2.1. Farmer’s Individual Strategy

In our network diffusion model, a finite set of soybean farmers choose between a DR seed and a seed that is NR. Since spraying dicamba creates a negative externality for nearby fields that adopt NR seed, each farmer’s seed choice has the potential to affect their neighbor’s profitability. If two farmers’ soybean fields are adjacent, then they are considered neighbors. The amount of neighbors farmer i has is known as their degree and is denoted d _i . The percentage of farmers within the network with a given degree is denoted P(d), where P(d) ≥ 0, for d ∈ {0, 1, 2, 3, 4}, and $\sum _{d=0}^{4}P(d)=1$ .

We assume that because the DR trait is a relatively recent development, the NR seed is the default seed choice. Farmer i’s payout from using NR seed is their expected externality-free profit from NR, $\pi _{i,{\rm NR}}$ , minus their expected externality damage from OTM, $E_{i,{\rm NR}}$ , denoted

(1) $$V_{i,{\rm NR}}=\pi _{i,{\rm NR}}-E_{i,{\rm NR}}$$

The externality damage farmer i receives from NR seed, $E_{i,{\rm NR}}$ , is a function of d _i , and the percentage of these neighbors growing DR soybeans, λ _i , and their externality-free profit, $\pi _{i,{\rm NR}}$ . The model parameter g estimates the percentage loss in yield based upon number of neighbors using DR seed, $g(d_{i},\lambda _{i})$ , while the parameter f estimates the percentage loss in NR profit as a function of yield loss, $f(g(d_{i},\lambda _{i}))$ . The percentage loss in profit is multiplied by expected externality-free profit to calculate total OTM damage,Footnote ² giving us the final form,

(2) $$E_{i,{\rm NR}}=f\left(g(d_{i},\lambda _{i})\right)\pi _{i,{\rm NR}}$$

Farmer i could instead receive a payoff for using DR seed, $V_{i,{\rm DR}}$ . This payoff is free from externalities since DR seed is by definition resistant to dicamba and thus is unaffected by neighbors’ actions and is simply the expected profit to growing DR seed, $\pi _{i,{\rm DR}}$ .

(3) $$V_{i,{\rm DR}}=\pi _{i,{\rm DR}}$$

Finally, a farmer compares the two options and chooses the one that provides the highest expected profit.Footnote ³ They will switch from NR seed to DR seed once the payoff of adopting DR, $V_{i,{\rm DR}}$ surpasses the opportunity cost of NR, $V_{i,{\rm NR}}$ . Hence, farmer i will adopt DR whenever ${V_{i,{\rm DR}} \over V_{i,{\rm NR}}}\geq 1$ .

2.2. Modeling Spatial Network Effects

As mentioned, payouts for each farmer’s decision within the network are influenced by the actions of others within their network. The social externality experienced by an NR seed grower, $E_{i,{\rm NR}}$ , is 0 if no one in the network grows DR, but it can become quite high if enough farmers within the network adopt DR seed. Due to this spatial externality tying together all farmers within the network, we must model how DR adoption rates within a network, x _t , evolve over time, t.

(4) $$x_{t}=\sum _{d=0}^{4}{x_{t,d}dP(d) \over \overline{d}}$$

Parameter x _{t, d} captures the percentage of farmers with degree d, that have chosen DR seed, at time t. Parameter $\overline{d}$ denotes the average degree of a farmer within the network. Diffusion of DR seed technology is modeled by exogenously establishing a given percent of DR seed adoptors at $t=0$ , x ₀. Each farmer responds to this x ₀ and its expected effect on their payouts from each seed choice by altering or keeping their original planting choice in the following period, t = 1, this new level of DR adoption is defined as x ₁. This new level of adoption in time 1 will then subsequently affect planting decisions in time 2, and so on. These changes will continue until the market hits a new steady state, $x_{\rm SS}$ , where neither NR or DR growers want to change technology in the subsequent period.

