Chronic, Intensive Grazing

Chronic, intensive grazing is detrimental to plants because it removes leaf area that is necessary to absorb photosynthetically active radiation and convert it to chemical energy (Caldwell et al. 1981; Briske and Richards 1995). This reduction in energy harvest is manifest in all aspects of plant growth and function because photosynthesis provides the total energy and carbon source for growth. A chronic, intensive reduction in photosynthetic leaf area negatively impacts root systems by reducing energy available to support existing root biomass and new root production. Root mass, branch number, vertical and horizontal root distribution, and root longevity all may be reduced by chronic, intensive defoliation (Hodgkinson and Bass Becking 1977). This reduces the ability of severely grazed plants to effectively access soil water and nutrients that often limit plant growth on rangelands.

Rest and deferment is the antithesis of this principle, which indicates that periodic cessation of grazing, especially during periods of rapid growth, will enhance both shoot and root growth by promoting the recovery and maintenance of greater leaf area (Holechek et al. 2001). Rest and deferment to promote plant growth is the most fundamental and long-standing corollary of the unifying principles and it represents a central assumption of all grazing systems.

Primary Productivity

Grazing was assumed to have a negative effect on primary production throughout much of the history of the rangeland profession for reasons described in the previous section. Therefore, an important goal of early range management was to implement grazing in a way that would minimize negative effects on both plant production and species composition. The potential for grazing to increase plant production was not considered a viable option (Ellison 1960) until the 1970s when ecologists introduced the grazing optimization hypothesis. This hypothesis indicates that primary production increases above that of ungrazed vegetation as grazing intensity increases to an optimal level followed by a decrease at greater grazing intensities (McNaughton 1979). Evidence exists to support the occurrence of the grazing optimization hypothesis at both the plant and community levels (Belsky 1986; Milchunas and Lauenroth 1993), and several potential mechanisms have been hypothesized and tested (McNaughton 1983).

However, grazing increased primary production in only approximately 20% of the comparisons evaluated (Belsky 1986; Milchunas and Lauenroth 1993). Presumably grazing was too intensive to promote compensatory growth, and this is often the case in commercial grazing systems (McNaughton 1993). The grazing pattern required to increase primary production has been compared to that of migratory herbivores because it is associated with a period of intensive grazing, often early in the season, followed by a long period of little or no grazing (Frank and McNaughton 1993). As a result, an absolute increase in plant growth is seldom documented in grazing ecosystems because plants do not have a sufficient opportunity for recovery following defoliation, and primary production generally decreases with increasing grazing severity compared to that of ungrazed communities (Milchunas and Lauenroth 1993).

Forage Quality

Forage quality determines the amount of energy and nutrients that herbivores can acquire from ingested forage, and it varies with several well-recognized plant characteristics. Tissue age, tissue type, functional plant group, and anti-quality agents (e.g., lignin, cellulose, secondary compounds) represent several of the more widely recognized characteristics (Van Soest 1982; Huston and Pinchak 1991). These characteristics primarily affect forage quality by influencing the ratio of cell soluble (e.g., amino acids, proteins, lipids, starch) to cell structural (e.g., hemicellulose, cellulose, lignin, silica) components within plant tissues. Tissues with the highest soluble to structural ratio typically possess the highest forage quality and are often the most preferred by grazing animals. Secondary compounds function as anti-quality agents to reduce forage quality of both herbaceous and woody dicots, but are generally less important in deterring herbivory in monocots (McNaughton 1983; Vicari and Bazely 1993). The ratio of soluble to structural cellular components decreases as mean tissue age increases throughout the growing season. Frequent grazing reduces this tendency by increasing the proportion of younger plant tissues with higher soluble to structural ratios (Walker et al. 1989; Georgiadis and McNaughton 1990). This explains the frequent occurrence of patch grazing where animals repeatedly graze the same area to optimize energy and nutrient intake per unit plant biomass even though total biomass may be substantially lower than in less frequently grazed patches (McNaughton 1984).

