Survey design and implementation

An online survey was designed using a professional platform (Qualtrics) and was distributed across the U.S. in the Spring of 2021 and again in the Spring of 2022Footnote ⁴ . This paper will focus on the second data collection round from the Spring of 2022. Prior to the survey distribution, two focus groups (n = 13) were conducted to gather instrumental feedback on the survey design. The focus groups lasted 75 minutes, and subjects were compensated $15 for their participation. Subjects were recruited through the University of Rhode Island’s nine colleges and had participants from the student, staff, and faculty body (with ages ranging from 20 to 70 years old), representing six different states.

The survey was distributed via Amazon Mechanical Turk (MTurk), a widely used survey recruitment tool that has been found to be fairly representative of the general population (Berinsky et al. Reference Berinsky, Huber and Lenz2012; Goodman and Paolacci Reference Goodman and Paolacci2017; McCredie and Morey Reference McCredie and Morey2019) Although MTurk respondents have been found, on average, to be younger, more educated, and employed less compared to the general population (Paolacci and Chandler Reference Paolacci and Chandler2014), it is still proven to generate a subject pool that is no worse than convenience samples (Berinsky et al. Reference Berinsky, Huber and Lenz2012). To mitigate any potential data quality concerns, only workers having high “approval rates” (HITs > 97%)Footnote ⁵ were allowed to participate in this study (Paolacci and Chandler Reference Paolacci and Chandler2014; Peer et al. Reference Peer, Vosgerau and Acquisti2014). Workers’ tasks were clearly stated, including description of the survey, realistic completion time, time constraints, and clear compensation rules (Harms and DeSimone Reference Harms and DeSimone2015; Lovett et al. Reference Lovett, Bajaba, Lovett and Simmering2018). In the Qualtrics survey, a CAPTCHA Verification question was utilized as well as screening questions to ensure participants belonged in the target population and are humans (Smith et al. Reference Smith, Sabat, Martinez, Weaver and Xu2015; Sharpe et al. Reference Sharpe Wessling, Huber and Netzer2017). After the data were collected, the IP addresses were checked for duplicates and location verification (Hauser et al. Reference Hauser, Paolacci and Chandler2018). The mean completion timeFootnote ⁶ (13 minutes) of the survey was checked, and speeders (those completing the survey in under 6 minutes) were removed (Sharpe et al. Reference Sharpe Wessling, Huber and Netzer2017). Finally, attention check questions were utilized, as well as a short answer questions designed to flag botsFootnote ⁷ .

The first section of the survey, the introduction, opens with a CAPTCHA Verification question, followed by presenting participants with an opening page which showed the University of Rhode Island’s logo and a short message thanking the respondents for their participation and a recommendation to take the survey on a screen larger than 7 inches. Following the opening page, a consent form was presented. The researchers obtained Institutional Review Board approval for the survey and all survey-related materials (e.g. focus group, recruitment material, and consent forms). After the consent form, screening questions were asked to ensure that respondents are eligible, with an eligible respondent being a resident of the U.S. and 18 years of age or older.

The second section of the survey collected data on awareness and usage of GRs. The first question asked respondents about their awareness of GRs, with possible responses as “Yes (please explain), No, or Unsure.” Only the respondents that reported being aware of GRs received the five follow-up questions about their knowledge and usage of GRs. The first follow-up question asked respondents to indicate how much they agree or disagree on a 5-point Likert scale (1 = strongly agree to 5 = strongly disagree) with the following statement: “I am an expert on green rooftops.” Following this question, respondents were asked “Are you aware of any green rooftop installations currently operating in your city or town?” with choice options including “Yes” or “No.” Next, respondents were asked “Have you seen a green rooftop in person?” with choice options “Yes” or “No.” Only respondent answering yes to seeing a GR continued to the following set of questions inquiring about spending time on GRs. First respondent answered the question “You mentioned that you have seen a green rooftop. Have you ever spent time on a green rooftop?” with choice options including “Yes” or “No.” Respondents that answered yes to spending time on GRs were then asked about the frequency of spending time on GRs, by being presented with the question, “How often do you spend time on green rooftop(s)?” with choice options including “weekly, bi-weekly, once a month, every few months, once a year, only once.”