Farmer adoption decisions in the previous period x _{t − 1} will affect adoption this period. Equation (5) computes the percent of DR adopters of a given degreeFootnote ⁴ in time t.

(5) $$x_{td}=1-C[1-f(g\left(d,x_{t-1}\right)]$$

Each farmer will have unique ratio of externality-free payouts between DR and NR adoption, denoted $K_{i}={\pi _{i,{\rm DR}} \over \pi _{i,{\rm NR}}}$ . When considering all farmers within a network, K captures the distribution of all K _i within the network. Parameter C in Equations (5) and (6) captures the CDF of K. Equation (6) shows the calculation of DR adaptors at time t for the entire network and is derived by substituting the right-hand side of Equation (5) into Equation (4) for x _{t, d} ,

(6) $$x_{t}=1-{1 \over \overline{d}}\sum _{d=0}^{4}dP\left(d\right)C\left[1-f(g\left(d,x_{t-1}\right)\right]$$

The result from Equation (6) captures whether DR adoption becomes more prevalent, less prevalent, or remains constant over time. This allows us to characterize what levels of x ₀ create a sufficiently large negative externality across the network to drive increased DR adoption. It also estimates what the new Nash Equilibrium level of DR seed adoption resulting from an externality for a given adoption rate. Details on steady-state characterization are found in Appendix A.

3.1. Relative Profitability DR Seed Adoption (Parameter K)

While a farmer can choose between soybean varieties, the reality of this highly concentrated market is that they will likely be choosing between two companies. As previously noted, about 86% of all 2020 soybean acres in the U.S. were planted with seed possessing genetic traits owned either by Bayer or Corteva (Reuters, 2020). However, only Bayer provides the gene for dicamba resistance. Thus, we make the simplification that there is one DR variety and one NR variety. This streamlines the problem with little loss in generality. While companies guard their yield data, talks with soybean farmers revealed that there is little perceived difference if any between the two seed types as long as fields remain unimpacted by OTM. This perception is corroborated by an agronomic study testing performance of various Xtend (that is, from Bayer, or “DR” in our notation) and Enlist (Corteva, “NR”) varieties across the state of Arkansas. Researchers found an average yield of 71.3 bu/acre for Xtend varieties and 71.0 bu/acre for non-Xtend (primarily Enlist) varieties (Carlin, Morgan, and Bond, Reference Carlin, Morgan and Bond2022).Footnote ⁵

Selling prices and production costs should also be comparable across these two different seed types. Midland, a soybean seed dealer, listed its suggested retail price for both Xtend and Enlist soybean seed to be $56.60 per 140,000 seeds for the 2021 season (Midland, 2020). Herbicide applications to Xtend soybean are typically a little more expensive than those to Enlist soybean, because additional volatility- and drift-reduction agents must be included in dicamba applications ($36.53/acre vs. $20.00/acre) (Kansas State Research and Extension, 2022).Footnote ⁶ We use a soybean crop budget to estimate the impact of yield losses on profitability (University of Missouri Extension, 2021).

While the aforementioned snapshots of various soybean seed yields and costs do not provide a definitive profit for each seed likely to be experienced by every farmer in all scenarios, they do suggest that the externality-free profit of DR and NR soybeans should be on average similar. Individual farmer experiences will vary depending upon production practices, seed- and herbicide-specific discounts retailers apply, as do fluctuating herbicide costs. To accommodate the fact that different traits could create slight differences in the yields, seed prices, or other intangible costs individual farmers experience, we model the ratio of these expected benefits experienced by everyone within a network to follow a distribution for the random variable K. To accomplish this, we assume a normal distribution with an expected value of this ratio equal to unity and a 10% standard deviation. We also run comparative statics on the mean of the distribution of K at 0.9 and 1.1. While we expect both seeds to provide similar externality-free payouts on average, it could be possible that DR seed provides higher expected average returns due to superior weed management with dicamba (mean $K=1.1$ ). It would also be possible that NR seed provides a higher average externality-free return due to lower herbicide cost or fewer application rules (mean $K=0.9$ ). Testing the distributional assumptions of K enriches the results of our baseline analysis ( $E[K]=1$ , ${\rm SD}[K]=0.1$ ) and provides detail on the impact of economic factors in influencing OTM damage and soybean seed adoption.

