Methods

The empirical strategy developed below is based on a conceptual model of a petroleum company's drilling location preferences. I assume that, with limited drilling resources, a company drills one location at a time.Footnote ² The expected value from location j at time t is

(1)$$v_{\,jtk} = pf\lpar {{\rm \alpha} h_j + {\rm \beta} x_j + {\rm \gamma} z} \rpar -c_j-rz + {\rm \delta} _th_j\lpar {1-k_t} \rpar + \lpar {\kappa + {\rm \mu} {\rm fe}{\rm e}_j + {\vartheta} h_j} \rpar k ,$$

where p is the per unit price of oil, f() is units of oil produced from the well, h _j are fixed habitat attributes, x _j are other location attributes, z are variable inputs, c _j is a location-specific cost, r is the marginal cost of the variable inputs, and κ  +  fee_j is the fixed plus location-specific cost of enrolling a well in the RWP. The variable k equals one if the well is enrolled and zero otherwise. The variables fee_j is the cost of mitigating for location j, which depends on ecoregion characteristics, prior impacts, and habitat quality. The fourth right-hand side term measures the penalty from ESA regulations that occur at time t. The last term measures the relative cost of enrolling in the RWP. Solving the first order condition for variable inputs shows that optimal output (oil production) depends only on location choice, conditional on k. The decision to enroll in the RWP, which is determined jointly with the preferred drilling location, therefore depends on location attributes. This decision can be modeled econometrically in a discrete choice framework.

The analysis uses three periods: (1) the time before the RWP, (2) during the RWP when the LPC is not listed, and (3) during the RWP when the LPC is listed. The first period occurs prior to December 2013, when the RWP was launched, and the third period runs from May 2014 to September 2015. First- and second-period comparisons reveal how location preferences shifted with establishment of the RWP, while the second and third periods show how participation and the value of conservation agreements changed after listing. Table 1 presents total RWP enrollment and nonenrollment numbers during these three periods.

Table 1. Number of oil and gas wells drilled by location, RWP status, and when drilling began

I now develop a discrete choice model to measure the effect of habitat quality on companies’ drilling locations and their willingness to enroll wells in the RWP. Companies’ preferences are a function of profitable location attributes and conservation values (with respect to habitat), as in the conceptual model. For simplicity, consider the location choice problem before the RWP. Using the structure of the conceptual model, expected value to company i of drilling in location j at time t is:

(2)$$v_{ijt0} = {\rm \alpha} h_j + {\rm \beta} x_j + {\rm \varphi} _j + {\rm \varepsilon} _{ijt0} $$

where h _j is a dummy variable that equals one if the location is in the EOR + 10 and zero otherwise, x _j is a vector of other location attributes, φ_j is a vector of county fixed effects, and ε _ijt0 is a random error term. The county fixed effects proxy the conceptual model's fixed cost c _j. Equation 2 does not contain any other terms from equation 1 because it is based on drilling in period 1, before the RWP, which by definition has k  =  0 and δ_t  =  0.

Now consider the choice problem when companies could participate in the RWP, in periods 2 and 3. Expected value depends on the choice to enroll in a conservation agreement or not. The expected value from an enrolled well (i.e. k  =  1) is

(3)$$v_{ijt1} = {\rm \alpha} h_j + {\rm \beta} x_j + {\rm \varphi} _j + \kappa + {\rm \mu} {\rm ln}\lpar {\rm fe}{\rm e}_j\rpar + {\vartheta} \bar{h}_j + {\rm \gamma} _{{\rm esa}} + {\rm \eta} _{ij} + {\rm \varepsilon} _{ijt1}, $$

