Crop residues and mulches

The CA concept adopts an element of the circular economy paradigm through the retention of crop residues as a mulch. This has been reported to support crop production through providing protection against soil erosion, improving infiltration and conserving soil moisture, suppressing weeds and supporting beneficial biodiversity (Ranaivoson et al., Reference Ranaivoson, Naudin, Ripoche, Affholder, Rabeharisoa and Corbeels2017). Nevertheless, it also has its limitations. Residue retention has not shown significant soil fertility improvements or reductions in inorganic fertilizer use. Moreover, residue load and type may impact subsequent crop establishment and thus need to be managed at critical levels to avoid trade-offs.

These limitations warrant investigating the option of using nutrient-rich cover crops as a mulch following termination. Mulched winter cover crops have been shown to increase soil nitrogen and organic carbon in numerous long-term studies (Vincent-Caboud et al., Reference Vincent-Caboud, Casagrande, David, Ryan, Silva and Peigne2019; Smit et al., Reference Smit, Strauss and Swanepoel2021). However, more research is needed to better understand the link between cover crop composition, in terms of the C-to-nitrogen (N) ratio, decomposition and mineralization dynamics in the context of hot, dry Mediterranean summers. Possible implications of mulching a high C:N, grass-dominated mix are slow decomposition and nutrient immobilization. Whereas, low C:N cover crops increase N availability for the cash crop, and while their fast decomposition is less likely to jeopardize subsequent planting (i.e. seed-drill obstruction when in zero-tillage system), their soil-protective benefits may be lessened.

The method and timing of termination of a cover crop need careful consideration to prevent the resurgence of cover crop species as volunteer weeds and ensure sufficient decomposition of the cover crop residue before planting the following crop. Non-chemical termination using a roller-crimper may be used successfully in Mediterranean regions (MacLaren et al., Reference MacLaren, Swanepoel, Bennett, Wright and Dehnen-Schmutz2019b); however, its effectiveness may be influenced by a number of factors. Soils with a high stone content have shown to reduce the stem crushing effect of the roller-crimper, rendering this approach unsuitable in these contexts. In dry years, cover crops may also not produce enough biomass to be effectively terminated by a roller-crimper (Vincent-Caboud et al., Reference Vincent-Caboud, Casagrande, David, Ryan, Silva and Peigne2019). In such cases, mowing or herbicides may be necessary; however, the attendant financial and ecological costs should be considered. Furthermore, successful termination with a roller-crimper also requires timing the rolling to coincide with the growth stage when the stems are susceptible to being crushed and before seed set (MacLaren et al., Reference MacLaren, Swanepoel, Bennett, Wright and Dehnen-Schmutz2019b). This may present additional management challenges when growing a cover crop mixture comprising varying growth cycles. Overall, roller-crimping as a termination method may also have non-nutritive advantages associated with the thicker layer of intact, anchored plant material over the soil surface that may permit greater weed-suppressive and erosion-protective benefits.

Nevertheless, the option of off-field organic waste and by-products as soil amendments (i.e. manure, slurry) has been associated with larger yield increases than these plant-based amendments due to substantially higher nutrient contributions (MacLaren et al., Reference MacLaren, Mead, van Balen, Claessens, Etana, de Haan, Haagsma, Jäck, Keller, Labuschagne, Myrbeck, Necpalova, Nziguheba, Six, Strauss, Swanepoel, Thierfelder, Topp, Tshuma, Verstegen, Walker, Watson, Wesselink and Storkey2022). Thus, the option of applying exogenous organic inputs in small-grain Mediterranean systems needs further evaluation.

Animal manures and chicken litter

Due to their similar nutrient concentrations and agronomic functionalities, the implications for ‘manure’ will be representative of other animal-based amendments; including ‘chicken litter’, ‘slurry’ and ‘bio-solids’ for simplicity purposes.

