Hostname: page-component-cd9895bd7-fscjk Total loading time: 0 Render date: 2024-12-26T20:01:36.442Z Has data issue: false hasContentIssue false

Does grazing winter cereal rye in Iowa, USA, make it profitable?

Published online by Cambridge University Press:  27 October 2023

A. Plastina*
Affiliation:
Department of Economics, Iowa State University, Ames, IA, USA
J. Acharya
Affiliation:
Department of Plant Pathology, Entomology, and Microbiology, Iowa State University, Ames, IA, USA
F. M. Marcos
Affiliation:
Department of Agronomy, Iowa State University, Ames, IA, USA
M. R. Parvej
Affiliation:
Department of Agronomy, Iowa State University, Ames, IA, USA Louisiana State University Ag Center, Scott Research & Extension Center, Winnsboro, LA, USA
M. A. Licht
Affiliation:
Department of Agronomy, Iowa State University, Ames, IA, USA
A. E. Robertson
Affiliation:
Department of Plant Pathology, Entomology, and Microbiology, Iowa State University, Ames, IA, USA
*
Corresponding author: A. Plastina; Email: plastina@iastate.edu
Rights & Permissions [Opens in a new window]

Abstract

Unproven economic returns at the farm level are a major barrier to large-scale adoption of cover crops. The objective of this study was to evaluate the short-run private net returns to producers implementing a cereal rye (Secale cereale L.) cover crop preceding the no-till corn (Zea mays L.) phase of a US Midwest corn–soybean (Glycine max [L.] Merr.) rotation in an integrated crop and cow–calf operation. We used experimental agronomic data from six location-years in Iowa to estimate private net returns to cereal rye across alternative scenarios in a partial budget framework. Net returns in the absence of grazing averaged −$123.74 ha−1 and were negative for 82.2% of the treatments, while net returns under partial grazing averaged −$15.24 ha−1 and were negative for 54.8% of the treatments. Early-broadcast cereal rye produced higher biomass and larger net cost savings in the livestock enterprise than late-drilled cereal rye, but it also resulted in higher corn yield penalties. In the no-grazing scenario, net losses for early-broadcast cereal rye were $165.97 ha−1 larger, on average, than for late-drilled cereal rye. Our findings should raise awareness about the low probability of obtaining positive annual private net returns to cereal rye in Iowa in the absence of sizable targeted financial incentives, and inform the policy discussion on the cost-effectiveness of government-sponsored conservation programs.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Despite the numerous environmental benefits associated with cover crop use, such as reducing erosion, improving infiltration, mitigating nutrient loading in surface waters, and improving soil health (Dabney, Delgado and Reeves, Reference Dabney, Delgado and Reeves2001; Kaspar, Radke and Laflen, Reference Kaspar, Radke and Laflen2001; Snapp et al., Reference Snapp, Swinton, Labarta, Mutch, Black, Leep, Nyiraneza and O'Neil2005; Tonitto, David and Drinkwater, Reference Tonitto, David and Drinkwater2006; Schnepf and Cox, Reference Schnepf and Cox2006; Kaspar and Singer, Reference Kaspar, Singer, Hatfield and Sauer2011), many farmers in the Midwestern United States are still reluctant to include cover crops in their production practices. Across four surveys (Werblow and Watts, Reference Werblow and Watts2013; Werblow and Myers, Reference Werblow and Myers2014, Reference Werblow and Myers2015, Reference Werblow and Myers2016), US farmers reported establishment, time or labor required, increased management, and species selection as the greatest challenges to using cover crops. The Iowa Farm and Rural Life Poll (Arbuckle, Reference Arbuckle2016) reported potential economic impacts had moderate-to-very strong influence on changes in 74% of producers' management practices, and 57% of them agreed with the statement ‘pressure to make profit margins makes it difficult to invest in conservation practices’.

In Iowa, which is the largest producer of corn (Zea mays L.) and second-largest producer of soybeans (Glycine max L.) in the United States, cover crops were implemented in 4% of all tillable area in 2017 (USDA, 2019a). While research on a wide range of winter-hardy cover crop species is ongoing, cereal rye (Secale cereale L.) is the only species documented to consistently grow well enough throughout Iowa to provide substantial water quality benefits. Yet, an ongoing concern for many farmers is that cover crops may reduce yields of the following cash crop (Arbuckle and Roesch-McNally, Reference Arbuckle and Roesch-McNally2015). A study of no-till plots in Iowa showed cereal rye reduced corn yields by 6% (Pantoja et al., Reference Pantoja, Woli, Sawyer and Barker2015). However, Marcillo and Miguez (Reference Marcillo and Miguez2017) concluded from a meta-analysis that cover crops did not generally reduce subsequent corn yields, particularly in the upper Midwest region. Martinez-Feria et al. (Reference Martinez-Feria, Dietzel, Liebman, Helmers and Archontoulis2016) did not find consistent corn yield declines following cover crops in Iowa, while Seifert, Azzari and Lobell (Reference Seifert, Azzari and Lobell2018, Reference Seifert, Azzari and Lobell2019) reported corn yield increases of 0.71% in the Midwest, based on satellite panel data. Small but statistically significant positive effects of cover crops on active carbon and soil stability in Midwestern states were reported by Wood and Bowman (Reference Wood and Bowman2021), but their economic implications were not evaluated. The peer-reviewed literature based on survey methods (Plastina et al., Reference Plastina, Liu, Miguez and Carlson2018a, Reference Plastina, Liu, Sawadgo, Miguez and Carlson2018b, Reference Plastina, Liu, Sawadgo, Miguez, Carlson and Marcillo2018c), field experiments (Thompson et al., Reference Thompson, Armstrong, Roth, Ruffatti and Reeling2020), and simulations from physical models (Marcillo et al., Reference Marcillo, Carlson, Filbert, Kaspar, Plastina and Miguez2019) concluded net returns to cover crops in the US Midwest were predominantly negative, even after accounting for cost-share payments.

Cover crop biomass in early spring can reduce an integrated production system's dependence on stored feed (Lundy, Loy and Bruene, Reference Lundy, Loy and Bruene2018; Phillips et al., Reference Phillips, Heins, Delate and Turnbull2019), and thus reduce feed costs. Furthermore, early spring cover crop biomass might allow for adjusting calving dates to optimize labor use and reduce the impact of mud at calving and calf scours (Sellers et al., Reference Sellers, Schwab, Arora, Clark, Dewell, Euken, Gunn, Lippolis, Loy, Lundy, Russell, Schulz, Shouse, Wall, Beenken, Harding, Holcomb, Jamison and Redifer2019). In 2019, cattle and calves in Iowa accounted for 14.3% of the state's total cash receipts from agricultural commodities and 5% of total cash receipts from cattle and calf production in the United States (USDA, 2021). According to Sellers et al. (Reference Sellers, Schwab, Arora, Clark, Dewell, Euken, Gunn, Lippolis, Loy, Lundy, Russell, Schulz, Shouse, Wall, Beenken, Harding, Holcomb, Jamison and Redifer2019), feed costs accounted, on average, for 63% of the direct costs of cow–calf production in Iowa, and stored feed represented 71% of feed costs. Despite the relevance of this livestock enterprise, the literature on feed cost savings stemming from grazing aboveground cover crop biomass is scant. A survey of Iowa farmers reported feed cost savings from grazing or harvesting cover crop biomass before corn ranging from $7.4 to $247.1 ha−1, and averaging $86.5 ha−1 (Plastina et al., Reference Plastina, Liu, Sawadgo, Miguez, Carlson and Marcillo2018c, p.24). A hypothetical harvest of cover crop biomass in Lexington, Illinois, would have generated $122.2 ha−1 in feedstuff value, on average (Thompson et al., Reference Thompson, Armstrong, Roth, Ruffatti and Reeling2020). However, the extra revenue would have been insufficient to offset the additional costs in the cropping system, leaving farmers with annual private losses of −$173.7 ha−1 in the absence of cost-share payments (Thompson et al., Reference Thompson, Armstrong, Roth, Ruffatti and Reeling2020). Furthermore, making hay with cereal rye biomass harvested in the early spring can be a major challenge in the US Midwest, given its high moisture content (Blanco-Canqui et al., Reference Blanco-Canqui, Ruis, Proctor, Creech, Drewnoski and Redfearn2020). Projected net returns to grazed cereal rye in the corn phase of a corn–soybean rotation in Iowa, based on a physically driven model of corn yields and cereal rye biomass, averaged −$30.5 ha−1 in the absence of cost-share payments and cereal rye termination costs, and −$64.0 ha−1 with termination costs (Marcillo et al., Reference Marcillo, Carlson, Filbert, Kaspar, Plastina and Miguez2019). Malone et al. (Reference Malone, O'Brien, Herbstritt, Emmett, Karlen, Kaspar, Kohler, Radke, Lence, Wu and Richard2022) suggested harvesting cereal rye for forage between mid-May and early June before planting soybeans in the north-central United States could be economically viable, particularly if producers did not observe soybean yield losses from the double-cropping alternative (Gesch, Archer and Berti, Reference Gesch, Archer and Berti2014; Nafziger et al., Reference Nafziger, Villamil, Niekamp, Iutzi and Davis2016).

