2.1. Censored system and convexity

The extent of BMP adoption is censored at zero when a producer refuses an offered incentive. This problem complicates estimation of typical producer or consumer demand systems because of cross-equation residual correlation caused by the symmetry restrictions. The applied econometrics literature has generally approached quantity-censoring problems from the consumer side, but the logic supporting the estimation procedures extends directly to estimation of indirect profit functions. Shonkwiler and Yen (Reference Shonkwiler and Yen1999) introduced an inefficient but consistent procedure to estimate constrained censored demand systems. Su and Yen (Reference Su and Yen2000) and Yen, Kan, and Su (Reference Yen, Kan and Su2002) applied the two-step approach to estimate demand for meat and fats and oils, respectively. Other two-step approaches include Perali and Chavas’s (Reference Perali and Chavas2000) minimum distance estimator. More efficient maximum likelihood (ML) estimators for censored demand systems were developed by Yen (Reference Yen2005) and applied by Yen and Lin (Reference Yen and Lin2006). Bayesian Markov chain Monte Carlo estimators have also been used to estimate demand systems with censoring (Kasteridis, Yen, and Feng, Reference Kasteridis, Yen and Feng2011).

This analysis extends the two-step censored system estimator of Yen, Kan, and Su (Reference Yen, Kan and Su2002) to model the voluntary adoption of BMPs by producers given cost share incentives. From equation (2), set ${{\beta }} = \left( {{b_P},{b_R},{b_W},{b_S},{b_{PP}},{b_{RR}},{b_{WW}},{b_{SS}},{b_{PR}},{b_{PW}},{b_{PS}},{b_{RW}},{b_{RS}},{b_{WS}}} \right)'$. Then, for the $\ell$th pasture BMP conditioned on the producer’s willingness to adopt the BMP given the offered incentive, the quantity of the BMP supplied by the producer is

(3)$${q_{i\ell }} = \left\{ {\matrix{ {{{\bf{x}}_{i(\ell )}}{{\bf \beta}_{(\ell )}} + u_i^\ell } {{\rm{if}}\,\,\,\,{{\bf{z}}_i}{{\bf \gamma} _\ell } + \epsilon _i^\ell \gt 0} \cr 0 {{\rm{otherwise}}} \cr } } \right.,$$

where ${{\bf {z}}_i}$ are variables hypothesized to influence the producer’s decision to adopt BMP $\ell$ apart from the offered incentives; ${{\bf{\gamma }}_\ell }$ are parameters; $\epsilon_i^\ell$ is a random error term, and the product ${{\boldsymbol{\bf z}}_i}{{\boldsymbol{\gamma }}_\ell }$ is a linear index function (Maddala, Reference Maddala1983). The stochastic terms of the adoption and supply equations share common omitted factors because of the cross-equation parameter restrictions (e.g., adopt = 1 when $\epsilon_i^\ell \gt - {{\boldsymbol{\bf z}}_i}{{\boldsymbol{\gamma }}_\ell }$) and acres allocated to (or units of) a BMP. This feature could cause correlation between the residuals of the index functions and their respective quantity equations. The selection mechanism is typically modeled as a standard normal random variable with the probability of adoption ${\rm{\Phi }}\left( {{{{\bf z}}_i}{{\boldsymbol{\gamma }}_\ell }} \right)$ (the standard normal cumulative density function, CDF), and a corresponding standard normal probability density $\phi \left( {{{\bf{z}}_i}{{\boldsymbol{\gamma }}_\ell }} \right)$ (the standard normal probability density function, PDF). The parameters are estimated with probit regression and ML. It is important to note that the incentives do not appear in the index function because of the homogeneity and symmetry constraints required by the indirect profit function (e.g., Yen and Lin, Reference Yen and Lin2006). Thus, the linear index function only includes nonpecuniary variables corresponding with operator attributes and farm structure and management characteristics. The unconditional mean of the BMP quantity supplied by a producer is