Animal manures and other animal-derived amendments such as chicken litter (a mixture of chicken faeces, feathers, bedding materials, feed and water) are primarily recognized for their enhancement of soil fertility through their supply of essential macro- and micronutrients (Urra et al., Reference Urra, Alkorta and Garbisu2019). MacLaren et al. (Reference MacLaren, Mead, van Balen, Claessens, Etana, de Haan, Haagsma, Jäck, Keller, Labuschagne, Myrbeck, Necpalova, Nziguheba, Six, Strauss, Swanepoel, Thierfelder, Topp, Tshuma, Verstegen, Walker, Watson, Wesselink and Storkey2022) observed that systems that received manure applications rather than plant-based amendments not only had greater yield increases, but could have most or all the nitrogen fertilizer removed without seeing yield reductions. This suggests that nitrogen supply is an important aspect of the contribution of organic amendments to yields. However, the application of animal manure can also indirectly support long-term soil fertility through increasing short-term microbial immobilization of nutrients, thereby reducing losses to leaching, nitrification and denitrification (Gómez-Sagasti et al., Reference Gómez-Sagasti, Hernández, Artetxe, Garbisu and Becerril2018). Applying manures may reduce N losses and improve fertilizer-use efficiency, particularly on sandy textured Mediterranean soils, which are heavily reliant on N fertilizer and prone to nitrate leaching during intensive winter rainfall (Lassaletta et al., Reference Lassaletta, Sanz-Cobena, Aguilera, Quemada, Billen, Bondeau, Cayuela, Cramer, Eekhout, Garnier, Grizzetti, Intrigliolo, Ramos, Romero, Vallejo and Gimeno2021). In turn, reduced synthetic fertilizer requirements without compromising yield or grain quality may improve the environmental and economic sustainability of these systems. Aside from their nutrient value, manure-based amendments may increase soil organic C and improve soil structure, thereby improving water infiltration and retention (Urra et al., Reference Urra, Alkorta and Garbisu2019). These improved hydro-structural properties may be of particular significance in Mediterranean systems that are often jeopardized by erosion and drought stress.

However, due to the high water content of manure and the especially large volumes required for cereal-based agro-ecosystems, handling of these unprocessed waste materials can be costly and pose various environmental risks, including volatilization of ammonia, greenhouse gas emissions and nitrate leaching (Lassaletta et al., Reference Lassaletta, Sanz-Cobena, Aguilera, Quemada, Billen, Bondeau, Cayuela, Cramer, Eekhout, Garnier, Grizzetti, Intrigliolo, Ramos, Romero, Vallejo and Gimeno2021). Animal manures are also often a hazardous source of contaminants; including pathogens, heavy metals, antibiotics and antibiotic-resistant bacteria. Depending on the animal-based waste and its origin, the level of contamination and potential adverse effects on human, animal and crop health can be significant. However, processing technologies such as anaerobic digestion, composting and biochar production have been shown to suppress these contaminants (Urra et al., Reference Urra, Alkorta and Garbisu2019). Furthermore, these technologies also represent cost-effective strategies for recovering nutrients from manure, while minimizing their environmental impacts and enhancing their economic value (Azim et al., Reference Azim, Soudi, Boukhari, Perissol, Roussos and Thami Alami2018). Nevertheless, to maximize the soil quality and crop benefits of animal-derived amendments and mitigate negative impacts on human and environmental health, there is still need to optimize application methods, establish contaminant thresholds of the various types of animal-based amendments and develop more effective treatment options for reducing contaminants in these organic resources.

Composts and biodigestates

Compost represents the most utilized form of recycled organic matter as a soil amendment. It is the stable end-product of aerobic decomposition of organic materials, typically agro- or municipal waste (crop residues, animal manures or sewage sludge). The composting conditions (i.e. temperature, oxygen and moisture) and the type of raw materials have the greatest effects on maturity, stability, nutrient availability and ultimately the quality of the compost (Sayara et al., Reference Sayara, Basheer-salimia, Education and Hawamdeh2020). Composts derived from nutrient-rich raw materials such as manure may supply significant amounts of essential macro- and micro-nutrients, directly improving soil fertility. Composts are also recognized for improving soil fertility through indirect means such as improved soil structure and associated nutrient retention, as well as improved nutrient cycling through enhanced microbial processing (Urra et al., Reference Urra, Alkorta and Garbisu2019). Although composting helps to reduce transportation costs and facilitates handling through reducing water content of organic wastes, its use in dryland small-grain systems is still limited by low cost-efficiency. Reeve et al. (Reference Reeve, Endelman, Miller and Hole2012), however, report on high rates of composted cattle manure having a long legacy effect on dryland winter wheat yield and soil quality. By inference, a similar strategy of applying high rates of compost at a lower frequency could contribute to the long-term economic feasibility of their use in Mediterranean small-grain CA systems due to lower transport and applications costs. However, the nutritive and non-nutritive carryover effects vary widely depending on compost composition, climate and soil type, and thus extensive context-specific research is needed to evaluate this approach for Mediterranean settings.

