Understanding producers' perspectives on rotational grazing benefits across US Great Plains

Tong Wang; Hailong Jin; Urs Kreuter; Richard Teague

doi:10.1017/S1742170521000260

Understanding producers' perspectives on rotational grazing benefits across US Great Plains

Published online by Cambridge University Press: 29 June 2021

Urs Kreuter and

Tong Wang*: Affiliation:
Ness School of Management and Economics, South Dakota State University, Brookings, SD57006, USA
Hailong Jin: Affiliation:
Ness School of Management and Economics, South Dakota State University, Brookings, SD57006, USA
Urs Kreuter: Affiliation:
Texas A&M University, College Station, TX77843, USA
Richard Teague: Affiliation:
Texas A&M AgriLife Research, Vernon, TX76385, USA
*: Author for correspondence: Tong Wang, E-mail: tong.wang@sdstate.edu

Article contents

Abstract
Introduction
Methods
Empirical model
Results
Discussion
Conclusion
Footnotes
References

Rights & Permissions

Abstract

Experimental findings on rotational grazing (RG) trials have generally differed from producer observations of RG outcomes on commercial scale ranches. Factors such as small plot size, short duration trials and relatively rigid grazing management that lacks responsiveness to the dynamic and complex social-ecological systems in grazing trials could all contribute to this disparity in outcomes. These differences call for a better understanding of producer perceptions of RG benefits. To fill this knowledge gap, we surveyed 4500 producers from the Northern and Southern Great Plains of the USA. Among the 875 respondents, 40.5% reported that they used continuous grazing (CG), 52.7% implemented RG management in an extensive manner, while 6.8% adopted management intensive grazing. Compared with CG users, adopters of RG in its extensive and intensive form reported an average annual increase of grazing season by 7.6 and 39.3 days, respectively. When controlling for producer demographics, ranch management goals and other rancher characteristics, we found soil and climate heterogeneity significantly affected the perceived relative benefits of RG vs CG strategies. Therefore, instead of focusing on whether RG outperforms CG per se, future research could focus on comparison of RG benefits under different management intensity levels and identifying soil and climate conditions where RG benefits are more noticeable.

Keywords

Grazing season length management intensive grazing perceived grazing benefits producer survey rotational grazing soil and climate heterogeneity

Type: Research Paper
Information: Renewable Agriculture and Food Systems , Volume 37 , Issue 1 , February 2022 , pp. 24 - 35

DOI: https://doi.org/10.1017/S1742170521000260 [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike licence (http://creativecommons.org/licenses/by-nc-sa/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the same Creative Commons licence is included and the original work is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use.
Copyright: Copyright © The Author(s), 2021. Published by Cambridge University Press

Introduction

As one of the earth's major land cover types, rangelands play a critical role in sustaining human livelihoods and wellbeing through the production of grazing livestock and the provision of a wide range of ecosystem services, including carbon sequestration (Schuman et al., Reference Schuman, Janzen and Herrick2002; Garnett et al., Reference Garnett, Godde, Muller, Röös, Smith, De Boer, zu Ermgassen, Herrero, Van Middelaar, Schader and Van Zanten2017) and biodiversity maintenance (Fuhlendorf and Engle, Reference Fuhlendorf and Engle2001; Sugita et al., Reference Sugita, Asanuma, Tsujimura, Mariko, Lu, Kimura, Azzaya and Adyasuren2007; Godde et al., Reference Godde, Boone, Ash, Waha, Sloat, Thornton and Herrero2020). In the past several decades, rangeland degradation, mainly attributable to overstocking, improper grazing management, diminished nutrient cycling and changing climate, has become a worldwide concern (Archer and Stokes, Reference Archer and Stokes2000; Vetter et al., Reference Vetter, Goqwana, Bond and Trollope2006; Harris, Reference Harris2010; di Virgilio et al., Reference di Virgilio, Lambertucci and Morales2019). To help improve long-term ecological and economic sustainability of rangelands, rangeland research during the past century has primarily focused on identifying proper stocking rate and developing sustainable grazing management strategies (Wang et al., Reference Wang, Teague, Park and Bevers2018; di Virgilio et al., Reference di Virgilio, Lambertucci and Morales2019).

While stocking rate can affect soil health, plant and livestock productivity, maintaining proper stocking rate alone is insufficient to avoid overgrazing and prevent rangeland degradation (Teague et al., Reference Teague, Dowhower and Waggoner2004, Reference Teague, Provenza, Kreuter, Steffens and Barnes2013; Barnes et al., Reference Barnes, Norton, Maeno and Malechek2008; Provenza et al., Reference Provenza, Pringle, Revell, Bray, Hines, Teague, Steffens and Barnes2013). In large pastures, livestock demonstrate heterogeneous grazing behavior with preferred areas that have better soils or are close to water and shade being heavily grazed, while other areas are underutilized (Wallis DeVries et al., Reference WallisDeVries, Laca and Demment1999; Witten et al., Reference Witten, Richardson and Shenker2005; Teague et al., Reference Teague, Dowhower, Baker, Haile, DeLaune and Conover2011). To minimize overgrazing and reverse rangeland degradation in preferred areas, managing livestock distribution and providing adequate recovery time from grazing are deemed critical (Barnes et al., Reference Barnes, Norton, Maeno and Malechek2008; Norton et al., Reference Norton, Barnes and Teague2013; Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013).

Rotational grazing (RG) facilitates the attainment of such management objectives by dividing the grazed area into a number of paddocks with one paddock being grazed while the other paddocks are recovering from prior grazing (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013). In practice, RG spans a continuum of management intensity levels with greater management intensity typically being associated with more paddocks, shorter grazing period per paddock and longer post-herbivory recovery periods in each paddock (Hanson et al., Reference Hanson, Ford, Parsons, Cunningham and Muller1998; Undersander et al., Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002; Foltz and Lang, Reference Foltz and Lang2005; Heiberg and Syse, Reference Heiberg and Syse2020; Wang et al., Reference Wang, Jin, Kreuter, Feng, Hennessy, Teague and Che2020).

There is evidence that RG with few paddocks per herd, longer grazing periods and shorter recovery periods can result in limited plant and animal production advantages compared to continuous set-stocking at low stocking rates (Briske et al., Reference Briske, Derner, Brown, Fuhlendorf, Teague, Havstad, Gillen, Ash and Willms2008, Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013). Low stocking rate as well as improperly applied RG strategies do not facilitate degraded resource recovery or provide adequate economic returns over time (Jakoby et al., Reference Jakoby, Quaas, Müller, Baumgärtner and Frank2014, Reference Jakoby, Quaas, Baumgärtner and Frank2015; Teague and Kreuter, Reference Teague and Kreuter2020). Therefore, some grazing research has concluded that there were no improvements in ecological and livestock indicators in RG compared to continuous grazing (CG) and recommended stocking rate adjustment as the primary tool for preventing overgrazing (e.g., Briske et al., Reference Briske, Derner, Brown, Fuhlendorf, Teague, Havstad, Gillen, Ash and Willms2008). However, grazing management success stories reported at the whole ranch scale are often underpinned by the implementation of adaptive RG strategies (Gerrish, Reference Gerrish2004; Provenza et al., Reference Provenza, Pringle, Revell, Bray, Hines, Teague, Steffens and Barnes2013; Savory and Butterfield, Reference Savory and Butterfield2016; Teague and Barnes, Reference Teague and Barnes2017; Teague and Kreuter, Reference Teague and Kreuter2020).

The contextual differences between scientific research and rancher experiences may help explain the apparent conflicts in outcomes. Spatial and temporal scales are frequently noted as important factors in research outcomes. While commercial ranches generally exceed 100 hectares and sometimes cover several thousand hectares, most scientific research is carried out in small field plots, averaging less than 30 hectare with only 14% comparable in size with commercial ranches (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013; Wolf and Horney, Reference Wolf and Horney2016). Compared to controlled experiments in small paddocks, livestock behavior and grazing distribution differ in larger paddocks, thereby affecting plant composition differently (Earl and Jones, Reference Earl and Jones1996; Teague and Barnes, Reference Teague and Barnes2017). Due to treatment response time lags, study duration is another factor that likely affects research outcomes. Compared to ranchers' long-term experiences with conservation practices, the duration of most research projects is generally too short to capture the improvement in grass composition and soil health resulting from the improved grazing management (Pinchak et al., Reference Pinchak, Teague, Ansley, Waggoner and Dowhower2010; Teague et al., Reference Teague, Dowhower, Baker, Haile, DeLaune and Conover2011).

