stakeholders and for the protection of threatened and charismatic species (Walpole et al., Reference Walpole, Goodwin and Ward2001; Bandara & Tisdell, Reference Bandara and Tisdell2005; Baral et al., Reference Baral, Gautam, Timilsina and Bhat2007a, Reference Baral, Stern and Heinenb; Wilson & Tisdell, Reference Wilson and Tisdell2007; Richardson & Loomis, Reference Richardson and Loomis2009). The method has, however, been used less frequently for large carnivores (Lindsey et al., Reference Lindsey, Alexander, du Toit and Mills2005; Richardson et al., Reference Richardson, Rosen, Gunther and Schwartz2014).

As the goal was to estimate the amount that visitors would be willing to pay using a single bound dichotomous question, we measured the compensating variation for the improvement in conservation practice. Therefore, willingness to pay was operationalized as the amount that must be subtracted from people's income to keep their utility constant:

(1)$${\rm V}_1({\rm y} - {\rm A},{\rm} {\rm p},{\rm} {\rm q}_1;{\rm} {\rm X};{\rm \psi} ){\rm} = {\rm} {\rm V}_0({\rm y},{\rm} {\rm p},{\rm} {\rm q}_0;{\rm} {\rm X};{\rm \psi} )$$

where V denotes the indirect utility function, y is income, A is the bid amount, p is a vector of prices faced by the individuals, q ₀ and q ₁ are the alternative levels of conservation practice (q ₁ being improved quality), X is a vector of other characteristics, and ψ is a preference parameter. To maximize utility, the individuals would make a trade-off between income and conservation practice given their other characteristics. Individuals respond to the stated bid such that:

$$R = \left\{ \matrix{"{\rm Yes}" \quad {\rm if}\;{\rm WTP} \gt Bid \cr "{\rm No}" \quad {\rm if}\;{\rm WTP} \le Bid} \right.$$

where R denotes the response, WTP is willingness to pay and Bid is the stated conservation fee posed in the question asking about the visitors’ willingness to pay.

Following the contingent valuation scenario (Supplementary Material 1), visitors were presented with a single bound referendum-type question asking if they would be willing to pay a specific amount (USD A) as a conservation fee in addition to entry fees. One bid amount per questionnaire was randomly allocated from 12 proposed conservation fees: USD 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100 and 120. These bid amounts were selected based on a literature review of the contingent valuation of threatened species and protected areas (Walpole et al., Reference Walpole, Goodwin and Ward2001; Bandara & Tisdell, Reference Bandara and Tisdell2005; Baral et al., Reference Baral, Stern and Bhattarai2008), supplemented by prior experience of conducting similar studies elsewhere. Two debriefing questions were also included. An open-ended follow-up question solicited the most important reason for visitors’ response regarding their willingness to pay the specified amount. These qualitative responses were later coded and tallied.

There is some criticism of the contingent valuation method concerning the reliability of results, potential biases and uncertainty of hypothetical markets (Venkatachalam, Reference Venkatachalam2004; Bartczak & Meyerhoff, Reference Bartczak and Meyerhoff2013). Respondents may choose to state a lower willingness to pay if they are concerned that their responses may affect pricing policy, especially if they are likely to revisit the Conservation Area: the ‘unrevealed motivation’ bias (Walpole et al., Reference Walpole, Goodwin and Ward2001). The reverse may also be true, with individuals wanting to demonstrate their dedication to conservation. The strength of the contingent valuation approach, however, is its ability to capture non-use values, describe the socio-demographic characteristics of the target stakeholders and present hypothetical markets to estimate the value of the species in question (Ressurreicao et al., Reference Ressurreição, Gibbons, Dentinho, Kaiser, Santos and Edwards-Jones2011). Careful survey design is crucial to minimize hypothetical biases and our design reflected a real market scenario as closely as possible by choosing the entry fee as a payment vehicle. Similar to Baral et al. (Reference Baral, Stern and Bhattarai2008), we also reported to respondents that the Annapurna Conservation Area might re-assess pricing policy based on the survey's results.