The goal of the present study was to evaluate the annual private net returns to cereal rye as a winter cover crop in the no-till corn phase of an integrated corn–soybean and cow–calf system in Iowa. We conducted the evaluation in two stages. First, the net returns to cereal rye in the crop system were calculated using experimental agronomic data from Marcos et al. (Reference Marcos, Acharya, Parvej, Robertson and Licht2023) and local average prices in a partial budget framework. Partial budgets captured the differences between total profits from no-till corn production in fields planted to cereal rye in the fall, and total profits from no-till corn production in fields left fallow over the winter. Second, using data on cereal rye biomass collected from the experimental plots and local average prices, we simulated the hypothetical net cost savings from grazing cows in the cover-cropped fields for a typical cow–calf enterprise. We calculated the annual net returns to cereal rye in an integrated crop–livestock operation as the direct sum of the net returns in the crop system and the net cost savings in the cow–calf enterprise. Note that partial budgets captured short-term ‘direct’ effects of adding cereal rye to the crop rotation. We did not include ‘indirect’ benefits from cover crop use in our analysis, such as reduced soil erosion or nitrate loading from subsurface drainage (Roth et al., Reference Roth, Ruffatti, O'Rourke and Armstrong2018; Bergtold et al., Reference Bergtold, Ramsey, Maddy and Williams2017; Snapp et al., Reference Snapp, Swinton, Labarta, Mutch, Black, Leep, Nyiraneza and O'Neil2005), because they do not affect the private net returns to farming in the short-run.

The present study simulated private net returns to cereal rye by planting date and method, seeding rate, and termination date using experimental field data, and estimated feed cost savings from grazing cereal rye biomass in a cow–calf enterprise.

Materials and methods

Private net returns to cereal rye in no-till corn enterprise

Agronomic data from six location-years Marcos et al. (Reference Marcos, Acharya, Parvej, Robertson and Licht2023) and price data were used to evaluate the net returns to cereal rye preceding no-till corn in a partial budget framework. Treatment factors for the agronomic experiment included planting date-method, seeding rate, and target termination date. A comprehensive field study including all factors under analysis was implemented at a central Iowa research farm and supplemented with smaller studies at outlying research farms located in northwest and southeast Iowa. Each research farm is representative of a different soil type and weather pattern. Table 1 describes the main characteristics of the replicated treatments in each location-year. All treatment plots were 15.2 m long by 9.1 m wide.

Table 1. Commonalities in experimental design variables by location-year

Notes: NA, not applicable; DBP, days before planting; ^ control plots (no cereal rye) were also sprayed with the same chemicals to provide consistent exposure across treatment plots.

The comprehensive field study in central Iowa utilized a split-split-plot design with six replications. The main plot treatment was the cereal rye planting method: broadcast or drill. Following Iowa State University (ISU) recommendations (Conservation Learning Group, 2020), the subplot treatment was cereal rye target termination date: early and late termination dates targeted, respectively, 14 and 3 days before planting (DBP) corn. The sub-sub-plot treatment was seeding rate: high, medium, low, and zero. The seeding rates were 0.82, 1.65, and 2.47 million pure live seed (PLS) ha−1 for drilled cereal rye; and 1.65, 2.47, and 3.28 million PLS ha−1 for broadcast cereal rye. At the outlying farms, the three non-zero seeding rates were compared in the two seeding methods, but all treatments were terminated according to the 14 DBP target. Treatments were replicated six times at the outlying farms.

Cereal rye was established in mid-September in standing soybean (R7 growth stage; Pedersen and Licht, Reference Pedersen and Licht2014) for broadcast plots using a high clearance boom applicator. Soon after soybean harvest in mid to late October, drill plots were seeded in both 2019 and 2020 using a John Deere 750 10-feet no-till grain drill with a 19 cm row spacing. Since the different seeding dates have a confounding effect with the alternative planting methods, we refer to ‘early-broadcast’ vs ‘late-drill’ as our main seeding ‘date-method’ treatments in the remainder of the article. Early planting and late termination of cover crops has been associated with better establishment and biomass production (Ruis et al., Reference Ruis, Blanco-Canqui, Creech, Koehler-Cole, Elmore and Francis2019) and higher ecosystem services (Hively et al. (Reference Hively, Lang, McCarty, Keppler, Sadeghi and McConnell2009).

At all locations, May 1 was targeted as the ideal planting date for corn, but actual planting dates were affected by weather conditions. Consequently, cereal rye termination targeting 14 DBP actually occurred 19–39 DBP in 2019, and 10–13 DBP in 2020; while the 3 DBP target actually resulted in termination 13 DBP in 2019 and 2 DBP in 2020. Corn nitrogen management consisted of 168 kg N ha−1 applied mostly at the time of V4 to V6 corn stage (Abendroth et al., Reference Abendroth, Elmore, Boyer and Marlay2011), except for the southeast farm where a mistake by the field manager resulted in an application of 190.5 kg ha−1 in 2019. All locations utilized ISU recommendations for phosphorous and potassium fertilizer (Sawyer et al., Reference Sawyer, Nafziger, Randall, Bundy, Rehm and Joern2006; Mallarino, Sawyer and Barnhart, Reference Mallarino, Sawyer and Barnhart2013) as well as for weed management (Hodgson, Licht and Sisson, Reference Hodgson, Licht and Sisson2020). The agronomic data used for the present study include kg of cereal rye biomass in November and on the date of termination; as well as corn planting date, harvesting date, and yield. The full agronomic experiment is described in detail in Marcos et al. (Reference Marcos, Acharya, Parvej, Robertson and Licht2023).

Table 2 lists the relevant prices and costs from 2018 to 2020 used in our analysis. We estimated cereal rye seed costs using average prices paid by our project manager in 2018 and 2019. To estimate no-till planting costs at farm scale, we assumed machinery field efficiencies for broadcasting and drilling cereal rye seeds at 12.14 and 2.06 ha h−1, respectively (Hanna, Reference Hanna2016). The costs of purchased inputs for corn production reflect average prices from a number of specialized websites (e.g., https://farmtrade.com, https://ranchwholesale.com, https://fbn.com) and personal communications with input dealers in Iowa. We derived machinery and labor costs for the no-till corn phase from crop production budgets published by ISU (Plastina, Reference Plastina2018, Reference Plastina2019, Reference Plastina2020). While operators in Iowa are typically able to outsource multiple farm activities by hiring custom work, the present analysis assumed farm operators implemented all production activities with owned machinery. Since hiring custom work would typically be more expensive to farmers (because the service provider would have to recover the depreciation of their machinery and generate a profit margin), we consider our estimates optimistic and close to the upper bound of the actual distribution of net returns.

Table 2. Economic assumptions

Data on cereal rye biomass were collected in the fall during rye's vegetative dormancy period, and on the date of termination in the spring. We only collected fall samples for early-broadcast seeds because rye had emerged only in these treatments, but we collected spring samples for both planting date-methods. However, while in spring 2019 we sampled all plots as planned, changes in experimental field protocols during the spring of 2020 due to the COVID-19 pandemic resulted in only four out of six replications sampled for biomass in 2020. Since the northwest farm did not broadcast cereal rye seeds correctly in the fall of 2019, data on those early broadcast treatments were excluded from the analysis. Pandemic protocols were more lenient in the summer of 2020, and we collected corn yield data from all plots (even those not sampled in the spring).

We estimated net returns to cereal rye as the difference between total profits from no-till corn production preceded by cereal rye (treated plots) and total profits from no-till corn production in plots with no winter cover crops (untreated plots). Since we base our analysis on agronomic data collected from controlled field experiments, all field preparation, crop protection, and fertilization practices were identical across treated and untreated plots in each location-year. Hence, the only difference between treated and untreated plots affecting the calculation of private net returns per hectare (NR) were cereal rye planting costs (S), and differences in harvesting costs (ΔH) and corn revenue (ΔR):

(1)$$NR_{mra} = \Delta R_{mra}-\Delta H_{mra}-S_{mr}, \;$$

where m = {B ≡early-broadcast; D ≡late-drill} indexes planting date-methods; r = { L ≡low; M ≡medium; H ≡high} indexes seeding rates; and a = {3 DBP, 14 DBP} indexes target termination date. All economic assumptions were described in Table 2.