Conversely, digestates are produced through the anaerobic digestion of organic materials. They are also typically plant-derived and are relatively low in essential nutrients. Thus, their value is mainly tied to their provision of beneficial microbes that enhance plant growth and nutrient uptake through various mechanisms such as phosphorous and potassium solubilization, and nitrogen fixation (Sulok et al., Reference Sulok, Ahmed, Khew, Zehnder, Jalloh, Musah and Abdu2021). Nevertheless, anaerobic digestion of manure or sewage sludge presents emerging options for increasing and manipulating relative nutrient concentrations of these products, facilitating their handling, and reducing the load of potential human pathogens and pollutants. However, the economic feasibility of this approach for on-farm production is unlikely due to expensive equipment and production costs.

Biochar

Biochar is a highly stable carbon-rich product obtained from the thermal decomposition (pyrolysis) of organic material (feedstock) under low oxygen conditions. The pyrolysis conditions and the feedstock type can be optimized to generate ‘tailored’ biochar that has selective properties which address soil physiochemical constraints common to arable soils in Mediterranean regions. For instance, biochar derived from carbon-rich raw materials such as wheat straw, under relatively fast and high temperature (>400°C) pyrolysis, raises soil pH and soil organic C, and has surface characteristics that improve nutrient retention and create a favourable habitat for microorganisms (Gao et al., Reference Gao, Yang, Liu, Gu, Han, Li, Li, Liu, An, Dai, Liu and Han2021). The agronomic value of such a biochar in Mediterranean CA systems may be in addressing the pertinent issue of soil acidification, serving as a long-acting liming agent (Zhang et al., Reference Zhang, Yan, Niu, Liu, van Zwieten, Chen, Bian, Cheng, Li, Joseph, Zheng, Zhang, Zheng, Crowley, Filley and Pan2016), while also reducing leaching losses, and improving soil nutrient dynamics. Conversely, slow pyrolysis at low temperature (<400°C) of a nutrient-rich feedstock such as manure favours the production of biochar with more labile carbon and nutrients, and thus greater potential to directly improve soil fertility (Lehmann et al., Reference Lehmann, Gaunt and Rondon2006).

However, despite the many reported positive impacts that biochar can have when applied to soils (Basak et al., Reference Basak, Sarkar, Saha, Sarkar, Mandal, Biswas, Wang and Bolan2022), there is a need for long-term research evaluating the effects of different biochars on soil quality and crop productivity under Mediterranean dryland farming constraints. This should be coupled with research in identifying easily accessible and suitable waste materials in these production regions for the efficient upscaling of this technology. Furthermore, biochar's expensive nature brings its economic feasibility into question, particularly in cereal-based agroecosystems. Thus, a long-term economic assessment of its impacts in these systems is called for. There is also a need for developing biochar application strategies (e.g. top-dressing v. incorporation, optimum application rate and co-application with fertilizer or other organic amendments) that will optimize the efficiency of its use (Basak et al., Reference Basak, Sarkar, Saha, Sarkar, Mandal, Biswas, Wang and Bolan2022).

Microbial bioeffectors

Microbial bioeffectors can be further categorized into beneficial fungi, such as arbuscular mycorrhizal fungi or Trichoderma spp., and beneficial bacteria – primarily rhizospheric or endophytic. The representative genera of plant growth-promoting bacteria (PGPB) include nitrogen-fixing Rhizobium, Azotobacter spp., Azospirillum spp., Pseudomonas spp. and Bacillus spp. Through numerous and often synergistic mechanisms, PGPB applied directly into soil with a carrier material or via inoculated seed could successfully colonize plant roots and positively enhance plant growth and fitness. Plant growth promotion and resilience can be obtained by their release of growth-stimulating compounds and the improvement of nutrient uptake (e.g. iron and phosphorous solubilization and nitrogen fixation). Furthermore, some PGPB may indirectly promote plant growth through control of pathogens, and the synthesis of antibiotics and secondary metabolites that induce systemic resistance (Vimal et al., Reference Vimal, Singh, Arora and Singh2017).