The third section of the survey aimed to determine respondents’ support and value for the GR Program, the federally proposed GR bill. The section opened with a short statement describing the GR Program (Appendix B) and continued by asking respondents how they would want their government representatives to vote on the proposed program with options including “for, against, and unsure.” Respondents who selected against or unsure were asked a follow-up multiple-choice question that aimed to clarify the motivation behind their choices. A WTP question was asked for the GR Program in the form of payment cardFootnote ⁸ (Appendix C). The question used a sliding scale that allowed respondents to choose from a wide range of amounts (from $0 to $500Footnote ⁹ ). Respondents that reported a WTP of zero were asked a follow-up question about the motivation behind their choices. Next, respondents were presented with some information on GRs (found in the relevant literature), including information on the definition of GRs and their benefits and costs (Appendix D). Once the respondents were familiarized with GRs, the researchers asked the respondents once more about their vote and WTP for the GR Program. Again, respondents that selected the option to reject the program or reported a WTP of zero dollars were asked follow-up questions about the motivation behind their choices.

The fourth section in the survey aimed to determine what features respondents would want on a GR installation on a commercial building they frequently visit and how frequently they would visit this particular GR. First, to identify the commercial building respondents most frequently visit, the sample was asked to select from a list of 14 buildings the one they most frequently visited (Building options included: school, hospital, library, coffee shop, grocery store, restaurant, bar, gym or workout facility, sport stadium, airport, museum, zoo, parking garage, residential complex/apartment, other). Follow-up questions were asked about why the respondent visited the commercial building they selected with options including work, volunteer, recreational, errands, appointments/meetings, other (please specify). Additionally, respondents were asked to report how often they visited the building. To identify the most desired features a respondent wanted on a GR, respondents were informed that the commercial building the respondent previously selected will be installing a GR and that they will have access to this site. Then, a multiple-choice question asked the respondents to choose the features they would want to be included on the GR from a list of 15 randomized options (grass, shrubs/bushes, trees, flowers, walking paths, benches, area to work out, tables and chairs, lounge chairs, shaded area, garden/farm (producing fruits/vegetables, small ponds, bee hives, bird baths, solar panels), as well as options to indicate that they do not want a GR installed, have other preferences, and an attention check. A follow-up question was asked to all respondents that did not select the option “I do not want a GR installed” (n = 513) about how frequently the respondents would visit the hypothetical GR, if it had the desired features previously selected with choice options including “weekly, bi-weekly, once a month, every few months, once a year, and never.”

The fifth section included a choice experiment to determine respondents’ WTP for a GR installation on the commercial building the respondent selected in the previous section. This section of the survey is described in detail in “Choice Experiment Design.”

The sixth section aimed to gauge respondents’ support and preferences for a GR that hosts a produce farm on the commercial building chosen by the respondent in the previous section. The first question inquired about general support for a rooftop farm installed on the commercial building they frequently visited, with a 5-point Likert scale from “Very supportive to Not at all supportive.” Next, respondents had to indicate what types of fruits and vegetables they prefer to be grown on the rooftop farm. The short answers were processed with a free online word cloud generator to identify the most frequently reported produce items. Respondents were also asked how frequently they would purchase produce from the rooftop farm, with six choice options (daily, multiple times a week, once a week, monthly, less than once a month, and never), and their preferred venue to purchase the produce, with four different options: weekly farmers’ market, weekly community supported agriculture, daily store, or online delivery. Lastly, respondents received a matrix style question with a 5-point Likert scale from “Very important to Not at all important,” about the importance of the produce grown on the rooftop farm being “organic, sustainably grown, non-GMO, grown by local farmers, fresh, and pesticide free.”

The seventh and final section of the survey collected data on other factors that may affect the respondents’ decisions, such as social and demographic characteristics and attitudes toward environmental protection. To measure the respondents’ environmental attitudes, the researchers used the well-known New Ecological Paradigm scale (Dunlap et al. Reference Dunlap, Van Liere, Mertig and Jones2000). The survey concluded thanking the participants for their time and providing a space for feedback or comments.

