Theoretical Model of Crop Insurance and CRP Trade-Off

A representative producer faces a trade-off between production and participation in CRP. The relative costs and benefits of each option determine how much of the producer's total land holdings he or she devotes to each. The availability of government subsidized crop insurance may change the size of these relative benefits in favor of production over conservation.

I model the behavior of the representative producer following Chang and Boisvert (Reference Chang and Boisvert2009), who offer a household production model approach.Footnote ¹ The producer allocates his or her total endowment of land, $\bar{A}$, between crop production, A _p, and CRP enrollment, A _c. Though the entire endowment of land may be planted to crops, soil productivity varies within the field. A portion of land, A _m(q), is considered marginal cropland characterized by poor soil productivity (e.g., highly erodible land [HEL]). The amount of marginal cropland is exogenously determined by q, the soil characteristics of the farm which vary across geographic regions. The amount of marginal cropland eligible for enrollment into CRP is $\bar{A}_c\equiv t\cdot A_m\lpar q\rpar $, where t ∈ [0, 1] reflects national and regional acreage caps set by government policy.Footnote ² Limits on enrollment vary over time (national cap) and across regions (county cap).Footnote ³ Given there are only two land use choices, the amount of marginal cropland in production is defined as $A_p^m \equiv A_m\lpar q\rpar -A_c$, the difference between marginal land and the portion of marginal land enrolled in CRP.

I employ a Just and Pope (Reference Just and Pope1979) production function where output (yield per acre harvested) is a function of both a deterministic component and a stochastic shock.

(1)$$\matrix{ {y\lpar A_p^m\comma \; {\rm \varepsilon} \semicolon \; q\rpar = f\lpar {\rm \Gamma} \lpar q\comma \; A_p^m \rpar \rpar + {\rm \Gamma \lpar }q\comma \; A_p^m {\rm \rpar }^{-1}\cdot {\rm \varepsilon}} \cr} $$

The deterministic component,f( · ), depends on the average soil quality of land in production, represented by the term Γ( · ).Footnote ⁴ Average soil quality itself depends on two factors: an exogenous soil quality index q, which varies regionally and across farms, and $A_p^m $, the amount of marginal cropland placed in production. The former captures regional heterogeneity in cropping capability, where Γ_q >0. For example, a well-drained farm in Iowa will be endowed with a higher q than a typical farm in the arid West. The latter incorporates the effect of intra-field land allocation choices on crop yields. The average quality of soil in production will fall as additional marginal acres are brought into production (“fence to fence” planting), making the partial ${\rm \Gamma} _{A_p^m} $ negative.

The stochastic portion of yield is captured by the termε_, which represents negative production shocks such as drought, hail, or flooding. Yield risk is assumed to be i.i.d. distributed, where ε ≤ 0, ${{\open E}}\lpar {\rm \varepsilon} \rpar = {\bar{\rm \varepsilon}} \lt 0$, and$\; {\rm VAR\lpar \varepsilon \rpar } = {\rm \sigma} _{\rm \varepsilon} ^2 $. Production shocks are mitigated by the average soil quality of planted land. Higher values of Γ( · ), due either to superior regional soil characteristics or a smaller amount of marginal land in production, attenuates the negative effect of ε on yields toward zero.Footnote ⁵ The output price per unit of yield, p, is assumed to be exogenous to the producer and independent of land-use decisions.

The farmer purchases federal crop insurance on planted acres, which triggers an indemnity payment, $I\lpar {\rm \varepsilon}\comma \; {\rm \Gamma} \lpar q\comma \; A_p^m \rpar \rpar $, per acre in the event of a loss caused by the random shock,ε. Higher values of ε and lower values of Γ( · ) raise the frequency and size of insurance indemnities. The total premium cost per acre, $\nu \lpar {\bar{\rm \varepsilon}}\comma \; q\rpar $, is made to be actuarially fair for a given region based on expected losses, $\bar{\varepsilon} $, and regional soil characteristics.Footnote ⁶ The government subsidizes premiums at rate s ∈ (0, 1), so the per-acre insurance cost to the producer is$\; \lpar 1-s\rpar \cdot \nu \lpar {\bar{\rm \varepsilon}}\comma \; q\rpar $.

