Tillage has been ubiquitous to crop production in most of the world for millennia. Implements used to till the soil that were pulled by animals are known to have existed at least as far back as 8000 bc.Reference Lal, Reicosky and Hanson¹ However, growing concerns about the negative consequences of tillage on soil qualityReference Karlen, Wollenhaupt, Erbach, Berry, Swan, Eash and Jordahl^2–Reference Ismail, Blevins and Frye⁴ spurred widespread interest in reducing tillage practices on farms, particularly in the Great Plains of North America where farming practices brought by immigrants from eastern regions and from Europe were not adapted because of the dry conditions that were encountered. This realization and other developments culminating in the Dust Bowl era during the 1930s made it obvious that innovative farming practices were needed to protect soil from erosion and degradation in quality. A logical consequence is modern no-till farming, where soil is disturbed minimally, if at all, when growing annual cash and forage crops. Advantages of no-till compared with clean or conventional tillage farming have been widely described in the scientific literature, with an excellent recent summary by Triplett and DickReference Triplett and Dick⁵.

Growth in modern no-till farming coincided with the development and commercial use of synthetic herbicides, notably first with 2,4-dichlorophenoxyacetic acid (2,4-D) in the USAReference Lyon, Miller and Wicks⁶, and paraquat in EuropeReference Lal, Reicosky and Hanson¹. Herbicides provided farmers with an effective alternative to tillage for controlling weeds but, unlike tillage, did not bury crop residue. The resultant vegetative mulch protected soil from water and wind erosion and, in semi-arid regions, reduced evaporation and improved soil-water storage efficiencyReference Peterson, Schlegel, Tanaka and Jones⁷. The development of improved herbicides, along with seeding and harvesting equipment designed for use in no-till systems, resulted in the steady growth of this farming method, beginning in the 1990sReference Triplett and Dick⁵.

Few herbicide options are available to organic farmers, in contrast to conventional farmers, forcing a continued reliance on tillage for weed control in systems managed organically. Research on alternative tillage methods for organic farmers is limited and has lagged behind comparable efforts directed at conventional farmers. Moreover, the so-called bio-herbicides such as natural vinegar, corn gluten and pine extracts that are permitted for use in certified organic farming in some regions of the globe are not, to date, allowed in Europe (European Council (EC) Regulation No. 834/2007 on organic production). Consequences of this dependence on tillage are the negative impacts on soil quality described elsewhereReference Karlen, Wollenhaupt, Erbach, Berry, Swan, Eash and Jordahl^2–Reference Ismail, Blevins and Frye⁴.

Arguments have been made about the inferiority of organic farming compared with conventional no-till farming in maintaining or enhancing soil qualityReference Trewevas⁸, as well as providing other ecosystem servicesReference Robertson, Eldor and Harwood⁹. Curiously, comparisons of conventional no-till farming and tilled organic farming systems failed to reveal distinct soil quality advantages resulting from no-till farming methods. Rather, soil carbon and nitrogen levels were elevated under organic management in one study, presumably in part because of animal manure additions to the organic plotsReference Teasdale, Coffman and Mangum¹⁰. Potentially mineralizable nitrogen was over 20% higher in a tilled system transitioning to certified organic production, compared with conventional systems in the first few years of transitioning to long-term no-till management, in a separate study, probably because of the use of a pea green manure crop in the organic systemReference Miller, Buschena, Jones and Holmes¹¹.

There is interest in reducing tillage in organic farming systems for many of the same reasons that tillage has been reduced or eliminated in conventional farming. Peigné et al.Reference Peigné, Ball, Roger-Estrade and David¹² point out that conservation tillage practices, where at least 30% of the soil surface is covered by a dead vegetative mulch after seeding, could reduce fuel use, enhance soil microbial activity and increase water infiltration rates, as well as reduce soil erosion and leaching of plant nutrients if adopted by organic farmers. The researchers acknowledge the weed control challenges when considering a transition from clean tillage to conservation tillage systems, noting that changes in weed dynamics often deter adoption of conservation tillage by organic farmers in Europe. Likewise, concern over an inability to control weeds when tillage is reduced is a major impediment to adoption of conservation tillage practices among organic farmers in the USA (Duane Boehm, pers. comm.).