GR Program WTP elicitation method

For the valuation of the GR Program, we used a payment card method, which can be in the form of a sliding scale from zero to a predetermined upper value, or a table of values that includes zero. There are several benefits to using a payment card method to elicit WTP values. One benefit is that it helps to avoid the starting point or anchoring bias, which is a cognitive bias that occurs when people are influenced by the first value or piece of information they receive (the “anchor”) and adjust their estimates or judgments based on that anchor (Mitchell and Carson Reference Mitchell and Carson1989; Bateman et al. Reference Bateman, Carson, Day, Hanemann, Hanley, Hett, Lee, Loomes, Mourato, Özdemiroglu, Pearce and Elgar2002). Another benefit of the payment card is that respondents are more certain about the values they provide, and hence the estimate of WTP obtained using this method is more reliable or accurate than that obtained using a dichotomous choice method (Ready et al. Reference Ready, Navrud and Dubourg2001). A choice experiment was less desirable in this situation as the researchers were not interested in different characteristics of the GR Program but solely concerned with determining community’s support and WTP for the current proposed legislation.

However, the payment card method is prone to range and centering bias (Mitchell and Carson Reference Mitchell and Carson1989), which can undermine the validity of the results. These shortcomings have been studied in the literature, and research suggests that they can be addressed by using a wide range of WTP values that covers the entire possible spectrum, rather than truncating it. This can help to mitigate range and centering bias (Mitchell and Carson Reference Mitchell and Carson1989; Rowe et al. Reference Rowe, Schulze and Breffle1996; Covey et al. Reference Covey, Loomes and Bateman2007). The range for the payment card ($0 to $500) was carefully chosen based on information obtained from surveying the relevant literature (Netusil et al. Reference Netusil, Lavelle, Dissanayake and Ando2022; Wieczerak et al. Reference Wieczerak, Lal, Witherell and Oluoch2022), feedback from focus groups, and the total amount of appropriations: $2.2 billion over five years (H.R.1863 – Public School Green Rooftop Program 117^th) being requested to implement the GR Program. Some of our focus group participants stated they would be willing to pay more than $300 dollars for GR installations on public schools. These participants felt that the benefits to the education system and reduction in cost to the school district resulting from GR installations would outweigh a one-time increase in their federal income taxes. The range we chose for our study aligns with the most recent findings in the literature that show households in Portland, Oregon, have a WTP between $202 and $442 for a one-year-long GR program, depending on the characteristics of the program (Netusil et al. Reference Netusil, Lavelle, Dissanayake and Ando2022). Following existing guidelines in relevant literature (Rowe et al. Reference Rowe, Schulze and Breffle1996; Covey et al. Reference Covey, Loomes and Bateman2007), to mitigate centering and range bias, the upper bound for the payment card was chosen to be $500.

Contingent valuation surveys are subject to pitfalls such as information effects (Bergstrom et al. Reference Bergstrom, Stoll and Randall1989), orderings effects (Halvorsen Reference Halvorsen1996), and hypothetical bias (Johnston Reference Johnston2006) among others. Minimizing the impact of these biases can be achieved by careful study design and implementation. To avoid any information or ordering effectsFootnote ¹⁰ when assessing public support and WTP for the GR Program, the researchers decided to ask about support and WTP for the GR Program at the beginning of the survey. Since the GR Program is a proposed piece of legislation that already exists, it took precedence over the choice experiment, which was a hypothetical situation. Therefore, the section on the GR Program came before the choice experiment. The researchers were also concerned that a misunderstanding of GRs could bias the results of the survey. Previous focus group discussions had found that about 25% of participants had an incorrect or alternate definitions or ideas of a GR. Further, most recent literature using a contingent valuation survey found that 84% of the respondents visited the GR under study but only 40% were aware it was a GR (Nguyen et al. Reference Nguyen Dang, Legg, Khan, Wilkinson, Ibbett and Doan2022). To address the issue of participants potentially having a misunderstanding of what a GR is, we considered it important to provide information on GRs to ensure that respondents had a consistent understanding of them. This would allow us to see if the information provided had any impact on respondents’ WTP for the GR Program. We believed that this would not significantly burden the respondents and would provide useful information for policy makers. It would also give us an indication of how the information provided might influence the results of the choice experiment.

Choice experiment design

A choice experiment was utilized to assess the respondents’ preferences and estimate their WTP for different attributes of GRs. The experiment involves presenting respondents with hypothetical scenarios or choice sets that vary in terms of specific attributes related to GRs. Respondents are then asked to choose their preferred option from each set. The design of the choice experiment can greatly impact results; therefore, close attention was paid in developing a realistic market and choice sets. Before starting the choice experiment respondents were provided with clear and concise information about the experiment and information about the hypothetical GR bill² and the maintenance process for the GR (Appendix E). This information was provided to help create a scenario that was as realistic as possible before entering the choice experiment.