3.2. Dicamba Damage as a Function of Distance (Parameters f and g)

We used data from two experiment fields in Chariton and Dunklin Counties in Missouri between 2016 and 2017 to estimate yield damage as a function of distance from herbicide source. Soybeans in these fields were NR and were injured by dicamba OTM. The patterns of dicamba injury within the fields are consistent with primary dicamba drift, which occurs at the time of the herbicide application. Studies were designed at the sites specifically to quantify the impact of dicamba OTM on NR soybeans across various distances. Yield loss was estimated at 25-m intervals from the dicamba application area. We then estimated the damage for each field as a function of distance by fitting a curve to the data.

Figure 1 shows predicted soybean losses are high within 500 ft of herbicide application, but drop off quickly. Adjacent fields will be subject to considerable loss, but far enough away from DR plantings we would expect damages from OTM to be minimal. This result suggests that regions with high densities of soybean acreage (“dense networks”) are more likely to experience substantial losses from dicamba OTM. It is important to note that these field trials do not account for secondary drift, which occurs sometime after the herbicide application. Secondary drift covers a wider area, and it can be impossible to determine from whence the herbicide moved. This means our estimated losses are conservative: they do not include secondary drift damage, nor any damage to non-soybean plants (Dintelmann et al., Reference Dintelmann, Warmund, Bish and Bradley2020).

Figure 1. The loss in soybean yield of non-dicamba-resistant varieties as a function of distance. Field 1: (R ² = 0.4549, n = 419). Field 2: (R ² = 0.1711, n = 201). Data in Appendix B.

From here, we take the estimated relationship of yield loss as a function of distance and calculate the losses we expect a NR farmer with an 80-acre field (approximately 1,867 ft × 1,867 ft) would experience if one of the edges was adjacent to an 80-acre field of DR soybean treated with dicamba. We then summed damage as a function of distance for every square foot from the source to the edge of the field. Next, we multiplied that number by how many feet across a given field was. Finally, we averaged the yield loss for every 1 × 1 foot cell within the 80-acre model. This gives us the estimated yield loss associated with one neighbor using DR seed. We are able to estimate the loss for two or more neighbors by using the same process but adding in additional calculation for joint probabilities, which allows us to avoid double-counting OTM damage.

3.3. Estimating Network Structure for Soybean Farmers

One final factor that required estimation was the network structure of soybean farmers. We took county-level data for three representative counties within Missouri: Pemiscot, Cooper, and St. Genevieve. They represented high density, median density, and low density of soybean production within the state, with 55%, 17%, and 7% of respective total acreage for each county dedicated to soybean production (National Agriculture Census Data, 2021). This planting density influences network structure. We estimated the network structure of a given county using a Monte Carlo simulation which we explain in detail in Appendix C. The network structure influences the size of the externality farmers are exposed to, which in turn influences how many farmers switch to DR soybeans.

The number of neighbors bordering a field and the corresponding OTM damage varied considerably depending upon county-level grower density. Table 1 shows this impact of grower density on network structure and network induced damage on NR soybean growers if OTM follows the first field trial results. Results were similar but even more pronounced when we modeled after the second field trial (Appendix D). A quick comparison across yield losses and percent of a regional network with neighbors close enough for dicamba OTM to cause injury to NR varieties shows how much the magnitude of this problem can vary even within a given state.

Table 1. Network structure of soybean farmers under different planting densities (1^st field trial)

Once yield loss as a function of neighbors using DR seed was calculated (the parameter g), we applied these yield losses to the aforementioned crop budget to estimate the losses in profit resulting from a given yield loss (the parameter f). This means that the externality damage that each farmer growing NR seed is exposed to can be calculated for their given number of neighbors and the percentage of the network that has adopted DR seed.