Different strategies have been considered for adapting conservation tillage practices to organic farming systems. In North America, most of the present research is directed at reliance on vegetative mulch created by killed cover crops to suppress weeds during a subsequent cash crop phase within a longer crop rotationReference Vaisman, Entz, Flaten and Gulden¹³. This idea is not new and apparently originates from the use of drums with attached blunt blades to kill cover crops in conventional no-till farming systems in BrazilReference Kornecki, Price and Raper^14, Reference Kornecki, Price, Raper and Arrianga¹⁵. The effectiveness of using a blade rollerReference Vaisman, Entz, Flaten and Gulden¹³, also referred to as a roller–crimperReference Mirsky, Curran, Mortensen, Ryan and Shumway¹⁶, in killing winter rye (Secale cereale L.), winter wheat (Triticum aestivum L.) and black oat (Avena strigosa Schreb.) in the southern USA was reported by Ashford and Reeves almost a decade agoReference Ashford and Reeves¹⁷. The two researchers concluded that the three cover crops could be killed effectively if blade rolling was delayed until at least the early milk growth stage (BBCH growth stage 73)Reference Lancashire, Bleiholder, Van Den Boom, Langeluddeke, Stauss, Weber and Witzenberger¹⁸ of kernel development. Subsequent research confirmed this observation for winter rye in the mid-Atlantic region of the USAReference Mirsky, Curran, Mortensen, Ryan and Shumway¹⁶.

Creamer et al.Reference Creamer, Plassman, Bennett, Wood, Stinner and Cardina¹⁹ compared termination of several cover crop species using a sickle bar mower, flail mower and roller attached to a blade plow in the US Midwest region during the early 1990s. The researchers concluded that while there could be problems with clogging when terminating vine-like cover crops [e.g., hairy vetch (Vicia villosa Roth)], sickle bar mowing was as effective as the roller/blade plow in killing cover crops, and left a thick vegetative mulch that suppressed weeds. Creamer and DabneyReference Creamer and Dabney²⁰ indicated that problems could be encountered when attempting to kill cover crops by rolling, as well as with other mechanical methods that exclude tillage, including several identified by othersReference Morse²¹.

Improvements in blade roller design have occurred since early research was conducted. Newer designs have proven effective in terminating cover crops, and have enhanced the comfort of those operating blade rollers in the fieldReference Kornecki, Price and Raper^14, Reference Kornecki, Price, Raper and Arrianga¹⁵. Reports on the ability of cover crop residue to provide near season-long weed control when killed by modern blade rollers exist, and considerable enthusiasm has been generated for ‘no-till’ organic farming where tillage is eliminated entirely during certain crop phases of a crop rotation²². Six papers included in this special issue describe efforts to develop organic conservation tillage practices in North America, and the use of cover crops and blade rollers is a prominent, if not exclusive, focus of the research that is described.

Mirsky et al.Reference Mirsky, Ryan, Curran, Teasdale, Maul, Spargo, Moyer, Grantham, Weber and Way²³ discuss efforts to develop organic conservation tillage systems in the mid-Atlantic region, where much of the recent published research on blade rollers and cover crops in the context of organic no-till has been conducted in North AmericaReference Mirsky, Curran, Mortensen, Ryan and Shumway^16, Reference Mischler, Dulker, Curran and Wilson²⁴. The authors note that an inability to suppress weeds consistently is a major obstacle that must be overcome for rolled and killed cover crop residue to be considered a viable weed control tool in organic farming systems. Reberg-Horton et al.Reference Reberg-Horton, Grossman, Kornecki, Meijer, Price, Place and Webster²⁵ indicate that growing conditions in the southeast region of the USA allows for prolific growth by cover crops, sometimes exceeding 9000 kg ha⁻¹ of dry matter, which results in a thick vegetative mulch capable of suppressing weeds in many cash crops. The southern researchers acknowledge that additional weed control measures sometimes are needed if cover crop mulch alone is relied on for season-long weed control.