Inconsistent use of terminology can also contribute to the result disparities. Some studies simply refer to all practices that involve moving animals as RG. While some studies have used terms such as adaptive multiple paddock grazing, holistic planned grazing and management intensive RG to distinguish the adaptive management emphasis relative to conventional RG, which tends to follow a rigid predetermined rotation schedule, the definition of such terms are often inconsistent among different studies. In most experimental trials, a fixed grazing schedule and set stocking rates are applied without accounting for changing weather conditions and social variables, such as ranchers' goals, knowledge and experience. At the ranch scale, however, holistic or integrative management approaches respond more adaptively to the dynamics of complex social-ecological systems (Roche et al., Reference Roche, Cutts, Derner, Lubell and Tate2015; Teague and Barnes, Reference Teague and Barnes2017; Gosnell, et al., Reference Gosnell, Grimm and Goldstein2020).

Ranchers and researchers often have divergent perspectives, which could also lead to their different perceptions on grazing management practices. Barton et al. (Reference Barton, Bennett and Burnidge2020) found that ranchers prioritized the planning benefits of RG, such as drought planning and increased confidence about uncertainty and risks, rather than the grazing benefits as emphasized by researchers. Roche et al. (Reference Roche, Cutts, Derner, Lubell and Tate2015) also pointed out that ranchers adapt grazing management to pursue multiple outcomes, while researchers primarily emphasize only biophysical outcomes in terms of forage production and livestock weight gains at the scale of experimental plots.

To help reconcile the discrepancies between scientific findings and rancher perceptions, it is necessary to reduce their contextual differences. In this regard, studies have utilized producer interviews and surveys to identify their adoption decisions and the benefits and challenges perceived by ranchers regarding RG practices (Stinner et al., Reference Stinner, Stinner and Martsolf1997; Roche et al., Reference Roche, Cutts, Derner, Lubell and Tate2015; Becker et al., Reference Becker, Kreuter, Atkinson and Teague2017; Sitienei et al., Reference Sitienei, Gillespie and Scaglia2019; Venter et al., Reference Venter, Cramer and Hawkins2019; Barton et al., Reference Barton, Bennett and Burnidge2020; Heiberg and Syse, Reference Heiberg and Syse2020; Wang et al., Reference Wang, Jin, Kreuter, Feng, Hennessy, Teague and Che2020). Among these, Roche et al. (Reference Roche, Cutts, Derner, Lubell and Tate2015) inferred that ranchers perceive tangible benefits from RG as indicated by its widespread adoption in California and Wyoming. Additionally, Becker et al. (Reference Becker, Kreuter, Atkinson and Teague2017) found that North Central Texas ranchers using eight or more paddocks perceived an improvement in the ecological status of their land compared with those using CG. By contrast, Wang et al. (Reference Wang, Jin, Kreuter, Feng, Hennessy, Teague and Che2020) identified labor time and water source constraints followed by high installation costs as the main barriers to the adopting RG.

The analyses of producers' perspectives of RG benefits and the challenges they have to overcome to apply RG provide helpful insights. However, very few studies have investigated whether the relative benefits of alternative RG strategies vary under different scenarios (di Virgilio et al., Reference di Virgilio, Lambertucci and Morales2019). For example, climate factors potentially influence RG benefits (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013; Wolf and Horney, Reference Wolf and Horney2016; Gosnell et al., Reference Gosnell, Grimm and Goldstein2020). As droughts often exacerbate the disproportionate grazing impacts on palatable and unpalatable grass species (McIvor, Reference McIvor2007), RG benefits may be magnified in lower precipitation areas since it allows post-herbivory recovery of palatable grasses, and can improve underlying soil and ecological functions (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013). In addition, soil conditions also affect RG benefits and failing to consider soil and slope differences can lead to erroneous conclusions from field experiments (Teague and Foy, Reference Teague and Foy2004).

In this study, we add to the grazing management literature by analyzing climate and soil effects on producers' perceptions regarding RG benefits. Using the experiences from RG ranchers spanning the Northern and Southern extremities of the Great Plains, we examine the effects of soil and climate heterogeneity on producer perceptions of three categories of potential RG benefits: (1) plants—such as increased percentage of desirable grass, length of grazing season and faster drought recovery; (2) livestock—such as increased stocking capacity and improved livestock health; and (3) environmental—such as decreased runoff and soil erosion.

To understand producers' perceptions about the benefits of varying levels of management sophistication with RG, we define extensive RG as systems with 4–15 paddocks per herd with livestock grazing each paddock for weeks to months before being moved to the next paddock. On the opposite end of the continuum, we define management intensive grazing (MIG) as a more sophisticated and management intensive form of RG that incorporates at least 16 paddocks per herd and variable 1–7 days grazing periods followed by variable 20–100 days post-grazing recovery periods depending on management goals and extant weather conditions (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013). We also analyze how factors such as demographics, ranch management goals and ranch characteristics may affect producers' perceptions of RG benefit.

Methods

Survey description

In 2018, we conducted a mail survey among 4500 producers in North Dakota, South Dakota and Texas. The survey sample was purchased from Survey Sampling International. We used the selection criterion that the selected cattle operations had at least 100 non-feedlot cattle. We selected 1500 producers in each state using this minimum operation size criterion along with proportional sampling to ensure that the number of producers selected per county was proportional to the number of qualified ranching operations in each county.

In North and South Dakota, we included most counties but excluded those toward the west that consist primarily of public lands and forest. In Texas, we included counties from four districts that are primarily occupied by rangeland, including the Panhandle, Rolling Plains, Central and West Central districts (agecoext.tamu.edu). Our study areas are located on the northern and southern extremities of the US portion of the Great Plains, which exhibits a distinct north-south increasing temperature gradient and an east-west declining precipitation gradient. Our two study areas encompass these gradients, enabling us to examine differences in potential RG benefit perceptions across varying temperature and precipitation levels.

The mail survey was conducted using a questionnaire that incorporated areas of inquiry such as ranch management practices, perceived benefits and adoption status of extensive RG and MIG, basic ranch information and producer demographics. The survey was administered during late January to early April 2018 using five mailings. These included a pre-survey announcement letter, the survey questionnaire with a cover letter and a reminder/thank you card to all selected landowners, and for those producers who did not return the first survey questionnaire, we sent a replacement questionnaire with another cover letter and a final reminder card (Dillman, Reference Dillman1978). To help boost the response rate, we also mailed a third survey questionnaire to non-respondents in June 2018. We received 875 completed questionnaires from the three states, which represents an overall response rate of 20.6% based on an effective sample size of 4250 producers that excluded 250 ineligible samples (Wang et al., Reference Wang, Jin, Kreuter, Feng, Hennessy, Teague and Che2020).

Data description

In the survey questionnaire, we asked producers about the plant, livestock and environmental benefits of RG and MIG that they observed on or expected on their own or neighboring ranches. We directed the set of benefit questions to all producers, regardless of their adoption status, so that we not only gather opinions from RG or MIG adopters, based on their observations on their own ranches, but also understand non-adopters' expectations of the benefits, potentially based on their observations from neighborhood ranches. Producers were asked to indicate the benefits by using a four-point rating scale: 1 = None; 2 = Slight; 3 = Medium; and 4 = Significant. Besides the ordinal benefit variables, we also included a continuous dependent variable, i.e., grazing season length, whereby we asked producers to provide the length of their grazing season in a typical year.