We calculated the difference in corn revenue as the product of the mean yield difference in metric tons per hectare (mt ha−1) between treated and untreated plots in each location-year, ΔY, and the corn price: ΔR = ΔY × $198.81 mt−1. The harvesting cost difference wascalculated as the product of the mean yield difference and the variable cost to haul corn from the field to on-farm storage, dry it to a 14% moisture level, and store it until sold: ΔH = ΔY × $8.15 mt−1.

Cereal rye planting costs were defined as a function of the seeding rate (srate) and the variable portion of machinery costs and labor costs specific to each seeding method (V m):

(2)$$S_{mr} = \$ 25.4065 \times srate_{mr} + V_m, \;$$

where $25.4065 = $25 bag−1 × 1,000,000 seeds/(22.68 kg bag−1 × 43,387 seeds kg−1); V B =  $5.50 ha−1 = $4.32 ha−1 + $14.33 h−1/12.14 ha h−1; and V D = $25.99 ha−1 = $19.03 ha−1 + $14.33 h−1/2.06 ha h−1. The seeding rates, in million seeds ha−1, were srate Br = {0.82, 1.65, 2.47} and srate Dr = {1.65, 2.47, 3.28}.

Private net cost savings in cow–calf enterprise

Cost savings from grazing cereal rye are highly dependent on the type of livestock, herd size, proximity of the feedlot to the field, and total available biomass. In Iowa, farms selling between 20 and 99 cattle and calves in 2017 sold an average of 47 heads per farm and accounted for 40% of all farms with sales of cattle and calves in the state (USDA, 2019a).

We focused on a typical Iowa cow–calf production system with 48 cows feeding on dry hay in a feedlot during winter and early spring. Furthermore, we assumed cereal rye was planted on 64.75 ha arranged in the shape of a square adjacent to the feedlot; that a removable electrified fence along the perimeter and a pre-owned and fully depreciated waterer were installed in the early spring and removed the day before rye termination. The temporary fence was assumed to consist of two lines of barbed wire held in place by removable T-shaped posts placed 6.1 m apart, and electrified with a solar electric fence charger. These assumptions were in line with our intention to generate upper bound estimates of net returns.

Private net cost savings in the cow–calf operation, NCS, were dependent onwith fencing costs, F, net daily labor savings, L, daily hay cost savings, H, and number of grazing days, G:

(3)$$NCS_{mra} = ( {L + H} ) \times G_{mra}-F.$$

We calculated annual fencing costs as the sum of (a) $11.31 ha−1 from the linear depreciation over four years of 425 T-shaped posts, 5180 m of barbed wire, and a solar electric fence charger; (b) $1.85 ha−1 in materials to repair the fence; and (c) $7.08 ha−1 for 32 h of labor to install and remove the electric fence and waterer each spring: F = $20.23 ha−1.

Net daily labor savings, L, were calculated as the saved labor from not feeding cows in the feedlot (2 h G −1) and not collecting, hauling, and spreading manure accumulated over the spring (0.22 h G −1), minus the extra labor hours spent repairing the fence (2 h week−1) and refilling the waterer (2 h week−1): L =$14.33 h−1 × 1.65 h G −1/64.75 ha = $0.37 ha−1 G −1.

Assuming each cow consumes 4% of its body weight (including spoilage) and their average weight is 567 kg, the daily target herd consumption, K, was 1.0886 mt of cereal rye biomass (i.e., K =1.0886 mt G −1). The calculation of daily hay cost savings, H, assumed hay dry matter at 84.5% of hay weight, and the price of hay at $147.16 mt−1: H =1.0886 mt G −1 × $147.16 mt−1 × 84.5%/64.75 ha−1 = $2.93 ha−1 G −1.

Although our field experiments collected rye biomass data at two points in time (at most), G varied with the amount of biomass available on each day of the spring. We estimated G for the 21 treatments with both fall and spring biomass data using a two-step approach. First, we calculated the average daily growth rate of the biomass, x, between the date when vegetative dormancy broke, d, and the spring sampling date, T, as

(4)$$x = ( {B^S/B^F} ) ^{d-T}-1, \;$$

where B S is spring biomass; B F is fall biomass; and the subscripts {m, r, a} were excluded for simplicity of exposition. This equation solves the following compounded growth equation relating the fall biomass to the spring biomass, B S = B F(1 + x)(Td), for observed B S, B F, T, and d. The break in vegetative dormancy was documented on April 3, 2019, and March 4, 2020, for all locations. Then, we estimated the number of grazing days as:

(5)$$G = \ln \left({\displaystyle{{64.75 \times x \times B^S} \over K} + 1} \right)-\ln ( {1 + x} ) , \;$$

where ln( ) indicates the natural logarithm of the expression inside the parenthesis. This equation solves the equality 64.75 × B S = K/x[(1 + x)G − 1], which requires that the target herd consumption volume, K, be available across the 64.75 ha each of the G days preceding termination date, subject to the restrictions that: (a) spring biomass be larger than or equal to the target herd consumption volume (i.e., 64.75 × B S ≥ K, otherwise G = 0); and (b) that the number of grazing days could not exceed the total number of days between the breaking of vegetative dormancy and termination (i.e., G ≤ (T − d)), otherwise, some grazing days would take place in the fall, which would reduce the soil and water quality benefits of cover cropping. Although the latter effect is beyond the scope of this study, the environmental benefits of cover crops are typically major drivers of the adoption decision. For the late-drilled treatments, the number of grazing days was estimated using the average daily growth rate of cereal rye, x, calculated for the early-broadcast-equivalent treatment (same location, year, seeding rate, and target termination date). Since we did not collect biomass data for broadcast cereal rye in the northwest farm in 2019/20, we excluded the northwest farm from the 2019/20 feed-cost savings analysis.

Private net returns to cereal rye in an integrated crop and cow–calf system

The net returns to cereal rye preceding no-till corn in an integrated cow–calf system, NRI, were calculated as the direct sum of net returns from the corn partial budget and the net cost savings from the livestock operation:

(6)$$\eqalign{\;NRI_{mra} & = NR_{mra} + NCS_{mra} = {\rm \$ }190.66 \cr & \quad \times \Delta Y_{mra}-S_{mr} + {\rm \$}3.30 \times G_{mra}-{\rm \$}20.23.} $$

NRI mra did not include a termination-cost-saving term because grazing is not an effective termination method for cover crops and rye was chemically terminated. We did not introduce adjustments to crop fertilization costs based on livestock manure left on soil surface while grazing, because volatile losses can reduce the fertilizer replacement value by as much as 85% (ISU Extension and Outreach, 2016). Recent research on short-term soil physical responses to grazing and cover crops in an integrated crop–livestock agroecosystem in South Dakota (Singh et al., Reference Singh, Kumar, Jin and Schneider2022) concluded grazing cover crops did not cause substantial compaction or physical damage to the soil. Consequently, in the absence of similar local guidelines for Iowa, we assumed that hoof activity from livestock grazing in the spring had no significant effect on subsequent corn yields. Depending on the assumptions regarding the effects of cereal rye on corn yields, and the amount of cereal rye biomass left in the field by termination date, we developed three scenarios: no-grazing, full-grazing, and partial-grazing.

No-grazing scenario

This scenario was used as the baseline to measure any gains from grazing cereal rye biomass since it excluded the net cost savings from the livestock enterprise. We measured net returns to cereal rye in the no-grazing scenario as $NRI_{mra}^{No} = NR_{mra}$.

Full-grazing scenario

We based the full-grazing scenario on naïve assumptions that optimal timing of grazing decisions secured full use of cereal biomass produced during the spring, $G_{mra}^{Full} \equiv G_{mra}$, and the agronomic effect of the fully grazed cereal rye on corn yields was null, ΔY mra = 0:

(7)$$NRI_{mra}^{Full} = {-}S_{mr} + \$ 3.30 \times G_{mra}^{Full} -\$ 20.23.$$

This scenario was only intended to serve as an extreme hypothetical benchmark and was the least plausible of the three scenarios.

Partial-grazing scenario

For the partial-grazing scenario, we assumed that 90% of B S was effectively grazed in the spring, leaving only 10% of the biomass on the field by termination date, B  = 0.1 × B S; and yield differences between treated and untreated plots were a function of B . Replacing B S by (1 − B ) in the equation for G and leaving all other variables unchanged, we calculated $G_{mra}^{Partial} \le G_{mra}^{Full}$.

Furthermore, we represented the statistical relationship between total cereal rye biomass at time of termination and percent corn yields differences between treated and untreated plots as

(8)$$\eqalign{\% \Delta Y_{mra} & = \alpha + \beta _1\ln ( {64.75 \times B_{mra}^S } ) ^{{-}1} \cr & \quad + \beta _2\ln ( {64.75 \times B_{mra}^S } ) ^{{-}2} + \mu _{mra}, \;} $$

where %ΔY mra was the observed percent difference between the average corn yield for treatment {m, r, a} and the average corn yield in the corresponding check plots; α, β 1, β 2 were the parameters of the model to be estimated; and, μ mra was a random disturbance with zero mean and finite variance.