Forage quality is an important consideration in the design and implementation of grazing systems, and it is influenced by the length of both the grazing and the rest periods between subsequent grazing events. Animal performance declined linearly with increasing length of grazing period and length of rest period in a rotational grazing study in South African rangeland (Denny and Barnes 1977). A long rest period or a low grazing pressure allows plant tissues to mature and forage quality to decrease compared to more frequent grazing intervals.

Community Composition

Grazing induced modification of species composition originates from the species-specific reduction of leaf area and whole plant photosynthesis previously discussed (Briske and Richards 1995; Illius and O'Connor 1999). Selective grazing of individual species or species groups places them at a competitive disadvantage with less severely grazed species or species groups and alters competitive interactions and species composition within communities (Anderson and Briske 1995). The first quantitative procedure to evaluate the effect of grazing on community composition was based on recognition that selective grazing disproportionately affects some plant groups more than others. Dyksterhuis (1949) formally introduced the concept of increaser, decreaser, and invader plant response groups, but specific patterns of vegetation response to grazing had been recognized by many of his predecessors, including Arthur Sampson (Sampson 1919). These response groups are a function of a plant's ability to avoid or tolerate grazing. These plant response groups are based on the expression of numerous plant traits, but plant height and meristem location and number appear to be among the most important. For example, plant height during various stages of phenological development influences both the frequency and intensity of defoliation, and the corresponding location and number of remaining meristems determine the rate at which leaf area is replaced (Briske and Richards 1995; Díaz et al. 2001).

Community composition is further modified by the occurrence of heterogeneous grazing patterns through time and space (Willms et al. 1988; O'Connor 1992; Bailey et al. 1996; McIvor et al. 2005), and heterogeneity often increases with increasing size of management units (Senft et al. 1985; Stuth 1991; Bailey et al. 1996). Preferential use of specific patches results in uneven animal distribution, which increases the stocking rate on preferred patches compared to the entire management unit (Fuhlendorf and Engle 2001, 2004). Animal selection is minimally affected by small-scale heterogeneity at the feeding station level, but it is profoundly affected by large-scale heterogeneity at the landscape level; therefore, both the size and spatial arrangement of grazed patches are major components of selective grazing (Wallis de Vries and Schippers 1994; Wallis de Vries et al. 1999). Grazing patterns within landscapes are strongly influenced by the spatial distribution of topography, water, cover, minerals, and inter- and intraspecific animal interactions (Coughenour 1991). In time, heterogeneous use of rangelands may alter the spatial and temporal variability of primary production, and it may intensify localized herbivore impacts (Fuls 1992; Kellner and Bosch 1992; Illius and O'Connor 1999). A shifting mosaic of intensively grazed and underutilized patches may be critical to the maintenance of structural heterogeneity and biological diversity of rangeland ecosystems (Fuhlendorf et al. 2006).

The fundamental question is this: Do these unified principles of vegetation response to grazing determine that rotational grazing is superior to continuous grazing? If not, why not? Answers to these questions will provide a greater understanding of the perceptions and assumptions underlying continued support for rotational grazing.

Presumed Benefits of Rotational Grazing Were Overextended

The absence of observed benefits of rotational over continuous grazing in experimental research indicates that many of the anticipated benefits of rotational systems have not been realized (O'Reagain and Turner 1992). For example, experimental evidence indicates that defoliation is not always controlled more effectively in rotational grazing systems than in continuous grazing (Gammon and Roberts 1978a, 1978b, 1978c; Hart et al. 1993b) and that forage quality and quantity are not consistently and substantially increased in intensive systems compared to continuous grazing (Denny and Barnes 1977; Walker et al. 1989; Holechek et al. 2000). This further substantiates the notion that rotational grazing may have been introduced with heightened and unrealistic expectations that were not founded on evidence-based recommendations (e.g., Heady 1961).

Expectations of grazing systems may have been inadvertently heightened by the critical need to promote the sustainable use and recovery of rangelands damaged by excessive grazing early in the 20th century (Smith 1896; Sampson 1951; Hart and Norton 1988). The critical interpretation of continuous grazing, prompted by excessive stocking rates that were common prior to the implementation of proper grazing management, may still be promulgated today. The high stocking rates common to the late 19th and early 20th centuries were unsustainable, and the negative consequences of those high stocking rates should not be interpreted as a condemnation of continuous grazing at appropriate stocking rates (e.g., Ash and Stafford Smith 1996; Gillen and Sims 2006; Jacobo et al. 2006).