RG intensity level adopted by the producers was included as an explanatory variable to control for the influence of adoption decisions. We also included types of cattle operation as explanatory variables because the composition of grass species can vary between cow-calf plus stocker operations and cow-calf only operations (Wilmer et al., Reference Wilmer, Augustine, Derner, Fernández-Giménez, Briske, Roche, Tate and Miller2018). Compared to cow-calf only operations, cow-calf plus stocker operations can adapt more quickly to drought due to their greater capacity to adjust stocking rates by selling stockers.

According to Roche et al. (Reference Roche, Cutts, Derner, Lubell and Tate2015), ranchers' goal prioritization affects their perceptions on grazing management successes and failures. Therefore, we asked producers to use a five-point scale to indicate the importance of the goal to improve soil and grassland quality on their land: 1 = Not important; 2 = Slightly important; 3 = Somewhat important; 4 = Quite important; and 5 = Very important.

Given that level of education might also affect the likelihood of adoption of conservation practices, such as RG, we also asked producers to indicate their highest level of education. Choice options ranged from 1 = less than high school to 5 = advanced degree. Non-formal education provided by Extension agencies can also facilitate producers' understanding of the benefits of conservation practices and government agencies, such as the Natural Resources Conservation Service (NRCS), can play an important role in producers' adoption decisions (Kim et al., Reference Kim, Gillespie and Paudel2008; Bates and Arbuckle, Reference Bates and Arbuckle2017; Wang, Reference Wang2019). Producers were therefore asked to use a five-point scale to rate the importance of Extension and government agencies in their decision making: 1 = Not important; 2 = Slightly important; 3 = Somewhat important; 4 = Quite important; and 5 = Very important.

Several operation characteristics were also included as explanatory variables. Leased grassland, which generally associated with no tenure security and limited investment in infrastructure, often does not benefit from RG (Whitson et al., Reference Whitson, Heitschmidt, Kothmann and Lundgren1982; Wang et al., Reference Wang, Teague, Park and Bevers2018). Accordingly, we asked producers what proportion of their livestock operation was based on owned and leased land. Additionally, given that RG benefits may depend on operation scale (Wang et al., Reference Wang, Teague and Park2016), we also asked producers to select one of five choice options to indicate their approximate gross sales from cattle enterprises in a typical year: 1 = <$50,000; 2 = 50,000–99,999; 3 = $100,000–249,999; 4 = 250,000–499,999; 5 = 500,000–999,999; 6 = $1 million or more.

We also supplemented producer survey data with land capability class (LCC) and land slope data, obtained for each ranch location from the NRCS's SSURGO database, to capture the potential land quality effect on perceived RG benefits. LCC I refers to land that is highly suitable for crop cultivation, LCC II is land generally suitable for most cultivated crops but may require moderate conservation practices, LCC III and IV is land that requires careful conservation practices such as no-till and cover crops and proper management, and LCC V and above is land that is not suitable for cropping (Klingebiel, Reference Klingebiel1961). In addition, land with steeper slopes is more susceptible to soil erosion and, therefore, is suited mainly for livestock grazing.

To capture the potential climate effect on producers' perceptions of RG benefits, we also obtained the county level 30-year (1988–2017) average annual precipitation and growing season minimum temperature from the National Oceanic and Atmospheric Administration (NOAA). Finally, to capture regional differences in producers' perceptions of RG benefits, we included a bivariate respondent location variable in which 0 = the Dakotas and 1 = Texas.

Empirical model

Multivariate probit model

We developed an empirical model to understand how producers' perception on RG benefits varies across the US Southern and Northern Plains. To achieve this, we asked producers to indicate their perceptions of RG benefits on their own or neighboring ranches. Producers' responses toward potential benefits of RG take four discrete values with intrinsic order. Since producers' perceptions of RG-related plant, livestock and environmental benefits are likely correlated, we used a multivariate probit model to jointly analyze producers' perceptions of RG benefits in the five different aspects as listed in Table 1.

Table 1. Description and mean values for the benefit variables, overall and grouped by different grazing strategies

Note: ^†Producers rated benefits by on a four-point scale: 1 = none; 2 = slight; 3 = medium; 4 = significant. Superscripts are used to denote Duncan's multiple range test results, where the numbers with same letters imply no statistically significant difference exist between the average values in different groups.

Following Roodman (Reference Roodman2011), the multivariate probit model is defined as:

$$Y_i = \left\{{\matrix{ {1, \;} \cr {2, \;} \cr \vdots \cr J \cr } } \right.\,\;\matrix{ {{\rm if}} \cr {{\rm if}} \cr {} \cr {{\rm if}} \cr } \matrix{ {{\rm \alpha }_{i, 0} < Y_i^\ast \le {\rm \alpha }_{i, 1}} \cr {{\rm \alpha }_{i, 1} < Y_i^\ast \le {\rm \alpha }_{i, 2}} \cr \vdots \cr {\;{\rm \alpha }_{i, J-1} < Y_i^\ast \le {\rm \alpha }_{i, J}} \cr } , \;$$

where Y _i and $Y_i^\ast$ represent the observed and latent variables, with i ∈ {1, 2, 3, 4, 5} denotes the five potential benefits associated with RG. Among them, Y ₁ and Y ₂ are grass-related benefits, denoting increased percentage of desirable grass and increased drought resilience, respectively. Variables Y ₃ and Y ₄ relate to RG-associated livestock benefits, with Y ₃ representing increased stocking rate capacity and Y ₄ representing improved livestock health. The environmental benefit is denoted by Y ₅, which refers to decreased runoff and erosion. Each of the observed benefit variables Y _i can take J potential values. In our case, J = 4, meaning that producers have four different levels of perceived benefits to select from, which are 1 = None, 2 = Slight, 3 = Medium and 4 = Significant.

The latent variable $Y_i^\ast$ corresponds to the observed variable Y _i through an ascending sequence of cut-points α_i,0, α_i,1, α_i,2, ⋅ ⋅ ⋅ , α_i,J−1, α_J with α_i,0 = −∞ and α_J = +∞. Note that $Y_i^\ast{ \, = \, } X{\rm \beta }_i + {\rm \varepsilon }_i$, whereX denotes the vector of explanatory variables, which are the same across all five equations and capture farm-level variances regarding grazing management intensity, cattle enterprise types, producer goal and demographics, farm characteristics, land quality and climate variables (Table 2). The vector of coefficient estimates is denoted by β_i, which measures the effect of the explanatory variable on the expected values of the latent variables, $E( Y_i^\ast )$. The coefficient is scaled by density function to compute the marginal effect of explanatory variables on the observed variable, E(Y _i) (Greene, Reference Greene2012).

Table 2. Description and summary statistics for the explanatory variables in the multivariate ordered probit model

The error terms ɛ_i follow standardized normally distributions that are independent on X, i.e., ɛ_i|X ~ N(0, 1), but are correlated across equations with correlation coefficient matrix [ρ_ik]_3×3, where ρ_ik denotes the tetrachoric correlation between two latent variables $Y_i^\ast$ and $Y_k^\ast$ (i, k ∈ {1, 2, 3, 4, 5}). A ρ_ik that is significantly different from 0 means that producer perceptions on different benefits Y _i and$Y_k^{}$are correlated.

Ordinary least square model

In addition to the perceived RG benefits, we also asked producers about the length of their grazing season in a typical year, denoted by Y, which is a continuous variable that reflects the length of grazing period for different producers. To estimate the effect of grazing management intensity on Y, we use ordinary least square (OLS) regression, specified as Y = Xβ + ɛ. Note that X denotes the same vector of explanatory variables as used in the multivariate probit model, as detailed in Table 2, ɛ is the error term that follows standardized normal distribution that are independent of X and β is the vector of estimated coefficients that measure the effect of the explanatory variables on the expected value of Y.

Results

General statistics description

Table 1 provides the description and mean values for the variables related to RG benefits. Based on the overall mean values, it is apparent that producers perceived higher grass-related than livestock-related and environmental-related benefits associated with RG. The length of the grazing season for all respondents averaged 219 days. To understand differences in producer perceptions according to their grazing strategies, we conducted Duncan's multiple range test for all the benefit variables included in the empirical models. Compared to CG users, both extensive and intensive RG adopters perceived significantly higher benefits in all five benefit categories. On average, RG adopters observed medium to significant benefits in each category except for the livestock health, which averaged just less than medium benefit. Additionally, MIG adopters indicating a significantly longer grazing season than extensive RG and CG adopters.