We used the estimated parameters $\{ {\hat{\alpha }, \;\;{\hat{\beta }}_1, \;\;{\hat{\beta }}_2} \}$ and the residuals $u_{mra} = \% \Delta Y_{mra}-\hat{\alpha } + \hat{\beta }_1\ln ( {64.75 \times B_{mra}^S } ) ^{{-}1} + \hat{\beta }_2$ $\ln ( {64.75 \times B_{mra}^S } ) ^{{-}2}$ to project the percent difference in yields between treated and untreated plots for each level of $B_{mra}^{\prime}$ as follows:

(9)$$\eqalign{\widehat{{\% \Delta Y}}_{mra} & = \hat{\alpha } + {\hat{\beta }}_1\ln ( {64.75 \times B_{mra}^S } ) ^{{-}1} \cr & \quad + {\hat{\beta }}_2\ln ( {64.75 \times B_{mra}^S } ) ^{{-}2} + u_{mra}.} $$

Then, we derived the differences between treated and untreated plots using $\Delta \hat{Y}_{mra} = Y_{mra} \times \widehat{{\% {\rm \Delta }Y}}_{mra}$, where Y mra indicated the average corn yield in the check plots for treatment {m, r, a}. In summary, we calculated the net returns to cereal rye in the partial grazing scenario as:

(10)$$\eqalign{NRI_{mra}^{Partial} & = \$ 190.66 \times \Delta {\hat{Y}}_{mra}-S_{mr} \cr & \quad + \$ 3.30 \times G_{mra}^{Partial} -\$ 20.23.} $$

Results

We pooled observations across years (to emulate farmers' production uncertainty when deciding whether to plant cereal rye) and across locations (to maximize degrees of freedom in our statistical analyses). We evaluated treatment effects in each of the variables of interest within and across factors {m, r, a} applying analysis of variance (ANOVA) and adjusted P-values from Tukey's honestly significant difference tests with 95% family-wise confidence level in R Version 4.0.0. (R Core Team, 2017). Levene and Shapiro–Wilk tests were used to check for homogeneity of variance and normality of the residuals, respectively. When the hypothesis of normal residuals was rejected, we applied the non-parametric Kruskal–Wallis rank sum test (Hollander and Wolfe, Reference Hollander and Wolfe1973) to compare the location parameters of the distribution of an observed variable across groups.

No-grazing scenario

Corn yield differences between treated and check plots, ΔY, averaged −0.292 mt ha−1 across the 45 treatments (Table 3). ΔY averaged −0.760 mt ha−1 across the 29 treatments (64.4%) with ΔY < 0, and 0.555 mt ha−1 across the other 16 treatments (35.6%). While ΔY averaged 0.113 mt ha−1 across late-drilled plots, it averaged −0.755 mt ha−1 across early-broadcast plots. Furthermore, 90.5% of the early-broadcast plots showed ΔY < 0, but only 41.7% of the late-drilled plots did.

Table 3. Descriptive statistics of corn yield differences between treated and untreated plots, ΔY

Notes: B, early-broadcast; D, late-drill; L, low seeding rate; M, medium seeding rate; H, high seeding rate; 3 = target termination date 3 days before planting; 14 = target termination date 14 days before planting.

The mean corn yield difference between late-drilled plots and their corresponding check plots was 0.868 mt ha−1 higher than the mean corn yield difference between early-broadcast plots and their corresponding check plots (adj. P-value = 0.0015). While higher seeding rates and delayed termination were associated with more negative mean yield differences between treated and check plots (Table 3), those effects were not statistically significant in an ANOVA of ΔY.

Private net returns in the no-grazing scenario, NRI No, averaged −$123.74 ha−1 across the 45 treatments (Table 4). NRI No was negative for 37 treatments (82.2%), averaging −$174.88 ha−1, and positive for 18 treatments (17.8%), averaging $112.75 ha−1. Most of the negative net returns came from plots with early-broadcast cereal rye (20 vs 17 plots), which produced more biomass and suffered larger corn yield penalties than late-drilled plots, as discussed in the next subsection.

Table 4. Descriptive statistics of net returns to cereal rye in the no-grazing scenario, NRI No

Notes: B, early-broadcast; D, late-drill; L, low seeding rate; M, medium seeding rate; H, high seeding rate; 3 = target termination date 3 days before planting; 14 = target termination date 14 days before planting.

Net returns were $165.96 ha−1 less negative in late-drilled plots, on average, than in early-broadcast plots (adj. P-value = 0.0015), driven by corn yield differences across planting date-methods (Table 4). The average net loss across early-broadcast plots where NRI No < 0 was almost twice in magnitude as the average net loss across late-drilled plots where NRI No < 0: −$223.52 vs −$117.65 ha−1. Slightly less than one-third of the late-drilled plots (29.2%) had positive NRI No and averaged $127.01 ha−1.

Full-grazing scenario

The estimated number of grazing days for 48 lactating cows across 64.75 ha planted to cereal rye ranged from 2.4 to 50.7 days, and averaged 18.0 days, based on a mean biomass availability of 0.870 mt ha−1 on termination date (Table 5).

Table 5. Descriptive statistics of spring biomass, B S, and grazing days in the full-grazing scenario, G Full

Notes: B, early-broadcast; D, late-drill; L, low seeding rate; M, medium seeding rate; H, high seeding rate; 3 = target termination date 3 days before planting; 14 = target termination date 14 days before planting; ^ 2019/20 treatments in the northwest farm were excluded due to the unavailability of biomass data.

Due to high correlation between biomass and grazing days (Pearson correlation coefficient = 0.6589), we measured the treatment effects on the former (observed) variable. Furthermore, since the Shapiro–Wilk (P-value = 0.020) test and the Levene test for homogeneity of variance (P-value < 0.001) rejected normality of the ANOVA residuals, we evaluated the treatment effects on B S with the Kruskal–Wallis rank-sum test (Table 6). Planting date-method, termination date, their interaction, and the interaction between planting date-method and seeding rate had statistically significant effects on biomass availability. Biomass in early-broadcast plots was, on average, 1.1 mt ha−1 higher (P-value < 0.001) than in late-drilled plots (Table 5). A target termination date of 3 DBP was associated with an extra 0.9 mt ha−1 of rye biomass (P-value = 0.055) than a target termination date of 14 DBP. The difference in mean biomass produced across early-broadcasting and late-planting is significantly higher (P-value < 0.001) for a 3 DBP target termination date (2.3 mt ha−1) than for a 14 DBP target termination date (0.6 mt ha−1). Termination date was the only factor with a statistically significant effect on the variability of biomass across early-broadcast plots (P-value = 0.005): a 3 DBP target termination date was associated with 1.8 mt ha−1 higher biomass than a 14 DBP target termination date. Seeding rates had a relatively larger effect on biomass in late-drilled than in early-broadcast plots (P-value = 0.002): the mean biomass differences between high seeding rates and low seeding rates were 0.2 mt ha−1 for late-drilled rye and 0.1 mt ha−1 for early-broadcast rye.

Table 6. Kruskal–Wallis rank-sum tests on spring biomass, B S

Notes: Significance codes: ‘***’ 0.001; ‘**’ 0.01; ‘*’ 0.05; ‘.’ 0.1.

As shown in the last four columns of Table 5, early-broadcast plots produced 14.6 more grazing days than late-drilled plots (25.3 vs 10.7 days), on average, and a 3 DBP target termination date was associated with 8.8 extra grazing days over a 14 DBP target termination date (24.3 vs 15.5 days). Early-broadcast plots with a 3 DBP target termination date produced the largest number of grazing days (35.5 days) among the four possible combinations of planting date-methods and termination dates, while late-drilled plots with a 14 DBP termination date produced the lowest number of grazing days (9.8 days). On late-drilled plots, high seeding rates produced, on average, 4.9 extra grazing days than low seeding rates (13.1 vs 8.2 grazing days with 3.28 vs 1.65 million seeds ha−1, respectively); but the difference was only 3.4 extra grazing days on early-broadcast plots (27.0 vs 23.6 grazing days with 2.47 vs 0.82 million seeds ha−1, respectively). Appendix Table A4 reports the information used to calculate grazing days by treatment in the full-grazing scenario.

Net cost savings in the cow–calf enterprise, NCS, ranged from −$12.21 to $146.69 ha−1, and averaged $39.15 ha−1 (Appendix Table A5). In 35 out of 42 treatments, or 83.3% of the time, the estimated cost savings from grazing cereal rye more than offset the extra fencing costs, resulting in net cost savings to the cow–calf operation. All the early-broadcast plots and two-thirds of the late-drilled plots experienced net cost savings (averaging $63.22 and $25.90 ha−1, respectively), and only one-third of the late-drilled plots experienced extra net costs (averaging −$6.57 ha−1).