The producer receives an annual rental payment, r(q, t), for each acre enrolled in CRP. Rental rates are determined by the USDA Farm Service Agency (FSA) according to the soil properties of the region and prevailing cropland rent but are also influenced by government policy which sets maximum rates participants may receive during a given period.Footnote ⁷

The producer allocates land to maximize expected utility from farm profits, π(A _p, A _c), and environmental amenities generated by land enrolled in CRP, e(A _c). Environmental amenities include recreation and wildlife viewing and capture the non-monetary motivations for enrolling in the program. The importance of environmental amenities in the producer's utility likely vary according to demographics and farm type (Lambert et al. 2006).

The producer's constrained optimization problem is as follows:

(2)$$\matrix{ {\mathop {\max} \limits_{A_p\comma \, A_c} {{\open E}}\lcub {{{\open U}}\lsqb {{\rm \pi} \, {\rm \lpar }A_p\comma \; A_c{\rm \rpar }\comma \; e\, \lpar A_c\rpar } \rsqb } \rcub } \cr} $$

subject to:

(3)$$\!\! \matrix{ {{\rm \pi} \, {\rm \lpar }A_p\comma \; A_c{\rm \rpar } \!=\! \lcub {\,p\cdot \lsqb {\,f\lpar {\rm \Gamma} \lpar q\comma \; A_p^m \rpar \rpar + {\rm \Gamma \lpar }q\comma \; A_p^m {\rm \rpar }^{-1}\cdot {\rm \varepsilon}} \rsqb + I{\rm \lpar \varepsilon}\comma \; {\rm \Gamma \lpar }q\comma \; A_p^m {\rm \rpar \rpar }-\lpar 1-s\rpar \cdot \nu \, \lpar {\bar{\rm \varepsilon}}\comma \; q\rpar } \rcub }\cr \cdot A_p { + \; r\lpar q\comma \; t\rpar \cdot A_c} \cr} $$

(4)$$\matrix{ {A_p + A_c = \bar{A}} \cr} $$

(5)$$\matrix{ {A_c \le {\bar{A}}_c = t\cdot A_m\lpar q\rpar } \cr} $$

(6)$$\matrix{ {A_p\comma \; A_c \ge 0} \cr} $$

Constraint equation 4 assumes the producer can only allocate land between crop production and retirement. This is most representative of regions such as the Corn Belt, where soil productivity restricts the number of competing land uses, but is less representative of areas such as the West and Southern Plains, where crop production must compete with grassland pasture and forest (Bigelow and Borchers 2017). Constraint equation 5 defines the CRP eligibility limit as a function of the amount of marginal land, determined by regional soil characteristics, and government policy. Note that equation 5 may not be binding. In such a case, part or all the land eligible for CRP is put into production. Non-negativity constraints for the choice variables are stated in equation 6.

Substituting equation 4 into the objective function and using the definition of marginal cropland makes the constrained optimization problem a function of only A _c.Footnote ⁸

(7)$$\eqalign{& \quad\quad\quad\quad\quad\quad\quad\quad\quad\quad\quad L\left( A_c,{\rm \lambda}\right) =\cr & E\left\{{\open U}\left[\left[p\left[f\left({\rm \Gamma}\left(q,A_p^m \right) \right) + {\rm \Gamma} \left( {q,A_p^m } \right)^{-1}{\rm \varepsilon } \right] + {\rm I}\left( {\rm \varepsilon },{\rm \Gamma }\left( {q,A_p^m {\rm \; }} \right) \right)\right.\right.\right.\cr & \left.\left.\left. -\left( {1-s} \right)\nu \left({\rm \bar{\varepsilon }},q \right)\right] \left( {\bar{A}-A_c} \right) + r\left( {q,t} \right)A_c,\; e\left( {A_c} \right)\right]\right\}-\lambda \left(A_c-tA_m\left( q \right) \right)\#}$$