Figure 1 further shows these differences in perspectives, with RG and MIG adopters grouped into the adopter category and the CG users into the non-adopter category. Compared to adopters, a much higher proportion of non-adopters perceived there is no benefit of RG in all of the listed categories. This lack of benefit perception ranged from 15.2% for grass-quality to 26.8% for livestock health, while over one-fifth of non-adopters perceived significant benefits of RG for drought-resilience (22.9%), grass-quality (23.2%) and stocking capacity (25.2%) but less significant benefits for livestock health (17.8%) and soil erosion reduction (17.1%). In comparison, minimal RG adopters perceived no drought resilience (3.3%) and grass-quality benefits (1.8%), and over 80% of adopters perceived medium to significant grass-quality-related benefits. With respect to livestock, far fewer adopters perceived there to be no or slight benefits for increased stocking capacity (26.9%) and improved livestock health (30.4%), whereas 37 and 31.5% perceived significant benefits regarding stocking rate and livestock health, respectively. With respect to environmental benefits, i.e., decreased runoff and erosion, nearly 80% of the adopters perceived medium or significant benefits, compared to less than 50% of non-adopters.

Fig. 1. Percentage of adopters and non-adopters of RG with perceived RG benefits ranging from ‘none’ to ‘significant’. (Note that drought = faster drought recovery; grass = increased percentage of desirable grass; stocking = increased stocking capacity; health = improved livestock health; and erosion = decreased runoff and soil erosion)

Table 2 provides the description and summary statistics for all explanatory variables included in the multivariate ordered probit model and OLS model. Of the respondents, 40.5% used CG, 52.7% were extensive RG adopters and 6.8% were MIG adopters. Among them, 20.9% own a cow-calf plus stocker operation, only 2.6% have a grass-finishing operation, while the remainder have cow-calf only operations. Regarding the importance of the goal to improve soil and grassland quality on their land, the average value of 4.117 indicates that most producers rated soil and grassland quality improvement as ‘quite important’ (Table 2). With respect to the importance of Extension and government agencies, the average rating was 2.804, which indicates that producers generally viewed Extension and government agencies as ‘somewhat important’ in their decision-making. The mean value of 3.238 for education indicates that most producers have some college/technical school education. On average, about one-third (32.7%) of the rangeland and pasture used for livestock production was leased (Table 2). Annual gross sales of the beef cattle enterprise took six possible values, with the mean value of 3.067 indicating median gross sales of ‘$100,000–$249,999’ (Table 2).

With respect to land quality and slope within 1-mile radius of the location of respondents' farm or ranch, 43.8% of the land was categorized as LCC I to II and the slope of 43.1% of the land is less than 3 degrees. The average annual precipitation across all of the counties included in the study ranged from 137 to 1192 mm with an overall average of 626 mm, while the average growing season minimum temperature ranges from 9 to 24 degrees with an average minimum temperature of 15 degrees. For the Texas variable, the average value of 0.372 indicates that 37.2% of respondents are from Texas and 62.8% are from the North and South Dakota.

Model estimation results

Table 3 presents the coefficient and standard error (SE) estimation results for the multivariate probit model. All of the correlation coefficients, ρ_ik (i, k = 1, 2, 3, 4, 5)Footnote ¹, differ significantly from zero at P < 0.01 (bottom of Table 3). This indicates that ranchers' perceived RG benefits in the grass, livestock and environmental categories are significantly correlated with each other, which justifies our use of the multivariate probit model. The marginal effects of explanatory variables on grass, livestock and environmental-related benefits are presented in Tables 4–6. Table 7 presents the results from OLS model. The R ² value of 0.356 indicates that 35.6% of variability in the length of grazing season can be explained by the included explanatory variables.

Table 3. Estimated explanatory variable coefficients and standard errors for the multivariate ordered probit model

Note: ***P < 0.01, **P < 0.05, *P < 0.1.

Table 4. Marginal effects on grass-related benefits

Note: ***P < 0.01, **P < 0.05, *P < 0.1.

Table 5. Marginal effects on livestock-related benefits

Note: ***P < 0.01, **P < 0.05, *P < 0.1.

Table 6. Marginal effects on environmental benefits

Table 7. Estimate of the effects on length of grazing season

Note: ***P < 0.01, **P < 0.05, *P < 0.1.

As indicated in Table 4, extensive RG and MIG adopters are 20.4 and 20.7%, respectively, more likely to rate significant benefit from increased proportion of desirable grass. Compared to CG users, RG adopters, especially MIG adopters, also perceived significantly greater benefits for drought recovery (Table 4). Specifically, 22.2% of extensive RG adopters and 34.0% of MIG adopters perceived significant greater drought recovery benefits than CG users. Compared with CG users, both extensive and intensive RG adopters are more likely to perceive significantly greater livestock health and stocking capacity benefits (Table 5). Additionally, extensive RG and MIG adoption significantly affects producers' perception on environmental benefits, with extensive RG and MIG adopters being 22.4 and 28.1%, respectively, more likely than CG grazers to perceive significant benefits in decreased runoff and erosion.

The types of operations also affect producers' perceptions about RG-related livestock benefits (Table 5). Compared with cow-calf only producers, integrated cow-calf and stocker producers were 1.0 and 6.4% less likely to perceive medium or significant livestock health benefits, respectively. In contrast, compared to cow-calf only producers, grass-finishing cattle producers were 26.8 and 23.9% more likely to perceive significant RG-related benefits with respect to stocking capacity and livestock health, respectively.

Our research indicated that producers who prioritized soil/grassland quality improvement as a management goal are more likely to perceive significant benefits in all five RG-related benefit aspects (Table 4–6). One unit increase in the importance of the soil/grassland improvement goal led to a 9.7% increase in perceived benefit regarding runoff and erosion reduction (Table 6).

Education is positively related to perceived grass-related and runoff and erosion minimization benefits (Table 3). Specifically, an increase in education by one unit was found to lead to a 2.8% greater likelihood that producers perceive a significant increase in the benefit of desirable grass, and a 3.5% greater likelihood that they perceive a significant benefit in decreased soil runoff and erosion. Compared to formal education, informal education appears to play a more critical role in producers' perceived benefits of RG practices. Specifically, those who view Extension and government agency as important in their decision-making are more likely to perceive significant RG benefits in all benefit categories (Tables 4–6). This implies that by providing educational and technical support, Extension and government agencies may help producers improve their understanding of the RG benefits.

The ratio of leased to owned land is negatively related to producers' perceptions of RG-related benefits; specifically, operators on rented land were 7.4 and 7.1% less likely to perceive significant benefits regarding increased drought resilience and decreased runoff and erosion, respectively (Tables 4 and 6). We also found cattle gross sales, an indicator of herd size, was negatively associated with producers' perceived livestock health benefits of RG (Table 5).

The proportion of land under LCC I and II, which can sustain greater stocking capacity, negatively affects producer perceived RG-associated benefits (Table 3). Specifically, when the proportion of LCC I and II increases from 0 to 100%, producers were 7.4, 6.2 and 7.2% less likely to perceive increased percentage of desirable grass, improved livestock health and decreased runoff and erosion as significant benefits, respectively (Table 4). These findings indicate that producers with poorer quality land are more likely to perceive RG to be beneficial. Flatter land, with a slope of less than 3%, has a positive effect on perceived grass benefit. That is, when the percentage of land with flatter slope increases from 0 to 100%, producers were 8.3% more likely to perceive significant benefit toward increased percentage of desirable grass.