Delate and CwachReference Delate and Cwach²⁶ in the US Midwest region and Luna et al.Reference Luna, Mitchell and Shrestha²⁷ in the US Pacific Northwest region consider the efficacy of rolled and killed cover crop mulch for weed control in tomato (Lycopersicon esculentum Mill.) and several other crops. Delate and CwachReference Delate and Cwach²⁶ report that excellent early-season weed control can be provided by cover crop mulch, but acknowledge that suppression of weeds may be diminished by mid-season. Luna et al.Reference Luna, Mitchell and Shrestha²⁷ recognize the potential that organic no-till has in eastern portions of North America, but consider lack of weed control as only one of several problems which prevents this cropping strategy from being adopted in the Pacific Northwest region presently. Carr et al.Reference Carr, Anderson, Lawley, Miller and Zwinger²⁸ report that annual weed growth can be suppressed by rolled and killed cover crops in the semi-arid northern Great Plains region of the USA, but suggest that cover crop mulch will be ineffective in controlling established perennial weed species such as Canada thistle (Cirsium arvense [L.] Scop.). Shirtliffe and JohnsonReference Shirtliffe and Johnson²⁹ indicate that weed growth can be greater when cover crops are killed by disking compared with mowing and blade rolling, but acknowledge that refinement is needed before organic no-till is a viable production system on commercial organic farms in western Canada.

A recurring theme from recently completed and ongoing research on organic no-till farming in North America is that efficacy must be improved when relying on killed cover crop mulch for weed control in subsequent cropsReference Mirsky, Ryan, Curran, Teasdale, Maul, Spargo, Moyer, Grantham, Weber and Way^23–Reference Carr, Anderson, Lawley, Miller and Zwinger²⁸. Interest in organic farming systems which rely on rolled and killed cover crop residue for weed control also has been expressed by European scientistsReference Peigné, Ball, Roger-Estrade and David¹². This is documented, for instance, by a paper presented at the 16th IFOAM Congress in Italy on the direct seeding of fababean (Vicia faba L.)Reference Köpke and Schulte³⁰. Although a recent review of the literature failed to identify published results from European field studies on use of killed cover crop mulch for weed suppressionReference Peigné, Ball, Roger-Estrade and David¹², seeding fababean directly into small-grain stubble without pre-plant tillage has been considered by German scientists at the University of BonnReference Massucati, Geib and Köpke³¹.

Efforts to reduce tillage in organic farming systems by European scientists generally are not focused on its complete elimination, as is the case in North America. Instead, European researchers are working mainly on methods that decrease the amount of inversion tillage being used by organic farmers, particularly when a pasture ley is included in rotations with annual cash crops. This emphasis on reducing, rather than eliminating, tillage completely is exemplified in a series of papers summarizing results from the first 6 years of a long-term field study at the Research Institute of Organic Agriculture located at Frick, SwitzerlandReference Berner, Hildermann, Flieβbach, Pfiffner, Niggli and Mäder^32–Reference Gadermaier, Berner, Flieβbach, Friedel and Mäder³⁵. The experiment, established in 2002, compared two tillage systems across a winter wheat (2002–2003)–sunflower (Helianthus annuus L.; 2004)–spelt (T. spelta L.; 2005)–grass/clover polyculture (2006–2007)–maize (Zea mays L.; 2008) crop sequence between 2002 and 2008: a clean or conventional tillage system where primary tillage was done using a moldboard plow and a reduced tillage system where primary tillage was accomplished using a chisel plow. A stubble cleaner or skim plow was used for removal of the grass–clover ley before maize in both tillage systems, with secondary tillage accomplished using a rotary harrow.