Kuhn Tucker conditions defining an optimum are as follows:

(8)$$\eqalign{& E\left\{{\rm {\open U}}_\pi \cdot \left[\left( {\bar{A}-A_c} \right)\left[ {p\left( {-{f}^{\prime}\left( \cdot \right){\rm \Gamma }_{A_p^m } + {\rm \Gamma }{\left( \cdot \right)}^{-2}{\rm \Gamma }_{A_p^m }{\rm \varepsilon }} \right)-{\rm I}_{\rm \Gamma }{\rm \Gamma }_{A_p^m }} \right]-p\left[ {f\left( \cdot \right) + {\rm \Gamma }{\left( \cdot \right)}^{-1}{\rm \varepsilon }} \right]\right.\right.\cr & \quad \left. -{\rm I}\left( \cdot \right) + \left( {1-s} \right)\nu \left( \cdot \right)\right] + E\left( {\rm {\open U}_\pi \cdot r\left( \cdot \right)} \right) + E\left({\rm {\open U}_e\cdot {e}^{\prime}\left( \cdot \right)} \right)-{\rm \lambda } = 0\#}$$

(9)$$\matrix{ {A_c-tA_m\lpar q\rpar \le 0} \cr} $$

(10)$$\matrix{ {{\rm \lambda \lpar }A_c-tA_m{\rm \lpar }q{\rm \rpar \rpar } = 0} \cr} $$

(11)$$\matrix{ {\lambda \ge 0} \cr} $$

where ${{\open U}}_\pi $ and ${{\open U}}_e$ represent marginal utility from farm profit and environmental amenities, respectively. Equation 8 shows that the optimal land allocation equates the expected marginal utility of crop production profit with the expected marginal utility of CRP revenue plus the marginal utility of environmental amenities generated by land in CRP minus λ, the shadow price of CRP eligibility. The shadow price represents the marginal utility of increasing the amount of land eligible for CRP, either by changing the endowment of marginal cropland or by raising the number of acres the government allows to enter the program. If the producer derives a large amount of utility from CRP's environmental benefits and would like to enroll more than is allowed by the cap (i.e., if constraint equation 5 is binding, a higher enrollment cap would cause him or her to put more land in CRP and increase their optimal utility). Lambda is then positive if A _c = tA _m(q) and zero if A _c <tA _m(q).

The optimal choice of A _c is found by simultaneously satisfying equations 8–11, which I express in reduced form as a function of exogenous variables.

(12)$$\matrix{ {A_c^{^\ast} = A_c^{^\ast} \lpar {\,p\comma \; {\rm \varepsilon}\comma \; s\comma \; q\comma \; t\comma \; {\rm \lambda}} \rpar } \cr} $$

The relationship of interest is the effect of decreasing the out-of-pocket cost of insurance, which increases the returns to production (including on marginal cropland) on the amount of acreage retired into CRP. Provided actuarially fair premiums remain constant, the per-acre cost of insurance to the producer will fall due to an increase in the government-determined subsidy rates. The sign and size of the relationship between subsidy rates and CRP are a function of the exogenous covariates of the model: output price, weather shocks, regional soil characteristics, and the enrollment cap.

Importantly, the relationship at the farm level depends on the degree to which land can come in and out of the program (i.e., how limited CRP enrollment is by constraint equation 5). If regional soil properties, q, and the government enrollment cap, t, are such that little or no land is eligible for CRP to begin with, any change in insurance subsidies (or any other variable) will have little or no impact on CRP enrollment. Conversely, if tA _m(q) is positive but constraint equation 5 is binding, then all eligible land that can be enrolled in CRP is enrolled. The amount of land the producer would like to enroll may greatly exceed eligibility. CRP will again be unresponsive to changes in crop insurance. This example reflects a farm in a county at or near its CRP acreage cap.