In addition to land attributes, climate and regional factors are also associated with producers' perceived RG benefits. Growing season minimum temperature and precipitation are positively correlated with producers' perceived RG-related grass, drought and environmental benefits. Specifically, as average growing season minimum temperature increases by 1 degree, producers were 3.8, 3.1 and 3.7% more likely to perceive significant increases in desirable grass and drought resilience and decreased runoff and erosion, respectively. Conversely, as average annual precipitation amount decreases, producers were more likely to perceive significant increased RG benefits associated with respect to increased desirable grass, increased drought resilience and decreased runoff and erosion, respectively. Finally, Texas producers were 18.4% less likely than Dakota producers to perceive significant benefits in terms of increased percentage of desirable grass (Table 4), but not with the other four categories of benefits.

We also modeled factors that affect producers' length of grazing season in a typical year. After controlling for the climate and study region, adoption of extensive RG and MIG were found to be associated with 7.6 and 39.3 days of longer grazing seasons per year, respectively, when compared with CG (Table 7). The other factors that were found to be associated with the length of grazing days included land quality, climate and location of the producers. When controlling for other factors, we counterintuitively found that an increase in the share of LCC I and II land from 0 to 100% was associated with a 20-day decrease in annual grazing season. This is probably because higher quality lands, as indicated by higher share of LCC I and II, are likely preferred for cropping than grazing, and producers are likely to use smaller portions of their arable land for shorter periods of grazing with livestock feeding on crop residues, cover crops or winter crops (Kumar et al., Reference Kumar, Sieverding, Lai, Thandiwe, Wienhold, Redfearn, Archer, Ussiri, Faust, Landblom and Grings2019). Our study also found that every 1 degree increase in minimum temperature led to a 7.45-day increase in the grazing season. Similarly, grazing season was found to be 11.9 days longer for every 100 mm increase in average annual precipitation. Finally, after controlling for the temperature and precipitation effects, Texas producers reported an average of 54-day longer grazing seasons than Dakota producers did.

Discussion

Overall, the proportion of livestock producers in our study who used RG to manage their forage resources (59.5%) is very similar to that of Pruitt et al. (Reference Pruitt, Gillespie, Nehring and Qushim2012), who found that, in 2008, 60.2% of US beef cow-calf producers reported using some type of RG. Windh et al. (Reference Windh, Ritten, Derner, Paisley and Lee2019) pointed out that RG adopters should perceive RG to be economically superior to CG in order to compensate the RG-related capital expenses, opportunity costs and maintenance costs. Like Roche et al. (Reference Roche, Cutts, Derner, Lubell and Tate2015), we found that a large majority of RG adopters implemented extensive rather than intensive RG practices. However, unlike the survey region of Roche et al. (Reference Roche, Cutts, Derner, Lubell and Tate2015), where Mediterranean climate annual grasslands dominate, our results are based on the experiences of producers' grazing perennial grasslands in the Great Plains and do not support the contention of the Californian researchers that MIG is less beneficial than extensive RG. The MIG producers in our study indicated multiple benefits including high-cost savings through prolonged grazing seasons. Therefore, it is more likely that the low MIG adoption rate is due to the labor and water resource concerns related to intensive grazing management (Wang et al., Reference Wang, Jin, Kreuter, Feng, Hennessy, Teague and Che2020).

Among all the benefits addressed, increased drought resilience is perceived as the most beneficial feature of RG. This finding is consistent with Savory's (Reference Savory1983) description about the particular suitability of holistic management for ecosystems with prolonged dry periods. Given that adjusting stocking rates in a timely manner is essential when coping with drought (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013), an important benefit of RG, specifically MIG, is that the forage in the smaller paddocks will be depleted more rapidly and noticeably under dry conditions, thereby allowing managers to proactively reduce stock numbers if dry conditions persist (Diaz-Solis et al., Reference Díaz-Solís, Grant, Kothmann, Teague and Díaz-García2009). Similarly, we found producers located in drought-prone areas, i.e., those with higher temperature and lower precipitation are more likely to perceive RG-related benefits. In this regard, simulation results also indicated that RG benefits are more apparent under drier weather conditions (Wang et al., Reference Wang, Teague, Park and Bevers2018), while others also highlight the importance of RG to minimize the negative impacts of droughts (Teague et al., Reference Teague, Provenza, Kreuter, Steffens and Barnes2013; Jakoby et al., Reference Jakoby, Quaas, Müller, Baumgärtner and Frank2014, Reference Jakoby, Quaas, Baumgärtner and Frank2015).

Our finding that RG adopters, especially MIG practitioners, experienced significantly longer grazing season in a typical year is consistent with Undersander et al. (Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002), who pointed out that, compared to CG, RG relieves grazing pressure during the post-grazing recovery period, which can boost forage yield through rapid regrowth and therefore extend the grazing season. Additionally, Ball et al. (Reference Ball, Ballard, Kennedy, Lacefield and Undersander2008) noted that longer grazing season is associated with improved livestock performance due to the better forage quality in properly managed pastures than hay that is required when pasture forage is depleted. Longer grazing season implies less hay feeding days, which provides substantial economic benefits as feeding hay is two or three times costlier than grazing livestock on grassland (Julien and Tess, Reference Julien and Tess2002).

Another highly rated benefit perceived by both extensive RG and MIG adopters is increased proportion of desirable grass. This finding is consistent with Lawrence et al. (Reference Lawrence, Whalley, Reid and Rader2019), who found that, compared with CG, short-duration RG increased foliar cover of perennial herbaceous species by 19%, and reduced foliar cover of introduced annual plants by 14%, both of which are positive outcomes. Both extensive RG and MIG adopters are more likely to perceive livestock-related benefits, i.e., stocking capacity and livestock health improvement. This result is consistent with findings by Heiberg and Syse (Reference Heiberg and Syse2020) who interviewed beef producers and indicated that MIG improves the land and carrying capacity, which allows more livestock production with less land. Meanwhile, Undersander et al. (Reference Undersander, Albert, Cosgrove, Johnson and Peterson2002) attributed the enhanced physical fitness of livestock under RG strategy to more frequent herd movement.

It is noteworthy that nearly 60% of non-adopters in our survey sample perceived medium or significant benefits of RG vs CG regarding desirable grass percentage and stocking capacity. This contrasts with the conclusions of some researchers regarding RG benefits for vegetation and livestock production (Briske et al., Reference Briske, Derner, Brown, Fuhlendorf, Teague, Havstad, Gillen, Ash and Willms2008). Among other factors, climate heterogeneity could affect the relative benefits of RG vs CG. For example, Hawkins (Reference Hawkins2017) found that most studies in areas with less than 400 mm precipitation showed negative or no significant RG benefits on plant basal cover and they concluded that RG is more suitable in areas with moderate or high precipitation. Given that the average annual precipitation in our study area is 626 mm with only 4.23% of the respondents having less than 400 mm rainfall, most of our survey respondents are located in moderate precipitation areas. This could explain the widespread favorable perception of RG on vegetation and livestock-related benefits. The relationship between perceived RG benefits and precipitation level has also been discussed in the context of equilibrium and non-equilibrium models of vegetation change. Sub-humid grasslands, where weather is relatively predictable, are often characterized as equilibrium systems in which herbivory represents a primary driver of these ecosystems (Woodis and Jackson, Reference Woodis and Jackson2009). In contrast, arid and semiarid grasslands are considered by many researchers to be non-equilibrium systems, the dynamics of which are primarily influenced by highly variable precipitation and frequent droughts, and grazing effects are regarded as less important (Illius and O'Connor, Reference Illius and O'Connor1999; Oates et al., Reference Oates, Undersander, Gratton, Bell and Jackson2011).

We also found that factors such as operation type, land lease status, herd size and regional factors could affect producers' perceptions and understanding about RG and MIG benefits. Among all operation types, the percentage of grass-finishing livestock producers is low (2.6%), which is consistent with Riely (Reference Riely2011)'s observation that grass-finished beef remains a niche market. As demand for grass-finished beef continues to increase (Acharya et al., Reference Acharya, Burke, Wood and Yancey2020), little growth in the supply chain suggests that some underlying barriers, such as lack of policy support, could hinder the expansion of the grass-finished beef sector (DeLonge, Reference DeLonge2017). Furthermore, finishing livestock on grass may require producers to acquire additional pastures and skills and to adopt new grazing management strategies including RG or MIG. Our finding that grass-finishing producers perceive greater livestock-related benefits of RG is consistent with Sitienei et al. (Reference Sitienei, Gillespie and Scaglia2019), who found that 97% of the grass-finishing producers they surveyed used RG and 91% indicated that RG is more profitable than CG.