Private net returns to cereal rye in the full-grazing scenario, NRI Full, averaged −$28.91 ha−1 across all treatments, and −$45.27 ha−1 for 34 out of 42 treatments (81.0%) with NRI Full < 0 (Table 7). The average net return for the remaining 19.0% of treatments where NRI Full > 0 was $40.66 ha−1. All but one of the late-drilled plots and two-thirds of the early-broadcast plots experienced negative net returns, averaging −$55.47 and −$30.70 ha−1, respectively. Only one late-drilled plot and one-third of the early-broadcast plots obtained positive net returns, averaging $1.76 and $46.22 ha−1, respectively.

Table 7. Descriptive statistics of net returns to cereal rye in the full-grazing scenario, NRI Full

Notes: B, early-broadcast; D, late-drill; L, low seeding rate; M, medium seeding rate; H, high seeding rate; 3 = target termination date 3 days before planting; 14 = target termination date 14 days before planting.

For the subset of early-broadcast plots, only termination date had a marginally statistically significant effect on net returns (P-value = 0.062): plots with a 3 DBP termination date obtained a $46.71 ha−1 higher average net return than plots with a 14 DBP termination date ($28.30 vs −$18.41 ha−1); and, while only 20% of the treated plots obtained positive net returns in the latter group, two-thirds of the plots in the former group did.

For the subset of late-drilled plots, only seeding rate had a negative and marginally statistically significant effect on net returns (P-value = 0.081): the higher the seeding rate, the more negative the net returns to late-drilled cereal rye.

Partial-grazing scenario

On average, across all treatments, the number of grazing days in the partial-grazing scenario was slightly less than one day (0.92) lower than in the full-grazing scenario. The fitted model from Equation (8) was statistically significant (F-statistic P-value < 0.001) and explained 30.87% of the variability in %ΔY (Table 8). As shown in Figure 1, the fitted percent difference in corn yields between treated and untreated plots was positive for low levels of spring biomass (following an increasing and then decreasing pattern) and then turned negative (and increasingly so) for higher levels of spring biomass. We obtained the projected percent corn yield difference for each (unobserved) level of spring biomass in the partial-grazing model,$\;\widehat{{\% {\rm \Delta }Y}}_{mra}$, using the estimated coefficients from Table 8 and substituting $B_{mra}^S$ for $B_{mra}^{\prime}$ and u mra for μ mra in the statistical model. To avoid using the estimated model to predict values of the independent variable outside of the observed range of dependent variables, we imposed the condition that $\;\widehat{{\% {\rm \Delta }Y}}_{mra} = {\rm \;}u_{mra}$ when $( {1-B_{mra}^{\prime} } ) < \min ( {B^S} ) = 42.61$ kg ha−1 of dry matter. In other words, we assumed when the biomass left in the field on termination date (not grazed) was very small, cereal rye did not affect corn yields in the treated plot and any difference between corn yields in the treated plot and the check plot was caused by variables other than cereal rye biomass. This condition was binding for 19 treatments.

Table 8. Statistical model of percent change in corn yield differences between treated and untreated plots, %ΔY

Notes: Significance codes: ‘***’ 0.001; ‘**’ 0.01; ‘*’ 0.05; ‘.’ 0.1. Residual standard error: 6.799 on 42 degrees of freedom. Multiple R 2: 0.3083, F-statistic: 9.358 on 2 and 42 DF, P-value: 0.0004354.

Figure 1. Fitted and observed percent changes in corn yield differences, %ΔY, vs total field biomass, ln (64.75 × B S).

The projected yield differences,$\Delta \hat{Y}_{mra}$, obtained by multiplying corn yield in the corresponding check plot by $\widehat{{\% {\rm \Delta }Y}}_{mra}$, were, on average, 0.410 mt ha−1 higher than under the no-grazing scenario. Eighteen treatments experienced a 0.219 mt ha−1 yield decline, and 24 treatments experienced a 0.883 mt ha−1 yield increase in the partial-grazing scenario, on average, with respect to the no-grazing scenario (Appendix Table A6).

Net returns in the partial-grazing scenario, NRI Partial, averaged −$15.24 ha−1 across all treatments (Table 9), and were, on average, $13.66 ha−1 less negative than NRI Full and $108.50 ha−1 less negative than NRI No. However, dispersion of net returns around the mean (measured by the coefficient of variation, CV) in the partial-grazing scenario was higher than in the full-grazing and no-grazing scenarios (CVs of 9.40 vs 1.51 and 1.40, respectively). The average net return across the 23 treatments where NRI Partial < 0 amounted to −$116.27 ha−1, which was $58.61 ha−1 less negative than for treatments where NRI No < 0, but $71.00 ha−1 more negative than the treatments where NRI Full < 0.

Table 9. Descriptive statistics of net returns to cereal rye in the partial-grazing scenario, NRI Partial

Notes: B, early-broadcast; D, late-drill; L, low seeding rate; M, medium seeding rate; H, high seeding rate; 3 = target termination date 3 days before planting; 14 = target termination date 14 days before planting.

The average net return across the 19 treatments where NRI Partial > 0 amounted to $107.05 ha−1, which was $5.70 ha−1 lower than for the treatments where NRI No > 0, and $66.39 ha−1 higher than the treatments where NRI Full > 0. No statistically significant differences were found in NRI Partial across agronomic treatments.

Slightly more than half of the early-broadcast plots (52.4%) obtained positive net returns to cereal rye, averaging $98.15 ha−1, while only 38.1% of the late-drilled plots did, averaging $110.30 ha−1. A higher biomass availability in the spring generated with lower planting costs in the early-broadcast plots resulted in more economical grazing days and a higher probability of breaking-even than in late-drilled plots.

Discussion

Effects of farming practices on private net returns to cereal rye

Our findings have multiple implications for farm management. First, the statistical relationship between higher cereal rye biomass in the spring and lower subsequent corn yields showcases the trade-off faced by farmers between producing higher environmental services and incurring economic losses. Private net returns to cereal rye in the no-grazing scenario were negative for 82.2% of the treatments and averaged −$174.88 ha−1 for those treatments. In the absence of large financial incentives (subsidies, cost-share payments, or payments for ecosystem services) our findings suggest cover crops will not be adopted at large scale in Iowa.

Second, average net returns were significantly less negative in late-drilled plots than in early-broadcast plots in the no-grazing scenario, as higher rye biomass negatively affected corn yields relatively more in the latter than in the former plots. This suggests Iowa farmers would be more likely to break even if the planting date-method combination could be adjusted to achieve their environmental goals while minimizing corn yield losses. Late-broadcasting cereal rye (which was not explored in this study) could produce similar or even higher net returns than late-drilling, given the lower expenses associated with the former planting method.

Third, since seeding rates and target termination dates were not statistically significant factors affecting net returns to cereal rye in the no-grazing scenario, farmers could benefit from further research exploring the use of lower seeding rates and flexible termination dates to minimize costs subject to achieving their environmental goals. Marcillo et al. (Reference Marcillo, Carlson, Filbert, Kaspar, Plastina and Miguez2019) reported less negative private net returns to cereal rye at lower seeding rates.

Fourth, our finding that 45.2% of the plots under partial grazing obtained average net returns of $107.05 ha−1 suggests that cereal rye could be profitable to a sizeable share of the integrated row–crop and cow–calf production systems in Iowa when the rye biomass is used as forage. Figure 2 illustrates the relation between NRI Partial and total biomass produced by termination date (both grazed and left in the field). It seems to suggest that in order to be profitable while providing ground cover and its associated environmental benefits, cereal rye had to produce a total biomass of at least 2 mt ha−1 and possibly 3 mt ha−1 by termination date. However, this is a testable hypothesis that should be further explored with a larger sample size.

Figure 2. Net returns to partial grazing versus total biomass produced by termination date (grazed and left in the field).

Finally, our methodology could serve as the basis for future research to develop local guidelines to maximize private net returns to cereal rye in integrated crop and livestock systems, with expanded models also accounting for forage quality, actual herd behavior and associated weight gain, soil compaction issues, manure quantity and quality during grazing. For example, while cereal rye can be a very high-quality forage for cattle when grazed appropriately, farmers should be aware of local risks for grass tetany, ergot poisoning, and nitrate toxicity (Iowa Beef Center, 2018), as well as herbicide carry over from the soybean phase of the crop rotation (Hartzler, Anderson and Vittetoe, Reference Hartzler, Anderson and Vittetoe2017).