(4)$$E({q_{i\ell }}|{{\bf{x}}_{i\left( \ell \right)}},{{\bf{z}}_{i\ell }}) = {\rm{\Phi }}\left( {{{\bf{z}}_{i\ell }}{{\bf{\gamma }}_\ell }} \right) \cdot {{\bf{x}}_{i\left( \ell \right)}}{{{\beta }}_{\left( \ell \right)}} + {\lambda _\ell } \cdot \phi \left( {{{\bf{z}}_{i\ell }}{{\bf{\gamma }}_\ell }} \right),$$

where ${\lambda _\ell }$ is the covariance between the error terms of the participation decision and the quantity of the BMP adopted; that is, ${\lambda _\ell } = {\rho _\ell } \cdot {\sigma _\ell }$ (Cameron and Trivedi, Reference Cameron and Trivedi2005; Maddala, Reference Maddala1983; Shonkwiler and Yen, Reference Shonkwiler and Yen1999).

An advantage of the SNQ indirect profit function is that global convexity can be imposed using ex post procedures (Henningsen and Henning, Reference Henningsen and Henning2009; Koebel, Reference Koebel1998; Perali and Chavas, Reference Perali and Chavas2000) or by directly estimating the Cholesky factorization of the Hessian matrix (e.g., Diewert and Wales, Reference Diewert and Wales1987; Lau, Reference Lau, Fuss and McFadden1978). Any positive semidefinite matrix can be written as ${\bf{B}} = {\bf{AA}}'$, where ${\bf{A}}$ is a lower-triangular matrix. Then, for the parameters in ${\bf{B}}$,

(5)$${\bf{A}} = \left[ {\matrix{ {{a_{PP}}} 0 0 0 \cr {{a_{RP}}} {{a_{RR}}} 0 0 \cr {{a_{WP}}} {{a_{WR}}} {{a_{WW}}} 0 \cr {{a_{SP}}} {{a_{SR}}} {{a_{SW}}} 0 \cr } } \right],$$

where ${a_{SS}} = 0$ such that ${\bf{A'}1 = 0}$ (Diewert and Wales, Reference Diewert and Wales1992). This restriction ensures the homogeneity requirement ${b_{\ell \ell }} = - \sum\nolimits_{\ell = 1,\,m \ne \ell }^L {{b_{\ell m}}}$. The $\left[ {{\alpha _{\ell m}}} \right]$ elements enter directly into the system defined in equation (2) and are estimated with ML, along with the PDF and CDF evaluated at the first-stage probit ML estimates.

2.2. Estimation

The system is estimated with iterated feasible generalized nonlinear least squares (IFGNLS), which converges to the ML estimator (Zellner, Reference Zellner1962), using the ifgnls option in STATA’s nlsur routine (StataCorp, 2015). Applying IFGNLS in the second step yields consistent estimators because the ML probit estimates of ${{\gamma}}$ are consistent (Shonkwiler and Yen, Reference Shonkwiler and Yen1999).

Breusch and Pagan’s (Reference Breusch and Pagan1980) test is used to determine if the seemingly unrelated regression (SUR) error covariance matrix is diagonal. The null hypothesis is ${H_0}:{\sigma _{PR}} = {\sigma _{PW}} = {\sigma _{PS}} = {\sigma _{RW}} = {\sigma _{RS}} = {\sigma _{WS}} = 0$. Under this null, the test statistic is a chi-square random variable with six degrees of freedom and a critical value of 12.59 at the 5% level of significance. A likelihood ratio (LR) test is used to select the preferred model, with the null hypothesis ${H_0}:{\lambda _P} = {\lambda _R} = {\lambda _W} = {\lambda _S} = 0$. The test is a chi-squared random variable with four degrees of freedom and a critical value of 9.49 at the 5% level of significance.

Yen, Kan, and Su (Reference Yen, Kan and Su2002) suggest estimating the error covariance of the two-step censored system using a Murphy-Topel estimator. This application uses a jackknife covariance procedure to estimate the parameter covariance matrix (Perali and Chavas, Reference Perali and Chavas2000). The probit regression, the standard normal CDF and PDF, and the system of BMP supply equations were reestimated with IFGNLS for each jackknife replicate. Standard errors of the regression coefficients are estimated as the mean squared error difference between the replicate parameters and the parameters estimated with the original data set. Own- and cross-incentive elasticities are calculated for each jackknife replicate, with the lower 5% and upper 95% bounds determined by the elasticity distributions.