Our findings that leased land negatively affected perceived benefits of RG is possibly because lessees are unlikely to adopt intensified grazing management practices especially if the lease agreement does not encourage them to do so (DALC, 2012), or it could be because the lease agreement is too short for them to benefit from the lagged benefits of RG. Additionally, producers who lease land are not ultimately responsible for the land sustainability (Cox, Reference Cox2010), and, therefore, might not pay much attention to RG-related benefits such as drought recovery and reduced soil erosion. Our respondents' perception that large herd size is negatively associated with RG-related livestock health benefits may be partially explained by the fact that larger herds are more susceptible to respiratory and gastrointestinal diseases (Hill et al., Reference Hill, Green, Wagner and Dargatz2009). Furthermore, larger herd size generally requires more hired labor and poses greater challenges for livestock health inspection (Stahl et al., Reference Stahl, Conlin, Seykora and Steuernagel1999). Therefore, while RG is often associated with livestock health improvement, this perceived benefit may diminish with herd size.

We also observed regional differences in producers' benefit perceptions, which is consistent with previous studies that found producer willingness to adopt RG, level of RG intensity and perceived RG profitability varied by region (Kim et al., Reference Kim, Gillespie and Paudel2005; Pruitt et al., Reference Pruitt, Gillespie, Nehring and Qushim2012; Jensen et al., Reference Jensen, Lambert, Clark, Holt, English, Larson, Yu and Hellwinckel2015; Sitienei et al., Reference Sitienei, Gillespie and Scaglia2019). For example, differences in soil quality can affect the advantage of RG relative to CG. Our findings indicate that producers with poorer quality land are more likely to perceive RG-related benefits. Similar to our findings, Sherren and Kent (Reference Sherren and Kent2019) indicated that MIG is more advantageous in areas with poorer soils that exhibit less soil biota and slower nutrient cycling.

While our study enhanced the understanding of livestock producers' perspectives about RG benefits, it had some limitations and indicated some areas for future research. RG practices span a continuum of intensities; in our study, we include only two categories, extensive RG and MIG. Differentiation of RG into more explicit categories of grazing management intensity and adaptation capacity is important if the benefits and limitations of various types of RG are to be properly understood. Future studies could benefit by incorporating a wider range of RG strategies. Additionally, inclusion of a greater number of MIG adopters and grass-finished beef producers could fill knowledge gaps about the advantages of investing in grazing management intensification. Finally, research about effective information exchange platforms to help non-adopters make more informed decisions and to adopt more intensive grazing management strategies could facilitate improved management of grasslands more broadly.

Conclusion

We surveyed producers from the Northern and Southern Great Plains to understand their perceptions about the benefits of RG and MIG. Among the RG adopters, the majority (89%) implemented the practice in an extensive manner and only 11% adopted MIG. We found that producers who had adopted MIG generally provided higher ratings for RG benefits, but this practice has a low adoption rate indicating that it is underutilized. We also found that producers who prioritized grassland and soil improvement, those with more owned land and those with more formal education perceived significantly greater benefits from RG.

Our results demonstrated that while RG and MIG adopters in our study area perceive greater benefits than do CG producers, a high proportion (nearly 60%) of CG producers also perceived medium or significant benefits of RG in terms of providing faster drought recovery, increasing percentage of desirable grass and increasing stocking capacity. We found that the relative benefits perceived by RG adopters vary across heterogeneous geographic conditions. Specifically, perceived RG benefits were more pronounced in warmer, drier and more drought-prone areas within our survey region, which spanned mostly moderate precipitation areas. These perceived benefits are also more pronounced on poorer quality land that is not suitable for crop cultivation.

Grazing management terminology has generally conflated different grazing management approaches and needs to be refined to compare outcomes of studies that include different RG approaches. Our findings that MIG producers perceive more benefits than extensive RG suggest that lumping studies with low- and high-intensity RG management strategies, as has been done in some review articles, could lead to misleading conclusions about the benefits of RG. Careful definition and differentiation of the RG into more explicit categories of grazing management intensity and adaptation capacity is imperative if the benefits and limitations of various types of RG are to be properly understood.

The finding that a high proportion of CG producers also perceived medium or significant benefits related to RG suggests that the primary factors that hinder producers from adopting RG might not be lack of perceived benefits, but rather unresolved resource constraints, including labor and water. Therefore, to overcome potential barriers to RG adoption, technical and financial support and farm demonstrations may be critical. Finally, varying RG benefits across heterogeneous regions suggest that besides addressing the contextual differences between scientific studies and commercial ranching experiences, future research should emphasize the role of soil and climate disparities on the relative benefits of RG grazing strategies, especially MIG. Ultimately, it could be more cost-effective to promote intensified grazing management in regions where its benefits are most pronounced and salient.

Acknowledgements

This work was supported by the National Institute of Food and Agriculture, US Department of Agriculture, under award number 2017-67024-26279. We express our sincere gratitude to Iftekhar Uddin Ahmed Chowdhury for his valuable research assistance. We thank Dr David Hennessy and Dr Hongli Feng for their help in developing the survey questionnaire, and Yuyuan Che for her help in matching survey data with geo-climatic variables. We also thank Dr Srini Ale; Tanse Herrmann, NRCS district conservationist; Tate Lantz, NRCS assistant state conservationist; as well as Todd Trask, Charles Totton and Tanya Totton, South Dakota ranchers, for their valuable suggestions to improve the questionnaire. We also owe a debt of gratitude to 875 agricultural producers from North Dakota, South Dakota and Texas for providing us with the original data to carry out this research.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S1742170521000260.

Footnotes

¹ Note that ρ_ik stands for the correlation coefficients between benefit i and k, with the benefit numbered Table 3.

References

Acharya, M, Burke, JM, Wood, E and Yancey, J (2020) Developing criteria for forage finished beef in the Southeastern US. Journal of Animal Science 98, 30–30.10.1093/jas/skz397.069CrossRef Google Scholar

Archer, S and Stokes, C (2000) Stress, distribution and change in rangeland ecosystems. In Olafur A and Archer S (eds), Rangeland Desertification. Dordrecht, The Netherlands: Kluwer Academic Publishers, pp. 17–38.Google Scholar

Ball, D, Ballard, EN, Kennedy, M, Lacefield, GD and Undersander, D (2008) Extending Grazing and Reducing Stored Feed Needs. Bryan, TX: Grazing Lands Conservation Initiative Publication 8-01.Google Scholar

Barnes, MK, Norton, BE, Maeno, M and Malechek, JC (2008) Paddock size and stocking density affect spatial heterogeneity of grazing. Rangeland Ecology & Management 61, 380–388.10.2111/06-155.1CrossRef Google Scholar

Barton, E, Bennett, DE and Burnidge, W (2020) Holistic perspectives—understanding rancher experiences with holistic resource management to bridge the gap between rancher and researcher perspectives. Rangelands 42, 143–150.10.1016/j.rala.2020.05.003CrossRef Google Scholar

Bates, H and Arbuckle, JG Jr (2017) Understanding predictors of nutrient management practice diversity in Midwestern agriculture. Journal of Extension 55, 6FEA5.Google Scholar

Becker, W, Kreuter, U, Atkinson, S and Teague, R (2017) Whole-ranch unit analysis of multipaddock grazing on rangeland sustainability in North Central Texas. Rangeland Ecology & Management 70, 448–455.10.1016/j.rama.2016.12.002CrossRef Google Scholar

Briske, DD, Derner, JD, Brown, JR, Fuhlendorf, SD, Teague, WR, Havstad, KM, Gillen, RL, Ash, AJ and Willms, WD (2008) Rotational grazing on rangelands: reconciliation of perception and experimental evidence. Rangeland Ecology & Management 61, 3–17.10.2111/06-159R.1CrossRef Google Scholar