The effect of insurance subsidization on CRP is best observed in farms where $\bar{A}_c\lpar q\rpar \gt 0$ and 0 <A _c <tA _m(q). Such cases allow CRP participation to respond positively and negatively to variations in insurance subsidies. Insurance effects will be most evident on farms that closely reflect the model's assumption that land uses are limited to production and conservation. Farms in the Corn Belt, for example, embody the insurance-conservation trade-off because the margin between crop production and CRP is thin relative to regions with more land-use heterogeneity. In other words, the true effect of insurance on CRP participation will appear in areas plentiful in CRP-eligible land, having direct competition between CRP and row-crop production, and where the CRP enrollment constraint is non-binding.

In general, the eligibility constraint creates a limited dependent variable problem that one would ideally estimate with a censored regression model at the farm level. Because I estimate the CRP-insurance relationship using county-level data, however, the above conditions introduce the possibility of aggregation bias. Aggregating farms that are constrained in their CRP participation together with unconstrained farms may give the appearance of sufficient CRP engagement at the county level but will not take into consideration the limited responses that can be made on-farm. The true effect of insurance will emerge in counties where farms are homogenous in their ability to increase or decrease enrollment in CRP (i.e., where both CRP-eligible land is plentiful and crop production competes directly with it for land use). In the Results section, I discuss how this type of aggregation bias may partially explain differences in effect sizes observed across U.S. farm production regions.Footnote ⁹

Data

Data for this project come from the USDA Risk Management Agency, the USDA Farm Service Agency, the Chicago Board of Trade, the USDA National Agricultural Statistical Service, and the National Oceanic and Atmospheric Administration. Data are observed at the county level for the years 1989 to 2013. The chosen years span the enactment of four major crop-insurance policies that exogenously increased insurance participation (FCIRA of 1994, ad hoc rate increases, ARPA of 2000, and the 2008 Farm Bill) as well as 14 separate CRP General Sign-ups and four different national enrollment caps. The geographic scope of the study includes all 48 contiguous states. The USDA Risk Management Agency (RMA) operates the federal crop-insurance program and maintains thorough records of all crop-insurance policies sold since 1981. RMA reports these data at the county level and makes them publicly available through an online database. From RMA, I collected the number of acres insured, total premiums charged, and total government subsidies paid in each county by policy type.Footnote ¹⁰

County-level CRP enrollment data come from the USDA Farm Service Agency (FSA), which provides county totals for acres retired and total rental fees paid every year. To determine the average CRP rental fee per acre, I simply divide total payments made in a county by the number of acres enrolled. I correct CRP rental rates for inflation using the Producer Price Index (PPI). I also observe the years in which a General Sign-up or Continuous Sign-up was offered between 1989 and 2013.Footnote ¹¹ Continuous Sign-up was made available in every year after 1996, while General Sign-ups occurred in 1989, 1991, 1992, 1995, 1997, 1998, 2000, 2003, 2004, 2006, and 2010–2013. The relevant measure of CRP participation over time is the total CRP acreage enrolled in a county. This number includes both acres enrolled through General and Continuous Sign-up conventions. I exclude counties from the dataset that have no CRP enrollment in any of the 25 years examined.Footnote ¹²

Commodity prices play a key role in both land retirement and crop-insurance choices. Harvest prices are not known when crop-insurance policies and CRP contracts are established, so landowner decisions in each year are based on expectations. For insurance, RMA uses averages of December corn, November soybeans, and September wheat futures prices traded during the month of February to determine premiums and guarantees.Footnote ¹³ I collect futures prices for corn, soybeans, and wheat from the Chicago Board of Trade through an online database made available by Quandl Inc.Footnote ¹⁴ I take the average February settlement price for each futures contract for the years 1989 to 2013 and adjust for inflation using the PPI for each commodity.Footnote ¹⁵ From the USDA National Agricultural Statistical Service (NASS) I collect the number of acres harvested of corn, soybeans, and wheat in each observed county from 1979 to 2013. From this I calculate a measure of each commodity's importance based on its percentage of total acres harvested over the previous 10 years. I then create a weighted average of all three futures prices as follows:

(13)$$\matrix{ {P_{it} = \mathop \sum \limits_j {\rm \mu} _{\,jit}p_{\,jt}} \cr} $$

where

$$\; {\rm \mu} _{\,jit} = \displaystyle{{\mathop \sum \nolimits_{{\rm \tau} = t-10}^{t-1} H_{\,ji{\rm \tau}}} \over {\mathop \sum \nolimits_j \mathop \sum \nolimits_{{\rm \tau} = t-10}^{t-1} H_{\,ji{\rm \tau}}}} $$

The term H _jiτ represents the total acres harvested of crop j in county i during yearτ for j  = corn, soybeans, and wheat. Missing values for crop production weights are replaced with averages for the state in which the county resides.

The National Oceanic and Atmospheric Administration (NOAA) publishes the Palmer Drought Severity Index (PDSI) at the state level for all contiguous states. The PDSI measures soil moisture levels using both current and previous conditions, making the PDSI a good indicator of long-run trends in precipitation. Positive values indicate wet conditions, while negative values correspond to drought. From annual average PDSI values I create an indicator variable equal to one in years when states experienced moderate-to-extreme drought conditions.Footnote ¹⁶

The compiled dataset includes 2,756 counties observed between 1989 and 2013, for a total of 68,900 observations. Table 1 summarizes the variables described above for each of the relevant crop-insurance policy periods. The important policy changes that occurred during the observation period included the Federal Crop Insurance Reform Act of 1994 (FCIRA), ad hoc subsidy rate increases in 1998 and 1999, the Agricultural Risk Protection Act of 2000 (ARPA), and the 2008 Farm Bill. Each policy made meaningful changes to the schedule of crop-insurance subsidy rates for the purpose of increasing participation. Figures 1 and 2 depict the impact of these policy changes on different crop-insurance types, and Figure 3 shows the commensurate trend in overall crop-insurance participation between 1989 and 2013. The vertical dashed lines correspond to the passage of each of the four major policies. I consider a policy period the years between the passing of a given crop-insurance law and the enactment of a new policy.

Source: USDA Risk Management Agency, Crop Insurance Statistics by County 1989–2013.

Figure 1. Crop Insurance Subsidy Rates by Coverage Level (1989–2013)

Source: USDA Risk Management Agency, Crop Insurance Statistics by County 1989–2013.

Figure 2. Crop Insurance Subsidy Rates by Policy Type (1989–2013)

Source: USDA Risk Management Agency, Crop Insurance Statistics by County 1989–2013.

Figure 3. Total Acres Insured by Federal Crop Insurance (1989–2013)

Table 1. Summary Statistics by Crop Insurance Policy Period

Notes: CRP rental rates are adjusted for inflation using annual averages of the Producer Price Index for all goods. Commodity futures prices are adjusted for inflation using the Producer Price Index specific to each commodity for the month of February.

Sources: CRP data come from USDA FSA statistics on CRP enrollment. Crop insurance data provided by USDA RMA data files. PDSI generated by state specific queries on NOAA Climate Monitoring website. Futures prices from the Chicago Board of Trade are made available by Quandl Inc. Crop harvest data downloaded from USDA NASS Quick Stats online database. Producer Price Indices for each commodity were retrieved from the St. Louis Fed FRED online database.

Total acreage under federal crop insurance exhibits a general upward trend throughout the observation period, with large jumps occurring after FCIRA in 1994, ARPA of 2000, and the Farm Bill of 2008. Acres insured more than doubled after passage of the 1994 Act to over 70,000 acres per county. Trends in subsidy rates for various policy types illustrate the differential effects of the four policy changes. For example, because catastrophic insurance (CAT) carries a 50 percent coverage level, changes in subsidy rates for 50 and 55 percent policies reflect the full subsidization of CAT insurance brought about by FCIRA in 1994. Similarly, buy-up policies experience their largest increases in subsidy rates during the ad hoc and ARPA policy periods. Note that 80 percent policies and revenue-based policies do not enter the market until 1993 and 1996, respectively, so their subsidy rates are zero prior to the FCIRA policy period.