2.3. Application: adoption of survey best pasture management practices

Sediment load reductions generated by rotational grazing and the suite of the survey BMPs, including improved pasture management, water tanks, and stream crossings, are simulated by maintaining minimum pasture forage stands. The ArcSWAT (Version 2012, Release 10) graphical user interface was used to develop a Soil and Water Assessment Tool (SWAT) model of the Oostanaula Creek watershed in ArcGIS Desktop (ESRI, Version 10.5). SWAT is a physically based model developed to simulate land-management and rainfall-runoff processes in predominantly agricultural watersheds with a high level of spatial detail using hydrologic response units (HRUs). HRUs are unique combinations of soil type, slope, and land use/management practices (Gassman et al., Reference Gassman, Reyes, Green and Arnold2007).

For the adoption effects analysis, management practice modifications were made to pasture HRUs. Land use, soils, and digital elevation data were downloaded from the U.S. Department of Agriculture’s (USDA) Geospatial Data Gateway (USDA, Natural Resource Conservation Service [NRCS], 2018). Land use corresponded with the 2009 Croplands Data Layer (Johnson and Mueller, Reference Johnson and Mueller2010). Soil types were classified according to the State Soil Geographic (STATSGO) data set (Wang and Melesse, Reference Wang and Melesse2006). Slopes (0–2%, 2%–8%, 8%–16%, and >16%) were established using the National Elevation Dataset (10 m resolution; Gesch et al., Reference Gesch, Oimoen, Greenlee, Nelson, Stuek and Tyler2002). Rainfall input data for the model were obtained from the National Weather Station Coop database for two stations in Athens and Cleveland, Tennessee (Leeper, Rennie, and Palecki, Reference Leeper, Rennie and Palecki2015). Models were run from January 1990 to October 2013, with a monthly time step and a two-year startup period. Model development, calibration, and validation details are provided in online supplementary Appendix II.

A total of 466 HRUs represented the watershed’s unique land use/slope/soil combinations. Of these, 207 were classified as pasture, representing a total of 18,114 acres. Fescue forage was produced in pasture HRUs using fertilization and grazing management routines (online supplementary Appendix II). The adoption of the survey suite of BMPs was modeled through modifications to the management practice schedule for grazed fescue (“FESC”) land use category by varying the BIOMIN setting. This BIOMIN setting is used in SWAT to avoid pasture damage and increased erosion caused by overgrazing (White et al., Reference White, Storm, Busteed, Stoodley and Phillips2010). This procedure constrains minimum vegetation in kilograms of dry matter per hectare after which grazing is discontinued. A calibrated and validated model run with a BIOMIN setting of 300 was completed to assess sediment loss when the potential for severely overgrazed pastures existed. A second model run with a BIOMIN setting of 1,000 was used to assess sediment loss potential after implementing the suite of survey BMPs.

Fifty-two of the 207 pasture HRUs accounted for 90% of the annual sediment runoff from pasture (Figure 1).Footnote ² The total area represented by these 52 HRUs was 4,821 acres. In the absence of rotational grazing on any of these pasture HRUs (BIOMIN setting of 300), the SWAT model estimated an annual sediment yield of 22,839 tons/year from the watershed’s pastureland. When rotational grazing was implemented on the 52 pasture HRUs (BIOMIN setting of 1,000), the annual sediment yield from these HRUs decreased to 13,230 tons/year. Thus, the ability to identify and differentiate land use/soil/slope combinations offers the potential for more cost-effectivesediment abatement.

Figure 1. Distribution of differences in sedimentation loading for hydrologic response units managed with and without rotational grazing.