Of the fungal-based bioeffectors, mycorrhizal fungi inoculations forming extensive hyphal root networks that facilitate water and nutrient availability to plants represent an attractive symbiosis in dryland Mediterranean soils that are often compromised by drought stress and consequently low nutrient availability (Lassaletta et al., Reference Lassaletta, Sanz-Cobena, Aguilera, Quemada, Billen, Bondeau, Cayuela, Cramer, Eekhout, Garnier, Grizzetti, Intrigliolo, Ramos, Romero, Vallejo and Gimeno2021). Mycorrhizal fungi may also improve soil water- and nutrition efficiency through their formation of stable aggregates and solubilization of phosphate and micronutrients (du Jardin, Reference du Jardin2015). Distinct from the mycorrhizal species, Trichoderma spp. belong to a class of plant growth-promoting fungi that have been used successfully for biological control of plant pathogens and nematodes. There is also evidence that Trichoderma-based products may increase wheat growth under nutrient-poor and moderate drought conditions through altering the plant hormone balance (López-Bucio et al., Reference López-Bucio, Pelagio-Flores and Herrera-Estrella2015).

However, despite numerous reports of microbial bioeffectors enhancing crop performance and allowing nutrient savings, these are mainly in potting experiments under controlled greenhouse conditions, and there are limited studies demonstrating measurable benefits in field conditions (Herrmann et al., Reference Herrmann, Wang, Hartung, Hartmann, Zhang, Nkebiwe, Chen, Müller and Yang2022). The inability to exclude environmental stress factors and native microbial populations that may impede establishment of plant–microbial interactions leads to unreliable outcomes, limiting their practical use – and adoption in field conditions (Tabacchioni et al., Reference Tabacchioni, Passato, Ambrosino, Huang, Caldara, Cantale, Hett, Del Fiore, Fiore, Schlüter, Sczyrba, Maestri, Marmiroli, Neuhoff, Nesme, Sørensen, Aprea, Nobili, Presenti, Giovannetti, Giovannetti, Pihlanto, Brunori and Bevivino2021). Furthermore, the higher application costs for effective inoculation due to larger soil volumes in small-grain cropping systems, coupled with lower market prices of the final products as compared with horticultural production, further limits their viability in these systems. Nevertheless, the options of localized application of microbial bioeffectors for product-saving (e.g. in-furrow placement) and combined application with selected fertilizers, organic amendments or bioactive compounds as carrier materials offer perspectives for more efficient and cost-effective inoculation under field conditions (Vinci et al., Reference Vinci, Cozzolino, Mazzei, Monda, Spaccini and Piccolo2018). This may be explained by the positive influence of these inputs on viability and survival of novel microorganisms in the soil, along with synergistic interactions that further improve stress resistance and nutrient acquisition of crops. Nevertheless, these strategies still require further research and site-specific adaptations for their potential in small-grain Mediterranean agroecosystems to be realized.

Non-microbial bioeffectors

Non-microbial bioeffectors comprise a variety of bioactive natural compounds from plants or animals, including humic substances, amino acids and extracts from seaweeds and other plants. Relative to microorganisms, these bioactive compounds are less influenced by edaphic and environmental factors after application, and thus may offer options for more efficient and cost-effective applications in small-grain agroecosystems (Tabacchioni et al., Reference Tabacchioni, Passato, Ambrosino, Huang, Caldara, Cantale, Hett, Del Fiore, Fiore, Schlüter, Sczyrba, Maestri, Marmiroli, Neuhoff, Nesme, Sørensen, Aprea, Nobili, Presenti, Giovannetti, Giovannetti, Pihlanto, Brunori and Bevivino2021). Also, despite microbial and non-microbial bioeffectors showing common modes of action towards improving growth, nutrient acquisition and stress tolerance of crops, non-microbial bioeffectors have been most widely recognized for their protection against abiotic stress under field conditions. Exploiting these stress-protective functions may be of value for reducing production risks and yield fluctuations in Mediterranean-based small-grain systems. The potential of common non-microbial bioeffectors and their respective modes of actions, particularly relating to stress mitigation, are thus reviewed.

Combination strategies

In recent years, considerable research has gone into the development and adaptation of existing microbial and non-microbial bioeffectors for enhanced field efficiency. Through identifying product-specific modes of actions and designing combinations of microorganisms and non-microbes for targeted and complementary functions, these new products have achieved substantially larger yield increases to any single variants (Herrmann et al., Reference Herrmann, Wang, Hartung, Hartmann, Zhang, Nkebiwe, Chen, Müller and Yang2022). Nevertheless, there is still potential for developing synergistic combination options through better understanding the functional mechanisms underlying different bioeffectors.