Cost-share programs and social net returns to cereal rye

Our findings also have multiple implications for policy analysis. Since the USDA considers grazing livestock on cereal rye a good farming practice in Iowa, implementing this practice does not impact farmers' ability to receive government payments or subsidies or their amounts (USDA, 2019b). If the average incentive of $83.59 ha−1 from the USDA Environmental Quality Incentives Program (EQIP) to plant cereal rye in Iowa (Sawadgo and Plastina, Reference Sawadgo and Plastina2018; Myers, Weber and Tellatin, Reference Myers, Weber and Tellatin2019) had been applied to all treated farms in our analysis, the percent of plots that would have generated positive net returns in the no-grazing scenario would have increased from 17.8 to 42.2%. While this seems like a substantial achievement, it is relevant to highlight that even under such a generous incentive, 57.8% of the treatments would have incurred annual net losses. Even after doubling the cost-share incentive to $167.19 ha−1, 37.8% of the treatments would have not broken-even in the no-grazing scenario. In the partial-grazing scenario, cost-share incentives to plant cereal rye of $83.59 and $167.19 ha−1 would have brought the share of profitable farms to 69.0 and 90.5%, respectively.

Additionally, it is important to consider the differential impact of the same EQIP incentive across high- vs low-biomass producing practices, conceptually represented in our study through late-drilled vs early-broadcast plots, respectively. In the no-grazing scenario, 66.7% of the plots with low-biomass and 14.3% of the plots with high-biomass would have obtained positive net returns after receiving EQIP payments. This comparison should inform policy discussions on the cost-effectiveness of public programs to achieve environmental goals, and induce research on the social net returns to alternative cover cropping methods targeting high-biomass production.

Under partial grazing, the differential impact of an $83.59 ha−1 EQIP payment on private net returns across high- vs low-biomass plots would have been much smaller: 66.7% of the low-biomass plots and 71.4% of the high-biomass plots would have obtained positive private net returns. However, further research is still needed to understand the social net returns to cereal rye planted for forage.

Other variables affecting net returns to cereal rye

Several caveats apply to our analysis. First, despite the large number of data points from experimental plots (324 observations), our analysis relied on homogeneous economic variables across location-years. While this seemed appropriate to evaluate the differential effects of agronomic practices on annual private net returns to cereal rye, our results might overstate the percent of treatments that would have generated losses to real farming operations, simply because farmers who anticipate losses might not plant cover crops.

Second, we relied on a fixed combination of herd size and area planted to cereal rye to estimate private net returns that were representative of a sizable portion of integrated farms in Iowa. Since the relationships between herd size, planted area, and net returns are non-linear, further analysis beyond the scope of this study would be required to develop practical guidelines to optimize the addition of cereal rye to integrated crop–livestock systems.

Third, while we incorporated fixed fencing costs into the analysis, we did not incorporate the opportunity cost of capital associated with the fencing equipment and the planting of 64.75 ha of cereal rye. This was an intentional choice to estimate the upper bound of net returns to cereal rye. Adding opportunity costs to our study will only reduce the calculated net returns.

Fourth, we calculated net returns to cereal rye only for no-till corn due to its higher environmental desirability than conventional tillage. However, no-till only accounts for 31% of tillable cropland in Iowa (USDA, 2019a). The net returns to simultaneously shifting from a conventional tillage system with fallow land in winter to a no-till system with winter cover crops could become positive if savings from tillage practices (elimination of chisel plow, deep rip, and moldboard plow) offset the negative net returns to cereal rye. Al-Kaisi et al. (Reference Al-Kaisi, Archontoulis, Kwaw-Mensah and Miguez2015) found that no-till corn and soybean systems in Iowa were consistently less profitable across 7 locations, 10 years, and multiple rotations, than their conventional counterparts. Deines et al. (Reference Deines, Guan, Lopez, Zhou, White, Wang and Lobell2023) reported that cover cropping practices implemented across the US Corn Belt caused average corn and soybeans yield losses of 5.5 and 3.5%, respectively, in 2019–2020.

Fifth, cereal rye planting dates and methods had confounded effects in our study. Future research including full factorial designs of planting dates (early and late) and methods (broadcast and drill) should help identify their separate unique effects.

Experimental vs survey data

The major advantages of our experimental approach over survey-based studies are that all agronomic practices were strictly controlled and documented (eliminating the noise from recollection of information by respondents) and plot characteristics were observable to researchers. In comparison, survey data are typically subject to sample selection bias, rely on farmers' recollections of costs and implemented practices, and pool responses across potentially different farms and production systems.

However, advantages of our experimental approach came at the expense of excluding behavioral responses to weather events, market trends, and other variables that affect profitability in real life. Additionally, our analysis relied on agronomic data obtained from small experimental plots that we extrapolated to a per-hectare basis.

Finally, our study did not consider fertilizing cereal rye, as proposed by Malone et al. (Reference Malone, O'Brien, Herbstritt, Emmett, Karlen, Kaspar, Kohler, Radke, Lence, Wu and Richard2022) for double-cropping soybean with cereal rye and mechanically harvesting the cereal rye biomass for hay. Potential extensions of our research include fertilization of cereal rye with a combination of manure and commercial fertilizers in the fall, and harvesting rather than grazing cereal rye biomass.

Conclusion

On a two-year study across three locations in Iowa, we found that in the absence of grazing, planting cereal rye as a cover crop followed by no-till corn was very likely to generate negative private net returns, averaging −$123.74 ha−1.

While early-broadcasting was less costly than late-drilling cereal rye, it produced more biomass, negatively affecting subsequent corn yields and private net returns in the no-grazing scenario. Net losses in early-broadcast plots were $165.96 ha−1 more negative, on average, than net losses in late-drilled plots in the absence of grazing. Since seeding rate and termination date did not have significant effects on private net returns in the no-grazing scenario, further research should be undertaken to assess the cost-effectiveness of alternative cover cropping practices to achieve desirable environmental effects at minimum cost.

In the partial grazing scenario, a higher availability of rye biomass during the spring was associated with higher private cost savings in the livestock enterprise, and lower amounts of rye biomass left on the field prior to corn planting resulted in improved corn yields with respect to the no-grazing scenario. Consequently, mean private net returns to cereal rye were less negative in the partial-grazing scenario than in the no-grazing scenario, and the likelihood of obtaining positive net returns in the former was more than twice the likelihood in the latter scenario (45.2 vs 17.8%). However, even in the more favorable scenario, average private net returns to cereal rye were negative at −$15.24 ha−1.

Our findings should inform farmers, advisors, extension specialists, researchers, and policy makers about the low probability of consistently obtaining positive annual private net returns to cereal rye in Iowa in the absence of substantial targeted financial incentives, even in an integrated crop–livestock operation. Further research should evaluate whether the environmental benefits from scaling-up the use of cereal rye as a winter cover crop would justify larger financial incentives for cereal rye adoption, and whether our results hold under agronomic trials that included actual rather than simulated grazing effects.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1742170523000388.

Acknowledgements

The authors are grateful to Timothy Christensen for providing valuable guidance on livestock production methods.

Author contributions

Plastina conducted the economic analysis using agronomic data collected by Acharya, Marcos, Parvej, Licht, and Robertson. Plastina developed the manuscript with feedback from Licht and Robertson.

Funding statement

Primary financial support for this research was provided by the Iowa Nutrient Research Center award #201812. The research was also facilitated by the Iowa Agriculture and Home Economics Experiment Station, Ames, Iowa, which is supported by USDA/NIFA and State of Iowa funds: IOW03908 (Phytobiomes in Crop Health and Disease Management), IOW04614 (Predicting Genotype by Management by Environment Interactions Across Scales), IOW03809 (Economics of the Food Sector: Consumption, Production, Trade and Marketing), and IOW04009 (Economics of the Food Chain: Uncertainty, Environment, Consumption, Production, Marketing and Trade). The Iowa Nutrient Research Center and USDA/NIFA had no role in the design, analysis, or writing of this article.

Competing interests

None.