Average CRP enrollment rises and falls between 11,000 and 13,000 acres per county during the study period. National CRP enrollment was originally capped at 45 million acres but has changed over time to reflect budgetary conditions and policy goals. Figure 4 illustrates the trend in CRP participation and the total enrollment caps from 1989 to 2013. Enrollment increased gradually until 1996 thanks to successful early General Sign-ups in 1989, 1991, and 1992, but suffered throughout the late 1990s despite the introduction of the Continuous Sign-up convention. Changes in total enrollment over time generally reflect the national enrollment cap, commodity prices, and climate (Claassen and Hellerstein 2008; Secchi et al. Reference Secchi, Gassman, Williams and Babcock2009; Rashford, Walker, and Bastian Reference Rashford, Walker and Bastian2010; Hendricks and Er Reference Hendricks and Er2018).

Source: USDA Farm Service Agency, CRP Statistics 1986–2014.

Figure 4. Total Acres Enrolled in CRP (1989–2013)

Drought conditions are most widespread in 1999 and 2000 and from 2009 to 2013.Footnote ¹⁷ Inflation adjusted futures prices for corn, soybeans, and wheat are also presented in Table 1 along with the historical proportion of acres harvested of each crop. Expected price refers to the production weighted average futures price as described above.

Estimating the Impact of Crop Insurance on CRP

The total number of CRP acres in any given year can be modeled as previous acres enrolled less exiting acreage plus new acres entering the program. The number of acres leaving the program can be expressed as a proportion of the total acres enrolled the year prior. Initially, I assume there is an average annual exit rate ofδ_, which is constant over time and across counties.Footnote ¹⁸ I test this assumption in Appendix B, showing that the exit (re-enrollment) rate is significantly higher (lower) during years when the national enrollment cap is low.

The total number of acres enrolled in CRP in county i during year t can be expressed as follows:Footnote ¹⁹

(14)$$\matrix{ {{\rm CR}{\rm P}_{it} = {\rm CR}{\rm P}_{it-1}-{\rm \delta CR}{\rm P}_{it-1} + {\rm \eta} _{it}\lpar {{\rm Acres\; Insure}{\rm d}_{it}\comma \; \; {\bi X}_{it}\comma \; {\rm \alpha}_i\comma \; {\rm \tau}_t} \rpar } \cr} $$

Net new acres entering CRP in each year, represented byη_it, is a function of the number of acres insured under federal crop insurance, Acres Insured_it, a vector of exogenous control variables that affect both insurance and conservation behavior, X_it, county fixed effects, α_i, and year fixed effects, τ_t.Footnote ²⁰ The vector X_it includes CRP rental rates, expectations of drought, and expected commodity prices. County fixed effects control for regional characteristics such as soil quality and preferences for environmental amenities. Policy changes that impact all counties in each year, namely, the national CRP enrollment cap, are captured by year fixed effects. Assuming linear relationships between CRP participation and all explanatory variables, I estimate the following panel data fixed effects regression:

(15)$$\matrix{ {{\rm CR}{\rm P}_{it} = \lpar {1-{\rm \delta}} \rpar {\rm CR}{\rm P}_{it-1} + {\rm \alpha} _i + {\rm \tau} _t + {\rm \psi Ren}{\rm t}_{it} + {\rm \beta Acres\; Insure}{\rm d}_{it}} \cr { + \theta {\rm Drough}{\rm t}_{st-1} + \phi P_{it} + e_{it}} \cr} $$

I first estimate a model without time controls as a baseline to compare with year fixed effects.