where $\bar{h}_j$ is a decomposition of the habitat dummy into different habitat ranks, including focal areas, connectivity zones and other suitable habitat (the fourth rank, unsuitable habitat, is the reference category), κ is the effect of the enrollment cost, which is a constant, fee_j is a location-specific mitigation fee, and η_ij is an error component measuring firm-specific heterogeneity in the demand for conservation agreements. The effect of fee is largely identified from variation in ecoregion type because fee is a function only of ecoregion type, prior impacts and habitat rank, habitat rank is included as a variable ($\bar{h}_j$), and existing impacts may be partially captured through the other location attributes (x _j). I expect that ${\vartheta} $ is positive and varies by habitat rank, e.g., companies prefer conservation agreements in focal areas to conservation agreements in unsuitable habitat. The RWP should be more valuable in focal areas because enrolling a project in these areas is more likely to help LPCs. It is also reasonable to expect that κ and μ are negative, i.e. that companies prefer to combine the RWP with locations that have a lower enrollment fee. The term γ_esa measures the effect of listing on recruitment into the RWP in period 3, i.e., when t  =  esa. This effect should be positive if enforcing ESA regulations incentivized participation in conservation agreements.

The expected value from drilling but not enrolling in the RWP (i.e. k  =  0) is

(4)$$v_{ijt0} = {\rm \alpha} h_j + {\rm \beta} x_j + {\rm \varphi} _j + \lpar {{\rm \delta}_{{\rm rwp}} + {\rm \delta}_{{\rm esa}}} \rpar h_j + {\rm \varepsilon} _{ijt0}, $$

where the effect of regulatory scrutiny δ_t in habitat locations varies across periods such that t  =  rwp in period 2 and t  =  esa in period 3. Equation 4 differs from equation 3 because projects that do not enroll in the RWP experience this scrutiny but do not experience any conservation agreement costs/benefits. The first term in parentheses measures the effect of the RWP on drilling in habitat, while the second term measures the effect of ESA regulations (listing the LPC) on drilling in habitat. The second coefficient, δ_esa, will be negative if ESA regulations impose land use restrictions on projects not in the RWP. The sign of the first coefficient, δ_rwp, is not clear ex ante; the RWP published detailed habitat maps, and the coefficient will be positive if this information attracted drilling into the habitat area (but that did not enroll in the RWP) and negative if it deterred companies from drilling in habitat.

Figure 1 presents a diagram of the empirical, discrete choice model. The top panel shows the choice alternatives before the RWP, when companies made location decisions using equation 2. The bottom panel shows the choice alternatives during the RWP, when companies made decisions using equations 3 and 4. Each habitat location has two choice alternatives during the RWP: an enroll alternative and a not-enroll alternative.

Figure 1. The choice model before availability of the RWP (top panel) and during the availability of the RWP (bottom panel). Locations outside the habitat area, such as locations 1 and J in the diagram, did not have the enrollment option.

I estimate two versions of the model. First, I fix η_ij at zero and assume ε_ijtk is independent and identically distributed extreme value for a conditional logit. The probability of choosing location j and enrollment option k from among all possible alternatives, i.e., v _ijtk > v _imtl for all m locations and l enrollment options, is

(5)$$P_{ijtk} = e^{w_{ijtk}}/ \sum \nolimits e^{w_{{\rm imtl}}}, $$

where w _ijtk is the observable, deterministic part of equations 2–4. The logistic function is estimated using equation 2 for the choice occasions in period 1, and equations 3–4 for the choice occasions in periods 2 and 3. I estimate all parameters simultaneously using maximum likelihood methods. Second, I assume η _ij is an independent, normally distributed error component with standard deviation σ, to relax the independence of irrelevant alternatives (IIA) assumption and allow for flexible substitution patterns between the RWP and non-RWP alternatives (Hensher, Rose, and Greene Reference Hensher, Rose and Greene2005). Thus, the error component “nests” the RWP alternatives separately from the non-RWP alternatives. Then the probability of choosing alternative j,k is

(6)$$P_{ijtk} = \smallint \nolimits e^{w_{ijtk}}/ \sum \nolimits e^{w_{{\rm imtl}}}{\rm \phi} \lpar {{\rm \eta} \vert {\rm \sigma}} \rpar d{\rm \eta}, $$

which is a mixed logit. I use the clogit routine in StataCorp Stata. Release Reference Langpap14 (2014) to estimate the conditional logit and the mixlogit routine developed by Hole (Reference Hole2007) to estimate the mixed logit.