Additionally, the simultaneous application of bioeffectors with special nitrogen fertilizers (e.g. stabilized ammonium) has improved their field efficiency through triggering mechanisms for nutrient acquisition (Zimmermann et al., Reference Zimmermann, Claß-Mahler, von Cossel, Lewandowski, Weik, Spiller, Nitzko, Lippert, Krimly, Pergner, Zörb, Wimmer, Dier, Schurr, Pagel, Riemenschneider, Kehlenbeck, Feike, Klocke, Lieb, Kühne, Krengel-Horney, Gitzel, El-Hasan, Thomas, Rieker, Schmid, Streck, Ingwersen, Ludewig, Neumann, Maywald, Müller, Bradáčová, Göbel, Kandeler, Marhan, Schuster, Griepentrog, Reiser, Stana, Graeff-Hönninger, Munz, Otto, Gerhards, Saile, Hermann, Schwarz, Frank, Kruse, Piepho, Rosenkranz, Wallner, Zikeli, Petschenka, Schönleber, Vögele and Bahrs2021). Foliar applications of selected seaweed, plant extracts and humic acids combined with stabilized ammonium were also able to reduce drought stress (Zimmermann et al., Reference Zimmermann, Claß-Mahler, von Cossel, Lewandowski, Weik, Spiller, Nitzko, Lippert, Krimly, Pergner, Zörb, Wimmer, Dier, Schurr, Pagel, Riemenschneider, Kehlenbeck, Feike, Klocke, Lieb, Kühne, Krengel-Horney, Gitzel, El-Hasan, Thomas, Rieker, Schmid, Streck, Ingwersen, Ludewig, Neumann, Maywald, Müller, Bradáčová, Göbel, Kandeler, Marhan, Schuster, Griepentrog, Reiser, Stana, Graeff-Hönninger, Munz, Otto, Gerhards, Saile, Hermann, Schwarz, Frank, Kruse, Piepho, Rosenkranz, Wallner, Zikeli, Petschenka, Schönleber, Vögele and Bahrs2021). Similarly, micronutrient fertilizers such as silicon, zinc and manganese, with functions in stress defence, synergistically improved the stress-protective performance of various microbial and non-microbial bioeffectors in cereal crops (du Jardin, Reference du Jardin2015). These results highlight the importance of further research toward enhancing host plant adaptations for optimizing the efficacy and/or efficiency of bioeffector applications. Long-term context-specific field trials monitoring yield development will also help to better quantify the potential benefits to yield assurance and ultimately whole-farm economics in the Mediterranean small-grain setting.

Cover crops v. monoculture pastures

The integration of monoculture pasture phases into Mediterranean-climate crop rotations and the associated income diversification through supporting a livestock enterprise has helped in dampening fluctuations in income as a result of both grain price and climate variability (Bell et al., Reference Bell, Moore and Kirkegaard2013). Monoculture pastures are typically legume based, consisting of either annual medics (Medicago spp.), clovers (Trifolium spp.) or lupines (Lupinus spp.), which are grown in single season rotations with cash crops, or of lucerne (Medicago sativa), which is grown in long phases of up to 7 years and then followed by 5–7 years of cash crops. Whereas grass-based pasture phases often include oats (Avena sativa) or barley (Hordeum vulgare) that is grown during the winter growing season. These pasture phases have also further optimized the beneficial characteristics of CA, particularly via their capacity to improve weed control and break pest and disease cycles, sequester soil carbon, increase biodiversity and improve nutrient cycling (Planisich et al., Reference Planisich, Utsumi, Larripa and Galli2021). However, the increased diversity that cover crops offer may provide superior soil quality, crop productivity and ultimately economic benefits compared to monoculture pastures.