Ecological Constraints Occur in All Grazed Ecosystems

A fundamental ecological explanation for why the unifying principles of vegetation responses to grazing do not support greater effectiveness of rotational grazing is that grazing management must optimize several competing ecological processes to attain production goals sustainably. Grazing management must optimize both residual leaf area to maintain plant productivity and forage utilization to yield sufficient animal nutrition and production on an area basis (Parsons et al. 1983; Briske and Heitschmidt 1991). This fundamental management dilemma places similar constraints on all grazed ecosystems and limits the potential benefits derived from the spatial and temporal redistribution of grazing pressure for any given stocking rate.

Low stocking rates or grazing pressures promote plant production by maintaining high leaf area per unit land area. However, a relatively small proportion of this production is harvested by livestock, and the majority senesces and decomposes without being consumed (Fig. 2). This will effectively promote conservation goals over short-term economic profitability, which may be a viable management alternative on some rangelands. Higher stocking rates reduce plant production by decreasing leaf area per unit ground area, but both the percentage and absolute amount of plant production harvested by livestock increases. Extremely high stocking rates are associated with very high forage utilization, but plant production is reduced so severely that even these high rates of utilization do not provide sufficient forage and animal production declines. In addition to suppressed plant and animal production, excessive stocking rates are often unsustainable from the perspective of desired plant species composition, soil stability, and hydrological function (Thurow 1991; Milton et al. 1994).

Figure 2

Illustration of the consequences of (A) low and (B) high stocking rate on energy partitioning (kg C ˙ ha⁻¹ ˙d⁻¹) between plant production and forage utilization by livestock in grazed ecosystems. Leaf area index (LAI) and forage utilization are interrelated so that neither can be optimized independently; rather, both must be simultaneously optimized to sustain plant and animal production. This fundamental requirement to balance plant growth and forage consumption by livestock partially explains why grazing research has found stocking rate to affect plant and animal response variables to a greater extent than grazing system on rangelands (redrawn from Parsons et al. 1983).

The ability to optimize plant production and forage harvest takes on even greater complexity on rangelands because the periodicity and predictability of plant growth are constrained by limited and erratic precipitation. As aridity increases and the duration and predictability of plant growth decreases, the potential benefit derived from the redistribution of grazing pressure in space and time becomes less important (Taylor et al. 1993; Holechek et al. 2001; Ward et al. 2004). Consider a situation in which the grazing season is 200 days, but the cumulative period of plant growth, scattered over several periods of various duration (i.e., primarily early and late in the season), is only 65 days (Fig. 3). Stocking rate must be adjusted, regardless of grazing system, to maintain sufficient forage to carry livestock through periods of minimal plant growth. In addition, rest and deferment during periods of minimal plant growth, associated with low soil water availability or temperature extremes, limit the potential for positive vegetation responses (Heitschmidt et al. 2005; Gillen and Sims 2006). Conditions of limited and erratic precipitation and productivity are the rule, rather than the exception, on most rangelands throughout the world. This interpretation indicates why the redistribution of grazing pressure conveys only a minor contribution to plant and animal production in grazed ecosystems compared to the variables of weather and stocking rate (e.g., O'Reagain and Turner 1992; Ash and Stafford Smith 1996; Gillen and Sims 2006).

Figure 3

Depiction of how infrequent and unpredictable rainfall and corresponding periods of plant growth can minimize the benefits of rest on vegetation responses in rotational grazing systems. Rest periods that coincide with limited plant growth convey minimal benefit to plants so that the impacts of increased grazing pressure during short grazing periods may not be offset during subsequent rest periods. This represents the most plausible ecological explanation for why grazing research has found the redistribution of grazing pressure to be of minimal benefit to vegetation compared to continuous grazing on rangelands.