A primary incentive for producers to enter CRP is the per-acre rental rate, represented in the model by the variableRent_it, which should have a positive and significant impact on CRP participation.Footnote ²¹ The estimate of the average CRP exit rate δ can be calculated by subtracting the estimated coefficient on lagged CRP acreage from one. To control for climate shocks that impact both CRP and crop-insurance decisions, I include a drought indicator. The variableDrought_st−1 is a dummy variable equal to one if the county located in state s has an average Palmer Drought Severity Index (PDSI) of negative two or below in year t − 1.Footnote ²² Lagged drought conditions represent expectations of future droughts which may positively or negatively affect CRP acreage, as poor growing conditions make risk-free CRP rental fees more attractive while at the same time increasing expected payouts from insurance. Weighted average commodity futures prices are represented by the variableP _it. As CRP rental payments are fixed for the duration of the contract, high crop prices raise the opportunity cost of CRP. I expect futures prices to negatively impact CRP enrollment.

The right-hand side variable of interest is the total number of acres insured in county i during year t. I predict that land insured under federal crop insurance crowds out potential new acres entering CRP and causes existing acres to exit the program. The magnitude of the effect, however, should be small, in accordance with previous literature (Young, Vandeveer, and Schnepf Reference Young, Vandeveer and Schnepf2001; Goodwin, Vandeveer, and Deal Reference Goodwin, Vandeveer and Deal2004; Lubowski et al. 2006; Claassen, Langpap, and Wu Reference Claassen, Langpap and Wu2017)

Endogeneity between insurance activity and CRP complicates the above specification. Producers make crop-insurance and land-retirement decisions jointly. Without an exogenous source of variation in insurance use, the estimated impact of insured acres on CRP will reflect this joint determination. Specifically, $\hat{\beta} $ may capture how CRP participation influences planting and insurance decisions. Moreover, equation 15 does not incorporate subsidies for crop insurance but only the total amount of insured acreage. The number of insured acres within a county may vary for many reasons unrelated to subsidization which are not the focus of this paper. An endogeneity issue also emerges in the CRP rental rate variable. Because the rental rate variable is calculated as an average for each county-year, acres enrolled in CRP enters both sides of the regression equation. If estimated as written, the relationship between acres enrolled and program compensation will be biased (likely in the downward direction).

I address these issues by employing an instrumental variables approach. Government policy exclusively sets the subsidy rates applied to each type of crop-insurance policy and coverage level. This schedule of subsidy rates has changed over time to encourage greater participation in the program and reduce the need for disaster assistance. I exploit increases in subsidy rates resulting from four major crop-insurance policy changes, the Federal Crop Insurance Reform Act of 1994 (FCIRA), ad hoc subsidy rate increases in 1998 and 1999, the Agricultural Risk Protection Act of 2000 (ARPA), and the 2008 Farm Bill. Figures 1 and 2 illustrate the impact of government policy changes (denoted by vertical dashed lines) on subsidy rates of different types of crop insurance.Footnote ²³ The impact of these policy changes can be seen clearly in Figure 3. A marked increase in acres insured follows the enactment of each piece of legislation, with the exception of the 2008 Farm Bill, which appears to have had a delayed effect on participation.Footnote ²⁴

I use dummy variables for each policy period (FCIRA, ad hoc, ARPA, and the 2008 Farm Bill) to instrument for changes in the number of acres insured. Policy indicators can explain within-county variation in acres insured over time but do not provide the spatial (between-county) variation necessary for proper instrumentation. Crop-insurance legislation is set at the national level, meaning every county in the dataset receives the policy “treatment” at the same time but may not receive it in the same way. A measure of the degree to which various policies affect a county is required. To do this, I measure preferences for different types of insurance prior to the enactment of each legislative change.