One major concern with using choice experiments is that respondents’ decisions may not accurately reflect what they would do in real life, as no money or goods are being exchanged. This is known as hypothetical bias. To mitigate the concern of hypothetical bias, we followed an ex-ante and ex-post approach as suggested by Footnote ¹¹ Özdemir et al. (Reference Özdemir, Johnson and Hauber2009) and Tonsor and Shupp (Reference Tonsor and Shupp2011). Prior to the choice experiment, the researchers provided “cheap talk” information, which explained to the respondents that their responses were being used in important research that could influence current policy. We also asked the respondents to answer the questions as if the GR installation would actually be built and paid for through an increase in their state income taxes. After the choice experiment, a follow-up consequentially question was asked, to gauge how strongly respondents agree or disagree that the results of the survey will aid in decision-making process around future GR policy.

Our choice experiment includes five attributes: vegetation, amenities, community access, solar, and the payment vehicle, each with varying levels (Table 1). The attributes and their respective levels were carefully selected by conducting focus groups, surveying the relevant literature (Fernandez-Cañero et al. Reference Fernandez-Cañero, Emilsson, Fernandez-Barba and Machuca2013; Lee et al. Reference Lee, Williams, Sargent, Williams and Johnson2015; Kim et al. Reference Kim, Jung, Hapsari, Kang, Kim, Yoon, Lee, Han, Choi and Choe2018; Vanstockem et al. Reference Vanstockem, Vranken, Bleys, Somers and Hermy2018), and reviewing current GRs installed across the U.S. These attributes and levels closely mirror existing characteristics and features implemented on existing GRs installations on commercial buildings. Focus group discussions helped eliminate attribute levels that were of less importance such as workout areas and food services and highlighted important attributes such as community access and solar.

Table 1. Choice experiment attributes and levels

The payment vehicle, which represents the method of collecting payment from respondents in a choice experiment, was chosen to be a one-time increase in the respondents’ state income taxes for the year 2022. This method was selected in part because the GR bill being evaluated was a hypothetical state-funded grant program, and state governments typically receive a significant portion of their funding for public services through taxes. A tax was also chosen because it has been widely used in the literature to elicit WTP for ecosystem services via a choice experiment (Rambonilaza and Dachary-Bernard Reference Rambonilaza and Dachary-Bernard2007; Wattage et al. Reference Wattage, Glenn, Mardle, Van Rensburg, Grehan and Foley2011; Jacobsen et al. Reference Jacobsen, Lundhede and Thorsen2012; Ndunda and Mungatana Reference Ndunda and Mungatana2013). The payment vehicle levels ($10, $20, $40, $80) were informed by the focus groups, the first data collection, and surveying the relevant literature. Most of the focus group participants believed that a reasonable amount to pay for a state bill would be between $10 and $100 per year. This was a lower range than what was previously reported for the federal GR Program. Focus group participants mentioned that the primary reason for the lower range of WTP values for the state-sponsored bill in the choice experiment was because private building owners would be the primary beneficiaries, rather than public schools. The first data collection, which took place in Spring 2021, found that the resulting mean WTP values were consistent with those found in other studies that have explored WTP for GRs and green infrastructure (Netusil et al. Reference Netusil, Lavelle, Dissanayake and Ando2022; Wieczerak et al. Reference Wieczerak, Lal, Witherell and Oluoch2022).

The choice experiment was designed in Stata (a statistical software) using the command dcreate, which creates efficient designs for discrete choice experiments using the modified Fedorov algorithm. The algorithm maximizes the D-efficiency of the design based on the covariance matrix of the logit model (Hole Reference Hole2015). The design generated eight choice sets. Each choice set included three alternatives, named Proposal A, Proposal B, and Proposal C, with a fourth option that allowed respondents to reject the rooftop proposal (Holmes et al. Reference Holmes, Adamowicz, Carlsson, Champ, Boyle and Brown2017) (Figure 1). Each respondent was randomly assigned four of the eight available choice sets.