The ecological dynamics and managerial challenges characteristic of most rangelands are very different from those associated with high and consistent plant production of mesic pasture systems, in which the principles of rotational grazing were initially devised (e.g., Voisin 1959; Heady 1970; Robson 1973; Woledge 1978). An overestimation of the presumed benefits of rest from grazing, within the framework of rotational grazing systems (e.g., several weeks rest between brief and often intensive grazing periods), may represent the primary misconception underlying continued advocacy for rotational grazing on rangelands (e.g., Taylor et al. 1993; Holechek et al. 2001; Gillen and Sims 2006). We fully appreciate that longer-term rest and reduced stocking, especially during conditions favorable to plant growth, contribute to the sustainability and recovery of grazed ecosystems (e.g., Holechek et al. 1999; Müller et al. 2007).

Context of Experimental Research

Grazing research has not adequately assessed the effects of grazing at large scales (Fuls 1992; O'Connor 1992; Bailey et al. 1996; Archibald et al. 2005), which often demonstrates the occurrence of patch- and area-specific grazing. Smaller experimental pastures usually result in more uniform distribution of grazing pressure, which may not appropriately describe how domestic grazing animals utilize large landscapes or, in the case of native ungulates, how they migrate regionally. Teague and others (Teague and Dowhower 2003; Teague et al. 2004) demonstrated that rest periods associated with rotational grazing facilitated an improvement in plant species composition of frequently grazed patches relative to continuously grazed areas at the same stocking rate in large management units (1 500–2 000 ha). The direct application of research results obtained in small-scale experiments (< 200 ha; Appendix I) to large ranch enterprises may not be entirely appropriate because the ecological processes of interest often do not scale in a linear fashion (Fuhlendorf and Smeins 1999). Evidence documenting the occurrence of beneficial grazing system effects at large scales, in the absence of comparable responses at smaller scales, has not been rigorously evaluated.

Failure to consider the time required for ecosystems to adjust to changes in management regimes may potentially mask ecosystem responses to the implementation of grazing systems. Several years may be required for some variables to adjust and show a response to the new management regime (Provenza 2003). Research experiments that operate for short periods following treatment imposition may largely capture the period of system adaptation and underestimate the long-term potential of grazing systems. However, several well-designed comparisons of rotational and continuous grazing have been conducted for 8–25 years without documenting a substantial change in the trajectory of plant and animal response variables (Hart et al. 1993a, 1993b; Derner et al. 1994; Manley et al. 1997; Gillen et al. 1998; McCollum and Gillen 1998; Derner and Hart 2007).

Experimental grazing research embodies a fundamental tradeoff between a robust assessment of ecological processes and the ability to mimic the responses associated with adaptive management. Research protocol requires that grazing experiments be structured in a manner that minimizes both ecological and managerial variability to effectively test hypotheses that enhance our understanding of critical ecological processes operating in grazed ecosystems. These research requirements do not allow grazing experiments to necessarily mimic management activities targeting production or conservation goals at the ranch enterprise (Heady 1970). Grazing treatments are often applied on a more rigid schedule to ensure experimental integrity and repeatability compared to commercial systems that are adaptively managed. Jacobo and others (2006) have partially documented the importance of adaptive management to grazing system effectiveness in ranch-scale comparisons of rotational and continuous grazing in the flooding pampas of Argentina.

Conservation Goals

Rangeland ecosystems are capturing greater public attention with growing recognition of the variety of products and services they provide (Havstad et al. 2007). These ecosystems are increasingly recognized as sources of water, biodiversity, recreation, aesthetics, wildlife habitat, carbon sequestration, and residential sites, in addition to livestock products. Conservation goals often emerge at large scales, and even though the flexibility associated with rotational grazing systems can provide managers with opportunities to manipulate grazing frequency, intensity, and seasonality to pursue specific conservation goals (e.g., bird nesting success, periodic plant establishment or reproduction, fuel accumulation or suppression), there has not yet been a comprehensive accounting of the conservation effects associated with the large-scale adoption of grazing systems. The majority of grazing experiments have not collected the appropriate variables, at the appropriate scale, to evaluate environmental quality and conservation issues (but see Hickman et al. 2004).