Cox, E (2010) The landowner's guide to sustainable farm leasing. Available at https://lib.dr.iastate.edu/cgi/viewcontent.cgi?article=1099&context=leopold_pubspapers (Accessed 8 May 2021).Google Scholar

DeLonge, M (2017) Reintegrating land and livestock: agroecological solutions to beef system challenges. Union of Concerned Scientists. Available at http://www.ucsusa.org/landandlivestock (Accessed 8 May 2021).Google Scholar

Díaz-Solís, H, Grant, WE, Kothmann, MM, Teague, WR and Díaz-García, JA (2009) Adaptive management of stocking rates to reduce effects of drought on cow-calf production systems in semi-arid rangelands. Agricultural Systems 100, 43–50.10.1016/j.agsy.2008.12.007CrossRef Google Scholar

Dillman, DA (1978) Mail and Telephone Surveys: The Total Design Method, vol. 19. New York: Wiley.Google Scholar

Drake Agricultural Law Center (DALC) (2012) Rotational grazing on leased land. Available at: https://www.leopold.iastate.edu/files/pubs-and-papers/2012-10-rotational-grazing-leased-land.pdf. Accessed on September 13, 2019.Google Scholar

di Virgilio, A, Lambertucci, SA and Morales, JM (2019) Sustainable grazing management in rangelands: over a century searching for a silver bullet. Agriculture, Ecosystems & Environment 283, 106561.10.1016/j.agee.2019.05.020CrossRef Google Scholar

Earl, JM and Jones, CE (1996) The need for a new approach to grazing management-is cell grazing the answer? The Rangeland Journal 18, 327–350.10.1071/RJ9960327CrossRef Google Scholar

Foltz, J and Lang, G (2005) The adoption and impact of management intensive rotational grazing (MIRG) on Connecticut dairy farms. Renewable Agriculture and Food Systems 20, 261–266.10.1079/RAF2005127CrossRef Google Scholar

Fuhlendorf, SD and Engle, DM (2001) Restoring heterogeneity on rangelands: ecosystem management based on evolutionary grazing patterns: we propose a paradigm that enhances heterogeneity instead of homogeneity to promote biological diversity and wildlife habitat on rangelands grazed by livestock. BioScience 51, 625–632.10.1641/0006-3568(2001)051[0625:RHOREM]2.0.CO;2CrossRef Google Scholar

Garnett, T, Godde, C, Muller, A, Röös, E, Smith, P, De Boer, IJM, zu Ermgassen, E, Herrero, M, Van Middelaar, CE, Schader, C and Van Zanten, HHE (2017) Grazed and confused?: ruminating on cattle, grazing systems, methane, nitrous oxide, the soil carbon sequestration question-and what it all means for greenhouse gas emissions. Food Climate Research Network. Available at https://library.wur.nl/WebQuery/wurpubs/fulltext/427016 (Accessed 8 May 2021).Google Scholar

Gerrish, J (2004) Management-Intensive Grazing: The Grassroots of Grass Farming. Ridgeland: Green Park Press.Google Scholar

Godde, CM, Boone, RB, Ash, AJ, Waha, K, Sloat, LL, Thornton, PK and Herrero, M (2020) Global rangeland production systems and livelihoods at threat under climate change and variability. Environmental Research Letters 15, 044021.10.1088/1748-9326/ab7395CrossRef Google Scholar

Gosnell, H, Grimm, K and Goldstein, BE (2020) A half century of Holistic Management: what does the evidence reveal? Agriculture and Human Values 37, 849–867.10.1007/s10460-020-10016-wCrossRef Google Scholar

Greene, WH (2012) Econometric Analysis, 7th edn. Pearson Education Limited, pp. 728–730.Google Scholar

Hanson, GD, Ford, SA, Parsons, RL, Cunningham, LC and Muller, LD (1998) Increasing intensity of pasture use with dairy cattle: an economic analysis. Journal of Production Agriculture 11, 175–179.10.2134/jpa1998.0175CrossRef Google Scholar

Harris, RB (2010) Rangeland degradation on the Qinghai-Tibetan plateau: a review of the evidence of its magnitude and causes. Journal of Arid Environments 74, 1–12.10.1016/j.jaridenv.2009.06.014CrossRef Google Scholar

Hawkins, HJ (2017) A global assessment of Holistic Planned Grazing™ compared with season-long, continuous grazing: meta-analysis findings. African Journal of Range & Forage Science 34, 65–75.CrossRef Google Scholar

Heiberg, EJ and Syse, KL (2020) Farming autonomy: Canadian beef farmers reclaiming the grass through management-intensive grazing practices. Organic Agriculture 10, 471–486.CrossRef Google Scholar

Hill, AE, Green, AL, Wagner, BA and Dargatz, DA (2009) Relationship between herd size and annual prevalence of and primary antimicrobial treatments for common diseases on dairy operations in the United States. Preventive Veterinary Medicine 88, 264–277.CrossRef Google Scholar PubMed

Illius, AW and O'Connor, TG (1999) On the relevance of nonequilibrium concepts to arid and semiarid grazing systems. Ecological Applications 9, 798–813.CrossRef Google Scholar

Jakoby, O, Quaas, MF, Müller, B, Baumgärtner, S and Frank, K (2014) How do individual farmers’ objectives influence the evaluation of rangeland management strategies under a variable climate? Journal of Applied Ecology 51, 483–493.CrossRef Google Scholar

Jakoby, O, Quaas, MF, Baumgärtner, S and Frank, K (2015) Adapting livestock management to spatio-temporal heterogeneity in semi-arid rangelands. Journal of Environmental Management 162, 179–189.CrossRef Google Scholar PubMed

Jensen, KL, Lambert, DM, Clark, CD, Holt, C, English, BC, Larson, JA, Yu, TE and Hellwinckel, C (2015) Cattle producers’ willingness to adopt or expand prescribed grazing in the United States. Journal of Agricultural and Applied Economics 47, 213–242.CrossRef Google Scholar

Julien, DJ and Tess, MW (2002) Effects of breeding date, weaning date, and grazing season length on profitability of cow-calf production systems in southeastern Montana. Journal of Animal Science 80, 1462–1469.CrossRef Google Scholar PubMed

Kim, S, Gillespie, JM and Paudel, KP (2005) The effect of socioeconomic factors on the adoption of best management practices in beef cattle production. Journal of Soil and Water Conservation 60, 111–120.Google Scholar

Kim, S, Gillespie, JM and Paudel, KP (2008) Rotational grazing adoption in cattle production under a cost-share agreement: does uncertainty have a role in conservation technology adoption? Australian Journal of Agricultural & Resource Economics 52, 235–252.CrossRef Google Scholar

Klingebiel, AA (1961) Land-capability classification (No. 210). Soil Conservation Service, US Department of Agriculture.Google Scholar

Kumar, S, Sieverding, H, Lai, L, Thandiwe, N, Wienhold, B, Redfearn, D, Archer, D, Ussiri, D, Faust, D, Landblom, D and Grings, E (2019) Facilitating crop–livestock reintegration in the Northern Great Plains. Agronomy Journal 111, 2141–2156.CrossRef Google Scholar

Lawrence, R, Whalley, RDB, Reid, N and Rader, R (2019) Short-duration rotational grazing leads to improvements in landscape functionality and increased perennial herbaceous plant cover. Agriculture, Ecosystems & Environment 281, 134–144.CrossRef Google Scholar

McIvor, JG (2007) Pasture management in semi-arid tropical woodlands: dynamics of perennial grasses. The Rangeland Journal 29, 87–100.CrossRef Google Scholar

Norton, BE, Barnes, M and Teague, R (2013) Grazing management can improve livestock distribution: increasing accessible forage and effective grazing capacity. Rangelands 35, 45–51.CrossRef Google Scholar

Oates, LG, Undersander, DJ, Gratton, C, Bell, MM and Jackson, RD (2011) Management-intensive rotational grazing enhances forage production and quality of subhumid cool-season pastures. Crop Science 51, 892–901.CrossRef Google Scholar