Figure 1. Choice experiment set example.

Econometric model

Choice experiments have a simplistic model that allows valuation of multiple attributes. They can provide a close estimate to respondents’ actual behaviors. Specifically, choice modeling is based on consumer theory and random utility theory. Based on Lancastrian consumer theory (Lancaster Reference Lancaster1966), choice modeling theory states that goods provide utility to consumers based on their attributes and can be broken down into separate utilities to reflect this. Therefore, this assumption can be applied to uncover prices consumers are WTP for each attribute. Random utility theory assumes consumers are rational decision makers that make choices to achieve the highest level of utility from the available options (McFadden Reference McFadden and Zarembka1974). Subsequently, the likelihood of an individual selecting a given alternative will be higher if the utility provided by the alternative is the highest among the different options.

The utility ${U_{ijt}}$ that an individual (i) can gain when choosing the alternative (j) ϵ {1,…,J} from choice set (t) ϵ {1,…,T} depends on observable and unobservable components. The observable components ( ${{\rm{V}}_{ijt}})$ are the linear additive combination of the explanatory variables, the GR attributes, and individual characteristics. The individual’s utility can be expressed in a linear equation in the form:

(1) $${U_{ijt}} = {\rm{\beta }}{'_i}{V_{ijt}} + {\varepsilon _{ijt}}$$

which includes ${\rm{\beta }}{{\rm{'}}_{\rm{i}}}$ , a vector of unknown marginal utilities that are to be estimated for the GRs attributes and control variables. The unobservable random component, ϵ_ijt, is assumed to be identically and independently distributed (iid) and follows the extreme value type 1 distribution (Hensher and Greene Reference Hensher and Greene2003).

The respondent will maximize their utility by choosing an alternative that will return the highest utility. The probability ( ${P_{ijt}})$ from an individual (i) choosing alternative (j) from a choice set (t) that yields the highest ${{\rm{U}}_{{\rm{ijt}}}}$ is given by:

(2) $${P_{ijt}} = \int {{{{\rm{e}}^{{\rm{\beta }}{{\rm{'}}_{\rm{i}}}{V_{ijt}}}}} \over {\mathop \sum \nolimits_{\rm{j}} {\rm{\beta }}{{\rm{'}}_{\rm{i}}}{V_{ijt}}}}{\rm{\;}}f({\rm{\beta |\theta )d\beta }}$$

where ${\rm{f}}({\rm{\beta |\theta )}}$ is the density function of ${\rm{\beta }}.$ The theory states that the difference in the utility of products drives product choices. The choice probabilities of an individual (i) selecting the j ^th alternative can be estimated using a random parameters mixed logit model:

(3) $$P\left( {{Y_{it}} = j} \right) = {\rm{\;}}{{{\rm{exp}}\left( {{v_{ijt}}{\rm{b'}}} \right)} \over {\mathop \sum \nolimits_{{\rm{j}} = 1}^{\rm{J}} {\rm{exp}}\left( {{v_{ijt}}{\rm{b'\;}}} \right)}}{\rm{\;}}$$

where Y_it represents the option in which individual (i) has chosen in choice set (t). A random parameters mixed logit model was chosen as the model of choice so both characteristics of the GR and the individual can be included (Hoffman and Duncan Reference Hoffman and Duncan1988.). A random parameters mixed logit model addresses the three limitations associated with standard logit models by allowing for random taste variation, unrestricted substitution patterns, and correlations in unobserved factors over time.

The random parameters mix logit model includes controls for the choice experiment attributes (price, vegetation, amenities, solar, and accessibility). Except for price, which is specified as a continuous variable, all other attribute controls are specified as dichotomous variables with shrubs/bushes, shaded area, no solar, and open access being the reference categories. Further, the alternate specific constant for no GRs installations is included. Each parameter is assumed to be normally distributed with the exception of the price coefficient which is specified to be log-normal.

To calculate the WTP _ijt for each respondent, the ratio between the estimated marginal utility for the GRs attribute is divided by the exponent of the estimated marginal utility for the monetary attribute (price), as seen below. It is necessary to take the exponent of the price parameter since it was specified to be log-normal distribution.

(4) $$WT{P_{ijt}} = {{{\beta _t}} \over {{\rm{exp}}\left( {{\beta _{price}}} \right)}}$$