The analysis draws on two datasets. The first is oil and natural gas wells recorded by the Kansas and Oklahoma corporation commissions. I focus on these states because they contain the majority of LPC habitat and most participation in the RWP.Footnote ³ Descriptive information includes the location, initial drilling date, completion date, geological formation targeted and if the well is producing oil, natural gas or both. I narrow the time series to January 2012 through May 2016 to focus on drilling around the time of the RWP and listing. For records missing the initial drilling date, I assume drilling began three months prior to completion, which is the typical length of time to complete a well in the study period. Following Melstrom (Reference Melstrom2017), I focus on drilling in western Kansas and Oklahoma based on corporation commission division boundaries. Location alternatives are described by Public Land Survey System (PLSS) coordinates, which subdivides land into a nested arrangement of quadrilaterals. Petroleum companies typically identify leases based on PLSS descriptions. Using the smallest spatial unit, the 1 × 1-mile section, there are nearly 100,000 location alternatives.

The second dataset comes from the list of petroleum projects participating in the RWP. I matched these projects to wells in the corporation commissions’ database using project (well) names. Out of 838 enrolled projects, 49 percent match to a well.Footnote ⁴ Unfortunately, it is impossible to tell if unmatched projects did not appear in commission records because companies decided not to complete the projects or were match failures because names did not harmonize across datasets. However, companies often delay drilling during periods of volatile and falling prices, which occurred at the end of the study period, making it likely that many of the unmatched projects never materialized (Kellogg Reference Kellogg2014). I also collected spatial data on the RWP's habitat classifications and projected mitigation fees, which are commensurate with the quality of habitat impacted by the well (Van Pelt et al. Reference Van Pelt, Kyle, Pitman, Klute, Beauprez, Schoeling, Janus and Haufler2013).

I drew a random sample of sections into the choice set to reduce the computational burden of estimating the model. Parsons and Kealy (Reference Parsons and Kealy1992) and Feather (Reference Feather1994) show that randomly sampling alternatives does not generate bias in problems with large choice sets. This procedure is based on the recommendation of McFadden (Reference McFadden1978) for handling discrete choice problems with thousands of alternatives. For each choice occasion I randomly drew 249 sections without replacement, excluding those classified as primarily surface water. I then added the chosen section to the sample to yield 250 alternatives. These alternatives became the choice set for wells drilled before the RWP. I expanded number of alternatives after the launch of the RWP, by adding an enrollment option for each section in the EOR + 10, doubling the number of choice alternatives associated with the habitat locations.

Table 2 provides a description and summary statistics for each choice attribute in the model. The first set of attributes describes habitat locations, the second set describes the location of existing land uses, and the third set describes features of the RWP. In particular, habitat is a dummy that equals one for sections in habitat and zero otherwise; focal, connectivityzone, and suitable are dummies for each habitat rank. These three areas are a priority for habitat conservation. The means of these dummies imply that 46 percent of sections are in habitat, with 11 percent in focal areas, 2 percent in connectivity zones, and 14 percent in other suitable habitat. The dummies pasture, crops, wetlands, and developed equal one if pasture, crop farming, wetlands, or housing, respectively, is the primary land use in a section. These data show that 50 percent of locations in the study region are pasture, 41 percent are crops, less than 1 percent are wetlands, and 2 percent are primarily housing (the balance, 7 percent, is in forest). The variable fee is the average projected mitigation fee per acre to drill a well and participate in the RWP.Footnote ⁵

Table 2. Location and RWP attributes in the choice models

I allow drilling activity in the model to be correlated over time and space in two ways. First, wells on the same lease are unlikely to be drilled independently of each other, so I cluster standard errors by petroleum lease. Second, companies may tend to cluster wells in locations with proven petroleum reserves. I therefore include the variable wells _dum, to indicate which sections have existing wells, and wells _num, to measure the number of existing wells in a section prior to each choice occasion. Another possible concern is that the choice set definition developed above is too broad and includes irrelevant and insignificant alternatives. I probe the sensitivity of the results to a narrower choice set definition by restricting each company's choice set to sections in counties in which the company has one or more existing wells (as a company probably does not own or lease any land in counties it has not worked in before).