Data analysis

We used logit regression to model the relationship between the dichotomous dependent variable (willingness to pay) and the independent variables. Ordinary least square regression violates the normality assumption when the response variable is binary, so the logit model is most appropriate in such a case. Based on a review of other contingent valuation studies conducted in relation to protected areas (Baral et al., Reference Baral, Stern and Bhattarai2008; Baral & Dhungana, Reference Baral and Dhungana2014) and threatened or charismatic species (Walpole et al., Reference Walpole, Goodwin and Ward2001; Bandara & Tisdell, Reference Bandara and Tisdell2005; Baral et al., Reference Baral, Gautam, Timilsina and Bhat2007a, Reference Baral, Stern and Heinenb; Wilson & Tisdell, Reference Wilson and Tisdell2007; Richardson et al., Reference Richardson, Rosen, Gunther and Schwartz2014), we hypothesized that respondents who were offered lower bid amounts, had greater knowledge of snow leopards, supported the implementation of the Snow Leopard Conservation Action Plan, were interested in participating in nature-based activities in the Conservation Area, travelled in a larger group (Baral et al., Reference Baral, Stern and Bhattarai2008), used a guide (Baral et al., Reference Baral, Stern and Bhattarai2008), spent longer in the Conservation Area, were more satisfied with their trip (Baral et al., Reference Baral, Stern and Bhattarai2008), were a member of an environmental organization, were older, had a higher income level, were more educated, and were male would all be more likely to pay a higher snow leopard conservation fee than others. With respect to the latter, the influence of being male is suggested by potential income disparity between men and women, as shown in other contingent valuation studies (Horton et al., Reference Horton, Colarullo, Bateman and Peres2003).

The following equation was estimated:

(2)$$\eqalign{&{\rm Probability}\;({\rm WTP}) = \cr & \quad a + b_1\;\hbox{bid amount}+b_2\; \hbox{snow leopard knowledge} \cr & \quad + b_3\; \hbox{support for Snow Leopard Conservation Action Plan} \cr & \quad + b_4\; \hbox{expectation to see snow leopards} \cr & \quad + b_5 \;\hbox{group size} + b_6\; \hbox{use of a guide} \cr & \quad + b_7\; \hbox{time in Annapurna Conservation Area} \cr & \quad +b_8 \;\hbox{trip satisfaction} + b_9 \;\hbox{environmental membership} \cr & \quad + b_{10} \;\hbox{age} + b_{11}\; \hbox{gender} + b_{12}\; \hbox{active in labour force} \cr & \quad +b_{13}\; \hbox{education level} + \hbox{error}}$$

where a is the constant and b_i are the coefficients of the explanatory variables. The goodness-of-fit of the model was estimated using the maximum log-likelihood ratio. We tested the model for misspecification and examined various residual plots.

Econometrics of willingness to pay

We presented the willingness to pay question as a referendum in which the respondents were asked if they would or would not be willing to pay a given bid amount A. It was assumed that visitors would maximize their utility while expressing their willingness to pay the specified bid amount to implement the Action Plan. The probability that a respondent would be willing to pay a given bid amount was assumed to follow a standard logistic variate (Hanemann, Reference Hanemann1984):

(3)$${{\rm Prob}({\rm Yes} \vert A{\rm,} X) = {({\rm 1} + e^{ - (\alpha + \beta A + X{\rm ^{\prime}}\Phi )})}^{ - {\rm 1}}}$$

where α is a constant parameter, β is the coefficient of the bid variable A, X is the vector of other explanatory variables influencing the response, and Φ is the vector of the corresponding slope parameters. Using estimated parameters of equation (3), the median amount that visitors were willing to pay was computed as

(4)$${\rm WTP =} \displaystyle{{\alpha + \bar X{\rm ^{\prime}}\Phi} \over \beta} $$

The mean amount was calculated by numerical integration of the expected values of willingness to pay, from USD 5.00 to the maximum bid amount of USD 120.00, using equation (3). We obtained the 95% confidence intervals for the mean amount visitors were willing to pay running the Monte Carlo simulation developed by Krinsky & Robb (Reference Krinsky and Robb1986). The simulation was implemented in STATA (StataCorp, College Station, USA) with the wtpcikr command (Estimate Krinsky and Robb Confidence Intervals for Mean and Median Willingness to Pay; Jeanty, Reference Jeanty2007).