The simulation focuses on the adoption of the survey suite of BMPs to increase forage productivity and reduce sediment runoff from pasture. The total program cost of achieving a sediment abatement goal for the watershed could be calculated as the solution to a cost minimization problem, subject to producer responsiveness to monetary incentives encouraging the enrollment of pasture acres into the hypothetical rotational grazing program. Along these lines, we adopt the optimization approach suggested by Govindasamy and Huffman (Reference Govindasamy and Huffman1993) and Smith et al. (Reference Smith, Williams, Nejadhashemi, Woznicki and Leatherman2014). Parameters and variables used to estimate the cost of meeting a sediment abatement target through the adoption of rotational grazing are in Table 1.

Table 1. Parameters and variables used in the optimization procedure

Notes: HRU, hydrologic response unit (see text for definitions); P, pasture improvement; R, rotational grazing; S, stream crossing; W, water tank.

The optimization problem minimizes the cost of reaching a watershed sediment abatement goal by choosing an HRU-specific incentive to encourage enrollment of pasture acres into the hypothetical program, subject to producer willingness to enroll acres into the program and animal water requirements.Footnote ³ By allowing incentives to vary among HRUs, we are implicitly assuming that the agency administering the incentive program has the information and authority to discriminate among land uses based on sediment loading rates.

The objective function for the optimization problem is

(6)$${\min _{{p_{R(k)}}{\rm{ > }}0}}\sum\nolimits_{k = 1}^{52} {{p_{R\left( k \right)}}} \cdot{q_{R\left( k \right)}}$$

subject to:

(7)$${S_k} = {S_{0(k)}} + {S_{1(k)}}\forall k.$$

(8)$$\mathop \sum \nolimits_{k = 1}^{52} {S_k} = Q.$$

(9)$${q_{R(k)}} = {\hat b_{RR}} \cdot \left( {{{{p_{R(k)}}} \over {\bar c}}} \right)\left[ {1 - {{\bar \omega R} \over 2} \cdot \left( {{{{p_{R(k)}}} \over {\bar c}}} \right)} \right]\forall k.$$

(10)$${q_{R(k)}} \le {T_k}\forall k.$$

The objective minimizes the total cost of enrolling private pasture into the rotational grazing program, with ${p_{R\left( k \right)}}$ the dollars per acre paid annually to producers in HRU k (equation 6). Equation (7) is the total amount of sediment loading generated by the k th HRU from areas managed with and without rotational grazing. The sediment abatement target is equation (8), which aggregates sediment (annual tons) loading across the watershed. Equation (9) is the estimated acreage supply equation for rotational grazing from the normalized quadratic profit function. The parameter $\overline c$ is the average of Diewert and Wales’s (Reference Diewert and Wales1992) price index over the sample ($\overline c$ = 351), and ${\overline \omega _R}$ the sample average of the weighting factors for rotational grazing (${\overline \omega _R}$ = 0.08). The intercept term is omitted because, in the absence of incentives, enrollment of pasture acres into the hypothetical rotational grazing program would be zero. The number of acres enrolled into the program cannot exceed the total available acres in HRU k (${T_k}$, equation 10).

The rotational grazing acreage supply equation is used to generate a watershed abatement curve. The abatement curve represents the dollars per ton the agency would have to pay in incentives to achieve an annual sediment target. Enrollment of pasture acres into rotational grazing is calculated for each HRU at the optimized incentives, corresponding with a target level of sediment. Then, using equation (7), the change in sediment loading because of the pasture managed under a rotational grazing system of BMPs (${q_{R\left( k \right)}} \cdot [{r_{0\left( k \right)}} - {r_{1\left( k \right)}}]$) is aggregated across HRUs at a given per acre incentive offered to producers to manage pasture acres using rotational grazing. The dollar per acre incentive is converted to dollar per sediment ton using the sediment yield parameters (${r_{0\left( k \right)}}$ and ${r_{1\left( k \right)}}$, Table 1) generated by SWAT. We vary the target sedimentation level Q from 13,000 to 22,800 tons/year in increments of 426 tons (24 intervals), solving the problem at each target with the General Algebraic Modeling System (GAMS Development Corporation) using a sparse nonlinear optimization procedure (snopt).