Pinchak, WE, Teague, WR, Ansley, RJ, Waggoner, JA and Dowhower, SL (2010) Integrated grazing and prescribed fire restoration strategies in a mesquite savanna: III. Ranch-scale cow–calf production responses. Rangeland Ecology & Management 63, 298–307.CrossRef Google Scholar

Provenza, F, Pringle, H, Revell, D, Bray, N, Hines, C, Teague, R, Steffens, T and Barnes, M (2013) Complex creative systems: principles, processes, and practices of transformation. Rangelands 35, 6–13.CrossRef Google Scholar

Pruitt, JR, Gillespie, JM, Nehring, RF and Qushim, B (2012) Adoption of technology, management practices, and production systems by US beef cow-calf producers. Journal of Agricultural and Applied Economics 44, 203–222.CrossRef Google Scholar

Riely, A (2011) The grass-fed cattle-ranching niche in Texas. Geographical Review 101, 261–268.CrossRef Google Scholar

Roche, LM, Cutts, BB, Derner, JD, Lubell, MN and Tate, KW (2015) On-ranch grazing strategies: context for the rotational grazing dilemma. Rangeland Ecology & Management 68, 248–256.CrossRef Google Scholar

Roodman, D (2011) Fitting fully observed recursive mixed-process models with cmp. The Stata Journal 11, 159–206.CrossRef Google Scholar

Savory, A (1983) The savory grazing method or holistic resource management. Rangelands Archives 5, 155–159.Google Scholar

Savory, A and Butterfield, J (2016) Holistic Management, 3rd Edn. Washington, DC: Island Press.Google Scholar

Schuman, GE, Janzen, HH and Herrick, JE (2002) Soil carbon dynamics and potential carbon sequestration by rangelands. Environmental Pollution 116, 391–396.CrossRef Google Scholar

Sherren, K and Kent, C (2019) Who's afraid of Allan Savory? Scientometric polarization on Holistic Management as competing understandings. Renewable Agriculture and Food Systems 34, 77–92.CrossRef Google Scholar

Sitienei, I, Gillespie, J and Scaglia, G (2019) Forage management practices used in production of US grass-fed beef. Applied Animal Science 35, 535–542.CrossRef Google Scholar

Stahl, TJ, Conlin, BJ, Seykora, AJ and Steuernagel, GR (1999) Characteristics of Minnesota dairy farms that significantly increased milk production from 1989–1993. Journal of Dairy Science 82, 45–51.CrossRef Google Scholar PubMed

Stinner, DH, Stinner, BR and Martsolf, E (1997) Biodiversity as an organizing principle in agroecosystem management: case studies of holistic resource management practitioners in the USA. Agriculture, Ecosystems & Environment 62, 199–213.CrossRef Google Scholar

Sugita, M, Asanuma, J, Tsujimura, M, Mariko, S, Lu, M, Kimura, F, Azzaya, D and Adyasuren, T (2007) An overview of the rangelands atmosphere–hydrosphere–biosphere interaction study experiment in northeastern Asia (RAISE). Journal of Hydrology 333, 3–20.CrossRef Google Scholar

Teague, R and Barnes, M (2017) Grazing management that regenerates ecosystem function and grazing land livelihoods. African Journal of Range & Forage Science 34, 77–86.CrossRef Google Scholar

Teague, WR and Foy, JK (2004) Can the SPUR rangeland simulation model enhance understanding of field experiments? Arid Land Research and Management 18, 217–228.CrossRef Google Scholar

Teague, R and Kreuter, U (2020) Managing grazing to restore soil health. Ecosystem Function, and Ecosystem Services. Frontiers in Sustainable Food Systems 4, 157.Google Scholar

Teague, WR, Dowhower, SL and Waggoner, JA (2004) Drought and grazing patch dynamics under different grazing management. Journal of Arid Environments 58, 97–117.CrossRef Google Scholar

Teague, WR, Dowhower, SL, Baker, SA, Haile, N, DeLaune, PB and Conover, DM (2011) Grazing management impacts on vegetation, soil biota and soil chemical, physical and hydrological properties in tall grass prairie. Agriculture, Ecosystems & Environment 141, 310–322.CrossRef Google Scholar

Teague, R, Provenza, F, Kreuter, U, Steffens, T and Barnes, M (2013) Multi-paddock grazing on rangelands: why the perceptual dichotomy between research results and rancher experience? Journal of Environmental Management 128, 699–717.CrossRef Google Scholar PubMed

Undersander, DJ, Albert, B, Cosgrove, D, Johnson, D and Peterson, P (2002) Pastures for Profit: A Guide to Rotational Grazing. Produced by Cooperative Extension Publishing, University of Wisconsin-Extension, Madison, WI. Edited by Linda Deith and designed by Susan Anderson.Google Scholar

Venter, ZS, Cramer, MD and Hawkins, HJ (2019) Rotational grazing management has little effect on remotely-sensed vegetation characteristics across farm fence-line contrasts. Agriculture, Ecosystems & Environment 282, 40–48.CrossRef Google Scholar

Vetter, S, Goqwana, WM, Bond, WJ and Trollope, WW (2006) Effects of land tenure, geology and topography on vegetation and soils of two grassland types in South Africa. African Journal of Range and Forage Science 23, 13–27.CrossRef Google Scholar

WallisDeVries, MF, Laca, EA and Demment, MW (1999) The importance of scale of patchiness for selectivity in grazing herbivores. Oecologia 121, 355–363.CrossRef Google Scholar PubMed

Wang, T, Teague, R and Park, SC (2016) Evaluation of the consequences of continuous and multi-paddock grazing on vegetation and livestock performance—a modeling approach. Rangeland Ecology & Management 69, 457–464.CrossRef Google Scholar

Wang, T (2019) Evaluating extension program impacts through comparison of knowledge and behavior of extension clientele versus others. Journal of Extension 57, 4R1B1.Google Scholar

Wang, T, Teague, WR, Park, SC and Bevers, S (2018) Evaluating long-term economic and ecological consequences of continuous and multi-paddock grazing-a modeling approach. Agricultural Systems 165, 197–207.CrossRef Google Scholar

Wang, T, Jin, H, Kreuter, U, Feng, H, Hennessy, DA, Teague, R and Che, Y (2020) Challenges for rotational grazing practice: views from non-adopters across the Great Plains, USA. Journal of Environmental Management 256, 109941.CrossRef Google Scholar PubMed

Whitson, RE, Heitschmidt, RK, Kothmann, MM and Lundgren, GK (1982) The impact of grazing systems on the magnitude and stability of ranch income in the rolling plains of Texas. Rangeland Ecology & Management/Journal of Range Management Archives 35, 526–532.CrossRef Google Scholar

Wilmer, H, Augustine, DJ, Derner, JD, Fernández-Giménez, ME, Briske, DD, Roche, LM, Tate, KW and Miller, KE (2018) Diverse management strategies produce similar ecological outcomes on ranches in Western Great Plains: social-ecological assessment. Rangeland Ecology & Management 71, 626–636.CrossRef Google Scholar

Windh, JL, Ritten, JP, Derner, JD, Paisley, SI and Lee, BP (2019) Economic cost analysis of continuous-season-long versus rotational grazing systems. Western Economics Forum 17, 62–72.Google Scholar

Witten, GQ, Richardson, FD and Shenker, N (2005) A spatial-temporal analysis on pattern formation around water points in a semi-arid rangeland system. Journal of Biological Systems 13, 59–81.CrossRef Google Scholar

Wolf, KM and Horney, MR (2016) Revisiting the rotational and continuous grazing system debate via meta-analysis. In: Wolf K.M. Examinations of the ecology, management, and restoration of rangeland ecosystems (PhD thesis), University of California-Davis, USA. pp. 20–146.Google Scholar

Woodis, JE and Jackson, RD (2009) Subhumid pasture plant communities entrained by management. Agriculture, Ecosystems & Environment 129, 83–90.CrossRef Google Scholar