Perhaps the most significant advantage of multi-species cover crops compared to monoculture pastures is that they do not only offer temporal diversity (through a crop rotation sequence), but also offer spatial diversity. Thus, through utilizing a combination of cover crop species that excel at different services, this may sustain a greater number of agroecological functions simultaneously. Importantly, however, it is the selection for functional diversity of the cover crop that is of more importance for ecosystem functioning than diversity (species richness) per se (Finney and Kaye, Reference Finney and Kaye2017). For instance, given the poor organic matter content of soils in Mediterranean-type environments, cover crops are often selected for functionally diverse traits that mediate nitrogen-related services such as sequestering, scavenging and supplying of nitrogen to the main crop. This could be achieved through combining legumes and cereal species for their respective nitrogen fixing and retention functions, whilst also providing significant carbon input and conservation benefits (Blanco-Canqui and Jasa, Reference Blanco-Canqui and Jasa2019). Nevertheless, selecting for cover crop multi-functionality may also cause trade-offs for service provision. For example, selecting for a highly weed-suppressive mix depends on individual species competitiveness rather than functional diversity. By implication, such a mix will typically have a relative abundance of competitive non-legumes, resulting in lower inorganic nitrogen availability and potentially reduced cash crop yields (MacLaren et al., Reference MacLaren, Swanepoel, Bennett, Wright and Dehnen-Schmutz2019b).

Furthermore, this diversity in space may increase resilience of the ecosystem services cover crops provide, as different plant types contribute to particular services in different ways and under different conditions. This enables a higher overall capacity for a cover crop to consistently perform a given function, whether it is providing more consistent, high-quality forage material and reducing the risk of feed gaps (Bell et al., Reference Bell, Moore and Thomas2018), improving resistance against various biotic or abiotic stresses (Isbell et al., Reference Isbell, Adler, Eisenhauer, Fornara, Kimmel, Kremen, Letourneau, Liebman, Polley, Quijas and Scherer-Lorenzen2017) or extending time with crop cover for erosion prevention and enhanced soil functioning (Garland et al., Reference Garland, Edlinger, Banerjee, Degrune, García-Palacios, Pescador, Herzog, Romdhane, Saghai, Spor, Wagg, Hallin, Maestre, Philippot, Rillig and van der Heijden2021). Nevertheless, a potential drawback of this spatial diversity is an increased susceptibility to harbouring insect pests and diseases and forming a ‘green bridge’ between cover crop and cash crop phases, exacerbating pest populations in crops. Although this is generally not considered a concern in Mediterranean regions due to a relatively dry summer, it warrants further investigation.

To illustrate the importance of permanent living plant material, in these regions where low or erratic rainfall limits plant productivity in the summer months and presents fodder flow and erosion issues, strategically designed cover crops may serve a particularly important role in increasing the proportion of time with living roots in the soil. Through over-sowing a winter cover crop or perennial lucerne pasture with a combination of hardy grass species such as annual teff (Eragrostis tef) or forage sorghum (Sorghum spp.) in spring, this may provide short-lived crop cover extending into the summer months and superior herbage production to perennial lucerne. This, in turn, may lead to improved fodder flow, reduced erosion and leaching, and the development of carbon-rich roots that enhance soil fertility, soil structure and microbial health, ultimately improving crop production (Garland et al., Reference Garland, Edlinger, Banerjee, Degrune, García-Palacios, Pescador, Herzog, Romdhane, Saghai, Spor, Wagg, Hallin, Maestre, Philippot, Rillig and van der Heijden2021).

Chen and Weil (Reference Chen and Weil2010) report that cover crops with deep taproots such as radish can directly alleviate soil compaction through their roots serving as bio-drills that penetrate compacted layers. Although this phenomenon is still disputed in the literature, it is well established that cover crops do reduce the susceptibility of the soil to compaction through improving soil aggregation and decreasing bulk density (Blanco-Canqui et al., Reference Blanco-Canqui, Claassen and Presley2012). Additionally, the inclusion of plants with deep tap roots can create root channels/macro-pores as they decompose, thereby improving water infiltration and the subsequent cash crops’ root growth.

Adaptive multi-paddock grazing v. continuous grazing

The integration of continuously grazed cover crop phases in CA crop rotations of a Mediterranean climate has shown to maintain yields at reduced fertilizer rates (MacLaren et al., Reference MacLaren, Storkey, Strauss, Swanepoel and Dehnen-Schmutz2019a). Set stocking in these systems has also shown to facilitate reductions in chemical plant protectants required for satisfactory weed, pest and disease management, providing not only ecological benefits but also improved economic performance (MacLaren et al., Reference MacLaren, Storkey, Strauss, Swanepoel and Dehnen-Schmutz2019a; Strauss, Reference Strauss, Dent and Boincean2021). However, the alternative use of AMP grazing management is under scrutiny for potentially superior ecosystem service delivery, crop productivity and profitability benefits.