From Figure 1 we see that FCIRA of 1994 dramatically impacts subsidy rates for 50 and 55 percent policies, while “buy-up” plans (60 percent coverage and above) experience smaller but meaningful increases in subsidy rates. The large change in subsidy rates for low-coverage plans reflects the introduction of fully subsidized catastrophic coverage (CAT). To measure the extent to which the 1994 Act impacts a county, I calculate the percent of total cropland insured at each coverage level category (50–55 percent, 60–65 percent, 70–75 percent, and 80–85 percent) in the period prior to the enactment of FCIRA (1989 to 1994).Footnote ²⁵ This approach generates between-county variation in exposure to FCIRA subsidy rate increases that is unrelated to CRP decisions.

Ad hoc subsidy increases passed in 1998 and 1999 raise subsidy rates for buy-up and revenue plans (see Figures 1 and 2) but leave low-coverage and yield-based policies relatively unaffected. ARPA of 2000 added to these changes, and the Farm Bill of 2008 further increases rates for high-coverage products. I capture a county's exposure to these policy changes by calculating the percentage of cropland insured under each coverage level in the periods directly preceding the passage of each legislative change.

Insurance participation prior to each policy change is measured as a percentage of total cropland to control for the scale of production capacity in each county. The USDA calculates total cropland for each county as part of the Census of Agriculture every five years. I use acres of cropland in 1992 to calculate percentages of insured acres during the pre-FCIRA period, cropland in 1997 to calculate insurance percentages in the FCIRA and ad hoc policy periods, and cropland in 2002 for the ARPA period.Footnote ²⁶

To generate instruments for insured acres, I interact these policy-exposure measures with dummy variables representing each of the four policy change periods.Footnote ²⁷ These interactions can be used to determine how much a county sees its effective subsidy rates increase and can be used to estimate the variation in insured acreage due only to changes in government policy and not to contemporaneous land-use decisions. Pre-policy exposure measures reflect a county's entrenched preferences for certain types of insurance. Therefore, when new legislation acts on these preexisting preferences, causing insurance participation to rise or fall, we can be confident that the resulting variation in acres insured is attributed only to exogenous government policy and not jointly determined CRP enrollment.

To provide further spatial variation in insurance use that is uncorrelated with conservation decisions, I include a one-year lag of acres insured as an additional instrument. While the policy-change instruments measure the impact of subsidy rate increases on insurance participation (demand response), lagged insurance use measures of a county's preference for crop insurance more generally. Lagged insured acres are highly predictive of future insurance use within a county but are predetermined with respect to current CRP enrollment (or exit) decisions.

Following a similar approach, I use a one-year lag of the county CRP rental rate to address the endogeneity between current rental rates and acres enrolled in CRP. This strategy resolves the downward bias in estimated rental rate effects that result from averaging total payments over the number of acres in CRP. CRP rental rates are made to reflect prevailing cash rental rates for non-irrigated farmland of different soil types. Because soil types are unchanged from year to year, lagged rates serve as strong predictors of future rates. Any remaining year-to-year fluctuations in CRP rent reflect changes in farm profitability (price and yield shocks) and government policy (maximum acceptable bids), which independently affect current CRP acreage decisions. Conditional on lagged CRP enrollment, drought expectations, commodity futures prices, and government policy (year fixed effects), prior CRP rental rates will be correlated with current rental rates but uncorrelated with the error term in equation 15. Lagged CRP rental rates are therefore a valid IV for present rental rates.

I perform a two-stage least squares (2SLS) regression using Stata's XTIVREG2 command, which accommodates both instrumental variables and clustering of standard errors. First-stage regression equations predict current insurance participation and CRP rental rates using policy-period dummies, policy-exposure measures, lagged-acres insured, lagged-CRP rental rates, and all exogenous covariates shown in equation 15. In the second-stage regression, predicted values for acres insured and rental rates take the place of the endogenous regressors. See Appendix A for a detailed explanation of the instrumental variables calculation and first-stage regression for insured acreage. Standard errors are clustered at the state level as opposed to the county level following Cameron, Gelbach, and Miller (Reference Cameron, Gelbach and Miller2011).Footnote ²⁸