The response of soil hydrological characteristics represents an important exception to this generalization based on a substantial number of experimental investigations conducted in the 1970s and 1980s. The response of soil hydrological characteristics to grazing largely parallels those of other ecological variables in that stocking rate is the most important driver, irrespective of grazing system (Wood and Blackburn 1981; Thurow 1991). This occurs because the removal of large amounts of plant cover and biomass by intensive grazing reduces the potential to dissipate the energy of raindrop impact and overland flow. The erosive energy of water and the long-term reduction of organic matter additions to the soil detrimentally affect numerous soil properties, including increased bulk density, disruption of biotic crusts, reduced aggregate stability, and organic matter content, to reduce infiltration rate and increase sediment yield and runoff. Animal trampling is another source of mechanical energy that breaks soil aggregates and is therefore negatively correlated with maintenance of soil structure necessary for high infiltration rates (Warren et al. 1986; Thurow 1991; Holechek et al. 2000). These results refute prior claims that animal trampling associated with high stocking rates or grazing pressures in rotational grazing systems enhance soil properties and promote hydrological function (Savory and Parsons 1980; Savory 1988). However, soil properties and hydrological processes do appear to recover with prolonged grazing deferment following intensive grazing, and rotational grazing may maintain higher infiltration rates than continuous grazing at high stocking rates (Thurow et al. 1988; Thurow 1991). These hydrological responses to grazing are strongly contingent on community composition, with communities that provide greater cover and obstruction to overland flow such as midgrass-dominated communities having greater hydrological function, including infiltration rate, than short grass–dominated communities (Wood and Blackburn 1981; Thurow 1991). Grazing management appears to have the greatest potential to enhance hydrological function by facilitating improvement in herbaceous species composition of grazed ecosystems.

Involvement of Human Dimensions

This synthesis poses the hypothesis that the interface between human dimensions and grazing systems represents a major source of inconsistent interpretations regarding the potential benefits of grazing systems. This long-standing controversy very likely originates from managerial emphasis on the socioeconomic benefits of the ranch enterprise while research scientists focus on ecological processes associated with vegetation-soil-herbivore interactions of individual management units. It is not unexpected that inconsistent interpretations would result from the assessment of distinct goals, with different procedures, by groups with divergent perspectives. Management goals, abilities, and opportunities as well as personal goals and values (e.g., human dimensions) are inextricably integrated within grazing systems, and they are likely to interact with the adoption and operation of grazing systems to an equal or greater extent than the underlying ecological processes.

Although circumstantial evidence from successful grazing managers cannot be elevated to the status of experimental data, valuable insight can be gained by comparing the experiences of successful managers with relevant research results regardless of grazing system. Research is required to document these “success stories” and to direct the development of a more robust approach to understanding and implementing successful grazing management. A novel case study approach was adopted by Jacobo et al. (2006), who compared adjacent ranches that had employed either continuous or rotational grazing to achieve the optimal production outcome. The strength of this approach is that it enables researchers to evaluate the entire ranch enterprise, including the capacity to manage adaptively for the best possible outcomes, within the constraints of the respective grazing regime. This approach simultaneously evaluates ecological and managerial responses, but it has yet to be determined whether or not it will be possible to distinguish between them. Simulation modeling represents an additional and complementary research approach where cost and logistics preclude field experimentation over large spatial and temporal scales (e.g., Hahn et al. 1999; Beukes et al. 2002; Diaz-Solis et al. 2003; Teague and Foy 2004). This approach is well suited to evaluate the managerial and ecological components of grazing management, both independently and in combination. The potential synergistic effects of well-managed rotational grazing systems have not been examined experimentally at the level of the ranch enterprise (but see Jacobo et al. 2006).

It is disconcerting to realize that little progress has been made in our understanding of management contributions to the performance of grazing systems since Heady (1961) made this insightful observation nearly a half-century ago. Advocates of rotational grazing often support their perceptions by indicating the experimental grazing research is incorrect, rather than by evaluating and quantifying the potential merits of effective management and planning decisions. A quantitative accounting of the potential managerial contributions to the success of rotational grazing systems is a prerequisite for complete resolution of this controversy.