References

Abendroth, L.J., Elmore, R.W., Boyer, M.J. and Marlay, S.K. (2011) Corn growth and development. PMR 1009. Ames, IA: Iowa State University Extension. Available at: https://store.extension.iastate.edu/product/Corn-Growthand-DevelopmentGoogle Scholar
Al-Kaisi, M.M., Archontoulis, S.V., Kwaw-Mensah, D. and Miguez, F. (2015) ‘Tillage and crop rotation effects on corn agronomic response and economic return at seven Iowa locations’, Agronomy Journal, 107, pp. 1411–24. https://doi.org/10.2134/agronj14.0470CrossRefGoogle Scholar
Arbuckle, J.G. (2016) 2015 summary report – Iowa farm and rural life poll. Ames, IA: Iowa State University Extension and Outreach PM 3075. https://doi.org/10.37578/OJJY9623CrossRefGoogle Scholar
Arbuckle, J.G. Jr. and Roesch-McNally, G.E. (2015) ‘Cover crop adoption in Iowa: the role of perceived practice characteristics’, Journal of Soil and Water Conservation, 70(6), pp. 418–29. https://doi.org/10.2489/jswc.70.6.418CrossRefGoogle Scholar
Bergtold, J.S., Ramsey, S., Maddy, L. and Williams, J.R. (2017) ‘A review of economic considerations for cover crops as a conservation practice’, Renewable Agriculture Food System, 34, pp. 115. https://doi.org/10.1017/S1742170517000278Google Scholar
Blanco-Canqui, H., Ruis, S.J., Proctor, C.A., Creech, C.F., Drewnoski, M.E. and Redfearn, D.D. (2020) ‘Harvesting cover crops for biofuel and livestock production: another ecosystem service?’, Agronomy Journal, 112, pp. 2373–400. https://doi.org/10.1002/agj2.20165CrossRefGoogle Scholar
Conservation Learning Group. (2020) Whole farm conservation best practices manual. Iowa state university extension and outreach, CLG105. Ames, IA: Iowa State University. Available at: https://store.extension.iastate.edu/product/15823Google Scholar
Dabney, S.M., Delgado, J.A. and Reeves, D.W. (2001) ‘Using winter cover crops to improve soil and water quality’, Communications in Soil Science and Plant Analysis, 32, pp. 1221–50.CrossRefGoogle Scholar
Deines, J.M., Guan, K., Lopez, B., Zhou, Q., White, C.S., Wang, S. and Lobell, D.B. (2023) ‘Recent cover crop adoption is associated with small maize and soybean yield losses in the United States’, Global Change Biology, 29, 794807. https://doi.org/10.1111/gcb.16489CrossRefGoogle ScholarPubMed
Gesch, R.W., Archer, D.W. and Berti, M.T. (2014) ‘Dual cropping winter camelina with soybean in the northern corn belt’, Agronomy Journal, 106, pp. 1735–45.CrossRefGoogle Scholar
Hanna, M. (2016) Estimating the field capacity of farm machines. Ames, IA: Iowa State University Ag Decision Maker File A3-24. Available at: https://www.extension.iastate.edu/agdm/crops/pdf/a3-24.pdfGoogle Scholar
Hartzler, B., Anderson, M. and Vittetoe, R. (2017) Herbicide use may restrict grazing options for cover crops. Ames, IA: Iowa State University Extension and Outreach, CROP 3082A, January.Google Scholar
Hively, W.D., Lang, M., McCarty, G.W., Keppler, J., Sadeghi, A. and McConnell, L.L. (2009) ‘Using satellite remote sensing to estimate winter cover crop nutrient uptake efficiency’, Journal of Soil and Water Conservation, 64(5), pp. 303–13. https://doi.org/10.2489/jswc.64.5.303CrossRefGoogle Scholar
Hodgson, E., Licht, M.A. and Sisson, A.J. (2020) Field crop production handbook. Ames, IA: Iowa State University Extension and Outreach. Available at: https://store.extension.iastate.edu/product/Field-Crop-Production-HandbookGoogle Scholar
Hollander, M. and Wolfe, D.A. (1973) Nonparametric statistical methods. New York: John Wiley & Sons.Google Scholar
Iowa Beef Center. (2018) Managing cattle health issues when grazing cover crops. Ames, IA: Iowa State University Extension and Outreach, IBD 0129, August.Google Scholar
Iowa State University Extension and Outreach. (2016) Using manure nutrients for crop production. Ames, IA: Iowa State University Extension and Outreach. PMR 1003, May.Google Scholar
Kaspar, T.C., Radke, J.K. and Laflen, J.M. (2001) ‘Small grain cover crops and wheel traffic effects on infiltration, runoff, and erosion’, Journal of Soil and Water Conservation, 56, pp. 160–4.Google Scholar
Kaspar, T.C. and Singer, J.W. (2011) ‘The use of cover crops to manage soil’ in Hatfield, J.L. and Sauer, T.J. (eds.) Soil management: building a stable base for agriculture. Madison, WA: American Society of Agronomy and Soil Science Society, pp. 321–37.Google Scholar
Lundy, E.L., Loy, D.D. and Bruene, D. (2018) ‘Performance comparison of fall-calving cow-calf pairs grazing cover crops vs. traditional Drylot system’, Iowa State University Animal Industry Report, 15(1), pp. 12. https://doi.org/10.31274/ans_air-180814-568Google Scholar
Mallarino, A., Sawyer, J. and Barnhart, S. (2013) A general guide for crop nutrient and limestone recommendations in Iowa. Iowa state university extension and outreach, PM1688. Ames, IA: Iowa State University.Google Scholar
Malone, R.W., O'Brien, P.L., Herbstritt, S., Emmett, B.D., Karlen, D.L., Kaspar, T.C., Kohler, K., Radke, A., Lence, S.H., Wu, H. and Richard, T.L. (2022) ‘Rye–soybean double-crop: planting method and N fertilization effects in the north central US’, Renewable Agriculture and Food Systems, 37(5), pp. 445–56. https://doi.org/10.1017/S1742170522000096CrossRefGoogle Scholar
Marcillo, G.S., Carlson, S., Filbert, M., Kaspar, T., Plastina, A. and Miguez, F.E. (2019) ‘Maize system impacts of cover crop management decisions: a simulation analysis of rye biomass response to planting populations in Iowa, U.S.A’, Agricultural Systems, 176, 102651. https://doi.org/10.1016/j.agsy.2019.102651CrossRefGoogle Scholar
Marcillo, G.S. and Miguez, F.E. (2017) ‘Corn yield response to winter cover crops: an updated meta-analysis’, Journal of Soil and Water Conservation, 72(3), pp. 226–39. https://doi.org/10.2489/jswc.72.3.226CrossRefGoogle Scholar
Marcos, F.M., Acharya, J., Parvej, M.R., Robertson, A.E. and Licht, M.A. (2023). ‘Cereal rye cover crop seeding method, seeding rate, and termination timing effects corn development and seedling disease’, Agronomy Journal, 115, pp. 1356–72. https://doi.org/10.1002/agj2.21306CrossRefGoogle Scholar
Martinez-Feria, R.A., Dietzel, R., Liebman, M., Helmers, M.J. and Archontoulis, S.V. (2016) ‘Rye cover crop effects on maize: a system-level analysis’, Field Crops Research, 196, pp. 145–59.CrossRefGoogle Scholar
Myers, R., Weber, A. and Tellatin, S. (2019) Cover crop economics: opportunities to improve your bottom line in row crops. College Park, MD: SARE Ag Innovation Series Technical Bulletin. 24p. June.Google Scholar
Nafziger, E.D., Villamil, M.B., Niekamp, J., Iutzi, F.W. and Davis, V.M. (2016) ‘Bioenergy yields of several cropping systems in the U.S. corn belt’, Agronomy Journal, 108, pp. 559–65.CrossRefGoogle Scholar
Pantoja, J.L., Woli, K.P., Sawyer, J.E. and Barker, D.W. (2015) ‘Corn nitrogen fertilization requirement and corn–soybean productivity with a rye cover crop’, Soil Science Society of America Journal, 79, pp. 1482–95. https://doi.org/10.2136/sssaj2015.02.0084CrossRefGoogle Scholar
Pedersen, P. and Licht, M.A. (2014) Soybean growth and development. PM 1945. Ames, IA: Iowa State University Extension and Outreach.Google Scholar
Phillips, H.N., Heins, B.J., Delate, K. and Turnbull, R. (2019) ‘Biomass yield and nutritive value of rye (Secale cereale L.) and wheat (Triticum aestivum L.) forages while grazed by cattle’, Crops 1(2), pp. 4254. https://doi.org/10.3390/crops1020006CrossRefGoogle Scholar
Plastina, A. (2018) Estimated costs of crop production in Iowa. Ames, IA: Iowa State University Ag Decision Maker File A1-20. Available at: https://www.extension.iastate.edu/agdm/crops/pdf/a1-20_2018.pdfGoogle Scholar
Plastina, A. (2019) Estimated costs of crop production in Iowa. Ames, IA: Iowa State University Ag Decision Maker File A1-20. Available at: https://www.extension.iastate.edu/agdm/crops/pdf/a1-20-2019.pdfGoogle Scholar
Plastina, A. (2020) Estimated costs of crop production in Iowa. Ames, IA: Iowa State University Ag Decision Maker File A1-20. Available at: https://www.extension.iastate.edu/agdm/crops/pdf/a1-20-2020.pdfGoogle Scholar