Although numerous publications have dealt with the integration of crops and livestock, there is almost no information comparing continuous to AMP grazing in integrated crop–livestock systems, let alone in Mediterranean climatic contexts. Thus, despite substantial anecdotal evidence from producers in support of AMP grazing on multi-species covers v. continuous grazing, there is still a lack of consensus in the scientific literature on the purported advantages. Nevertheless, based on studies from different farming systems and agroclimatic regions, benefits may still be inferred for crop–livestock systems with a Mediterranean climate.

AMP grazing is an observant approach, such that animal numbers, grazing intensity and recovery periods are adaptively adjusted to match available forage and ensure sufficient post-grazing plant residual for optimal regrowth. Several studies suggest AMP livestock management not only sustains greater forage production and quality than continuous grazing, but also synergistically enhances cover crop service delivery (Kleppel, Reference Kleppel2020). This sustaining of the functional value of cover crops may be largely attributed to the adaptive nature of AMP grazing. Other advantages of AMP grazing are linked to the short and intense nature of this high stock-density approach, which ensures even and non-selective utilization of plant material (Teague and Kreuter, Reference Teague and Kreuter2020). This may exert a greater selection pressure on weeds compared with low-density grazing and prevent less palatable plant types from dominating as a result of selective grazing. Importantly, however, for effective and sustainable weed control, this strategy should be integrated with contrasting selection pressures such as strategic low-use of herbicides and/or mechanical control (MacLaren et al., Reference MacLaren, Storkey, Strauss, Swanepoel and Dehnen-Schmutz2019a). The high utilization of vegetation associated with the high stocking density also implies greater root turnover, thereby stimulating more carbon sequestration and improving soil structure (Kleppel, Reference Kleppel2020). Furthermore, the high stocking density leads to the formation of a uniform layer of manure and plant litter that is trampled into the soil, enriching it with organic matter and enhancing nutrient cycling and soil fertility (Peel and Stalmans, Reference Peel and Stalmans2018).

There are also potential drawbacks of AMP grazing. Particularly when stocking densities are beyond the optimum and/or grazing duration is too long, this approach may increase the risk of overgrazing and soil compaction (Wang et al., Reference Wang, Richard Teague, Park and Bevers2018). Another limitation of AMP grazing is that its intensive and complex nature implies higher levels of organizational skills, knowledge and commitment are required for it to be effectively executed (Sanderson et al., Reference Sanderson, Archer, Hendrickson, Kronberg, Liebig, Nichols, Schmer, Tanaka and Aguilar2013). For instance, the selection of plant species to form a complementary mixture (spatially and temporally) in a specific context and the grazing management thereof is particularly complex. This is because optimal grazing times for maintaining forage quality and productivity vary for grasses and forage herbs due to their different growth patterns, and therefore trade-offs are inevitable with a mixture (Sanderson et al., Reference Sanderson, Archer, Hendrickson, Kronberg, Liebig, Nichols, Schmer, Tanaka and Aguilar2013).

Furthermore, a potential limitation of AMP grazing is that it may not ensure sufficient biomass is consistently maintained for cover crops to maintain their functional value to deliver specific ecosystem services to the cropping system (Sanderson et al., Reference Sanderson, Archer, Hendrickson, Kronberg, Liebig, Nichols, Schmer, Tanaka and Aguilar2013). Kelly et al. (Reference Kelly, Schipanski, Tucker, Trujillo, Holman, Obour, Johnson, Brummer, Haag and Fonte2021) suggest judicious cover crop utilization with low-intensity rotational grazing may be the best strategy to maintain cover crops’ dual-purpose of forage and service provision. However, in the South African Mediterranean climate region, Smit et al. (Reference Smit, Strauss and Swanepoel2021) found that high-density grazing (fundamentally similar to AMP) of cover crops did not affect subsequent wheat grain yield, while it did improve soil quality, and in particular nitrogen content when compared to a no grazing control. These findings suggest there is still a need for further research into the role of grazing intensity on cover crop ecosystem provision.

Research is still needed to identify and better quantify the specific services that different cover crop traits provide, as well as determine the species abundances required to achieve them. Knowledge gaps also exist around the interdependence and trade-offs among these services. Addressing these gaps will help farmers to strategically design multifunctional cover crops based on their specific objectives/constraints. Similarly, for producers to consider adopting AMP grazing of their cover crops, it needs to be validated in context-specific grazing studies that investigate its relative contribution to ecosystem service delivery, compared with conventional set-stocking approaches.