Project costs used to calculate the abatement curves include the incentives paid for the installation of water tanks. Water tanks are required when animals are in paddocks for rotational grazing and prevented from accessing streams or ponds. The number of water tanks required was calculated based on cattle water requirements and the number of beef cattle that could be supported by the optimal enrolled acreage levels for the different sediment targets. The number of beef cattle (BeefCattle) that can be supported by pasture forage in HRU k is (Undersander et al., Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002)

(11)$$BeefCattl{e_k} = {{{q_{R(k)}} \times Forage\,Yield} \over {Forage\,Access \times Animal\,Weight \times Days\,Grazed}}.$$

Forage productivity (Forage Yield) is assumed to be 4,000 lb./acre (Undersander et al., Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002), and animal forage requirements (Forage Access) assumes that animals require 4% of their live weight in forage per grazing day (Undersander et al., Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002). Based on what is typical for the region’s pasture forage systems, we also assume a 153-day grazing period (Days Grazed) and a finishing weight of 1,250 lb. (Animal Weight).

The number of water tanks required in a rotational grazing paddock in an HRU (${q_{WT\left( k \right)}}$) was determined as the number of beef cattle supported by the HRU times the gallons per day consumed by each animal (10 gallons/animal/day; Undersander et al., Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002) divided by the tank size (800 gallons):

(12)$${q_{W(k)}} = {{10 \times BeefCattl{e_k}} \over {800}}.$$

The 75% cost share rate of $1,150 per 800-gallon tank was held constant across the water shed.

3.1. Operator and farm characteristics

Operator and farm characteristics are hypothesized to influence the probability of adopting one or more of the BMPs (Table 2). Operator characteristics included in the probit adoption equations are age, educational attainment, and plans to pass on the farm to a family member. Farmers with more years of education may be inclined to adopt new technologies or practices (Daberkow and McBride, Reference Daberkow and McBride2003; Roberts et al., Reference Roberts, English, Larson, Cochran, Goodman, Larkin, Marra, Martin, Shurley and Reeves2004). Younger producers may be willing to experiment with new technologies because their planning horizons are longer (Schimmelpfennig and Ebel, Reference Schimmelpfennig and Ebel2011; Watcharaanantapong et al., Reference Watcharaanantapong, Roberts, Lambert, Larson, Velandia, English, Rejesus and Wang2014). A respondent’s ties to the farm and the prospect of passing on the operation to kin could also effectively extend a respondent’s time horizon and increase the likelihood of adopting BMPs (Claytor et al., Reference Claytor, Clark, Lambert and Jensen2018). Farmers who own relatively more of the land they operate may be more likely to adopt practices they perceive would improve the aesthetic or property value of their farm (Roberts et al., Reference Roberts, English, Larson, Cochran, Goodman, Larkin, Marra, Martin, Shurley and Reeves2004). Higher property values may be associated with proximity to other parcels that have been developed for residential or commercial uses. The assessed per acre property value of the parcel may therefore also influence the decision to adopt a pasture BMP. Farm topography may also affect the decision to adopt pasture BMPs. Slope was assigned to parcels based on the majority of the area associated with the parcel classified into one of four categories represented in the watershed: 0–2%, 2%–8%, 8%–16%, and >16% slope (Medwid, Reference Medwid2016).

Farm operation variables include farm size, the percent of land farmed in pasture, and animal stocking density. Larger operations are more likely to adopt new technologies because of scale economies (Fernandez-Cornejo, Daberkow, and McBride, Reference Fernandez-Cornejo, Daberkow and McBride2001). Farms allocating relatively more of the land they manage to pasture may be more likely to incorporate pasture BMPs into their operation (Jensen et al., Reference Jensen, Lambert, Clark, English, Yu, Larson, Holt and Hellwinckel2015). Operations stocking pasture with cattle at relatively higher densities may also be more inclined to perceive the adoption of a suite of pasture BMPs as a way to sustain or increase productivity (Jensen et al., Reference Jensen, Lambert, Clark, English, Yu, Larson, Holt and Hellwinckel2015). Familiarity and experience with each of the BMPs considered in this analysis may also explain willingness to participate in the hypothetical BMP incentive program.