Plastina, A., Liu, F., Miguez, F. and Carlson, S. (2018a) ‘Cover crops use in Midwestern U.S. agriculture: perceived benefits and net returns’, Renewable Agriculture and Food Systems, 35, pp. 3848. https://doi.org/10.1017/S1742170518000194CrossRefGoogle Scholar
Plastina, A., Liu, F., Sawadgo, W., Miguez, F. and Carlson, S. (2018b) ‘Partial budgets for cover crops in Midwest row crop farming’, Journal of the American Society of Farm Managers and Rural Appraisers, pp. 90106.Google Scholar
Plastina, A., Liu, F., Sawadgo, W., Miguez, F.E., Carlson, S. and Marcillo, G. (2018c) ‘Annual net returns to cover crops in Iowa’, Journal of Applied Farm Economics, 2(2), p. 24. https://docs.lib.purdue.edu/jafe/vol2/iss2/2/CrossRefGoogle Scholar
R Core Team. (2017) R: a language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing. Available at: https://www.R-project.org/Google Scholar
Roth, R.T., Ruffatti, M.D., O'Rourke, P.D. and Armstrong, S.D. (2018) ‘A cost analysis approach to valuing cover crop environmental and nitrogen cycling benefits: a central Illinois on farm case study’, Agricultural Systems, 159, pp. 6977. https://doi.org/10.1016/j.agsy.2017.10.007CrossRefGoogle Scholar
Ruis, S.J., Blanco-Canqui, H., Creech, C.F., Koehler-Cole, K., Elmore, R.W. and Francis, C.A. (2019) ‘Cover crop biomass production in temperate agroecozones’, Agronomy Journal, 111, pp. 1535–51. https://doi.org/10.2134/agronj2018.08.0535CrossRefGoogle Scholar
Sawadgo, W. and Plastina, A. (2018) ‘Cost-share programs for cover crops available to Iowa farmers in 2018’, Ag Decision Maker: A Business Newsletter for Agriculture, 22(12), pp. 13.Google Scholar
Sawyer, J., Nafziger, E., Randall, G., Bundy, L., Rehm, G. and Joern, B. (2006) Concepts and rationale for regional nitrogen rate guidelines for corn. Ames, IA: Iowa State University Extension and Outreach PM 2015. Available at: http://www.extension.iastate.edu/Publications/PM2015.pdfGoogle Scholar
Schnepf, M. and Cox, C.A. (eds.) (2006) Environmental benefits of conservation on cropland: the Status of our knowledge. Ankeny, IA: Soil and Water Conservation Society. ISBN 978-0-9769432-3-5.Google Scholar
Seifert, C.A., Azzari, G. and Lobell, D. (2018) ‘Satellite detection of cover crops and their effects on crop yield in the Midwestern United States’, Environmental Research Letters, 13, p. 064033. https://doi.org/10.1088/1748-9326/aaf933CrossRefGoogle Scholar
Seifert, C.A., Azzari, G. and Lobell, D. (2019) ‘Corrigendum: satellite detection of cover crops and their effects on crop yield in the Midwestern United States (2018 Environ. Res. Let. 13 064033)’, Environmental Research Letters, 14, p. 039501. https://doi.org/10.1088/1748-9326/aaf933CrossRefGoogle Scholar
Sellers, J., Schwab, D., Arora, K., Clark, C., Dewell, G., Euken, R., Gunn, P., Lippolis, K., Loy, D., Lundy, E., Russell, J., Schulz, L., Shouse, S., Wall, P., Beenken, A., Harding, J., Holcomb, M., Jamison, S. and Redifer, C. (2019) Iowa cow-calf production – exploring different management systems. Ames, IA: Iowa Beef Center, Iowa State University Extension and Outreach. IBC 131, January.Google Scholar
Singh, N., Kumar, S., Jin, V.L. and Schneider, S. (2022) ‘Short-term soil physical responses to grazing and cover crops in an integrated crop-livestock agroecosystem’, Journal of Soil and Water Conservation, 77(5), pp. 516–27. https://doi.org/10.2489/jswc.2022.00095CrossRefGoogle Scholar
Snapp, S.S., Swinton, S.M., Labarta, R., Mutch, D., Black, J.R., Leep, R., Nyiraneza, J. and O'Neil, K. (2005) ‘Evaluating cover crops for benefits, costs and performance within cropping system niches’, Agronomy Journal, 97(1), pp. 322–32.CrossRefGoogle Scholar
Thompson, N.M., Armstrong, S.D., Roth, R.T., Ruffatti, M.D. and Reeling, C.J. (2020) ‘Short-run net returns to a cereal rye cover crop mix in a Midwest corn–soybean rotation’, Agronomy Journal, 112, pp. 1068–83. https://doi.org/10.1002/agj2.20132CrossRefGoogle Scholar
Tonitto, C., David, M.B. and Drinkwater, L.E. (2006) ‘Replacing bare fallows with cover crops in fertilizer-intensive cropping systems: a meta-analysis of crop yield and N dynamics’, Agriculture, Ecosystems, & Environment, 112, pp. 5872.CrossRefGoogle Scholar
US Department of Agriculture (USDA). (2009) ‘Balancing your animals with your forage’. Small scale solutions for your farm. Available at: https://www.farmers.gov/sites/default/files/2022-09/farmersgov-small-scale-factsheet-balancing-animals-with-forage-10-2022.pdfGoogle Scholar
US Department of Agriculture (USDA). (2019a) 2017 census of agriculture. Washington, DC: National Agricultural Statistical Service, April.Google Scholar
US Department of Agriculture (USDA). (2019b) NRCS cover crop termination guidelines: version 4. Washington, DC: Natural Resources Conservation Service, June.Google Scholar
US Department of Agriculture (USDA). (2021) State fact sheets. Washington, DC: Economic Research Service, February. Available at: https://www.ers.usda.gov/data-products/state-fact-sheets/Google Scholar
US Department of Agriculture (USDA). (2022) Quickstats. Washington, DC: National Agricultural Statistical Service, April. Available at: https://quickstats.nass.usda.gov/Google Scholar
Werblow, S. and Myers, R. (2014) 2013–2014 cover crop survey report. West Lafayette, IN: North-Central Sustainable Agriculture Research and Education and Conservation Technology Information Center. Available at: https://www.sare.org/wp-content/uploads/2013-14-Cover-Crop-Survey-Report.pdf (Last accessed 21 November 2021).Google Scholar
Werblow, S. and Myers, R. (2015) 2014–2015 annual report cover crop survey. West Lafayette, IN: North-Central Sustainable Agriculture Research, Education and Conservation Technology Information Center, and American Seed Trade Association. Available at: https://www.sare.org/wp-content/uploads/2014-2015-Cover-Crop-Report.pdf (last accessed 21 November 2021).Google Scholar
Werblow, S. and Myers, R. (2016) Annual report 2015–2016 cover crop survey. West Lafayette, IN: North-Central Sustainable Agriculture Research, Education and Conservation Technology Information Center, and American Seed Trade Association. Available at: https://www.sare.org/wp-content/uploads/2015-2016-Cover-Crop-Survey-Report.pdf (last accessed 21 November 2021).Google Scholar
Werblow, S. and Watts, C. (2013) 2012–2013 cover crop survey: June 2013 survey analysis. West Lafayette, IN: North-Central Sustainable Agriculture Research and Education and Conservation Technology Information Center. Available at: https://www.sare.org/wp-content/uploads/SARE-CTIC-CC-Survey-Report-V2.8.pdf (last accessed 21 November 2021).Google Scholar
Wood, S.A. and Bowman, M. (2021) ‘Large-scale farmer-led experiment demonstrates positive impact of cover crops on multiple soil health indicators’, Nature Food, 2, pp. 97103. https://doi.org/10.1038/s43016-021-00222-yCrossRefGoogle ScholarPubMed
Figure 0

Table 1. Commonalities in experimental design variables by location-year

Figure 1

Table 2. Economic assumptions

Figure 2

Table 3. Descriptive statistics of corn yield differences between treated and untreated plots, ΔY

Figure 3

Table 4. Descriptive statistics of net returns to cereal rye in the no-grazing scenario, NRINo

Figure 4

Table 5. Descriptive statistics of spring biomass, BS, and grazing days in the full-grazing scenario, GFull

Figure 5

Table 6. Kruskal–Wallis rank-sum tests on spring biomass, BS

Figure 6

Table 7. Descriptive statistics of net returns to cereal rye in the full-grazing scenario, NRIFull

Figure 7

Table 8. Statistical model of percent change in corn yield differences between treated and untreated plots, %ΔY

Figure 8

Figure 1. Fitted and observed percent changes in corn yield differences, %ΔY, vs total field biomass, ln (64.75 × BS).

Figure 9

Table 9. Descriptive statistics of net returns to cereal rye in the partial-grazing scenario, NRIPartial

Figure 10

Figure 2. Net returns to partial grazing versus total biomass produced by termination date (grazed and left in the field).

Supplementary material: File

Plastina et al. supplementary material
Download undefined(File)
File 94.2 KB