Reduced nitrogen mineralization in spring and elevated weed competition under reduced tillage probably explains the mixed crop yield results between 2002 and 2005, when small-grain crop yields were depressed, while oilseed crop yield was elevated slightlyReference Berner, Hildermann, Flieβbach, Pfiffner, Niggli and Mäder^32, Reference Sans, Berner, Armengot and Mäder³³. Forage yield of the grass-clover ley was 25% higher in reduced tillage plots during 2006–2007 because of improved water retentionReference Krauss, Berner, Burger, Wiemken, Niggli and Mäder³⁴, and maize silage yields were 34% higher under reduced tillage in 2008, despite weed populations that were two to five times higher than in conventional tillage plotsReference Krauss, Berner, Burger, Wiemken, Niggli and Mäder³⁴. Greater enhancements in soil quality were detected under reduced tillage compared with conventional tillage during the first 6 years of this study and are summarized by Gadermaier et al.Reference Gadermaier, Berner, Flieβbach, Friedel and Mäder³⁵ in this special issue.

Colonization of maize roots by arbuscular mycorrhizae across tillage systems was considered by the Swiss researchers in 2005. Interestingly, no enhancement in maize root colonization was detected in reduced tillage compared with conventional tillage plotsReference Berner, Hildermann, Flieβbach, Pfiffner, Niggli and Mäder³². Rather, arbuscular mycorrhizal infection of maize roots was slightly higher under conventional tillage. These results contrast with those of othersReference Kabir, O'Halloran, Fyles and Hamel³⁶ who found root colonization by arbuscular mycorrhizae to be higher under reduced tillage compared with conventional tillage. KabirReference Kabir³⁷ concluded in his review of the literature that tillage generally is harmful to arbuscular mycorrhizae and the hyphae networks that are formed. However, the impact of tillage on arbuscular mycorrhizae can be confounded by such things as timing of field activitiesReference Kabir, O'Halloran, Fyles and Hamel^36, Reference Kabir³⁷ and the fungal species that are presentReference Jansa, Mozafar, Anken, Ruh, Sanders and Frossard³⁸. This was illustrated even at the intra-specific level of the mycorrhizal fungus Glomus intraradices, where the diversity of mitochondrial large subunit rDNA haplotypes was found to be higher under reduced tillage compared to conventional tillage in the Frick studyReference Börstler, Thiéry, Sykorová, Berner and Redecker³⁹.

The negative effect that tillage can have on arbuscular mycorrhizal populations and other edaphic factors led some researchers to suggest that adoption of reduced tillage practices fails to capture the soil quality improvements and other benefits that only result when tillage is eliminated completely from farming systems. Grandy et al.Reference Grandy, Robertson and Thelen⁴⁰ argued that no-till practices must be continuous throughout a crop rotation; many soil quality improvements can be undone in long-term no-till fields by a single tillage operation. Kettler et al.Reference Kettler, Lyon, Doran, Powers and Stroup⁴¹ reported that soil quality declined at shallow soil depths (0–7.5 cm) following the single use of a moldboard plow in long-term no-till plots, while soil quality improved at a 7.5–15 cm soil depth, concluding that occasional tillage may result in stratification rather than an overall decline in soil quality. Continuous no-till farming, like that described by Grandy et al.Reference Grandy, Robertson and Thelen⁴⁰, has not been accomplished successfully when farming organically on a commercial scaleReference Schonbeck⁴². Still, several soil quality and other potential advantages have been attributed to organic no-till farming as it presently is describedReference Moyer⁴³, and explains the motivation for many of the studies on organic no-till in North AmericaReference Mirsky, Ryan, Curran, Teasdale, Maul, Spargo, Moyer, Grantham, Weber and Way^23, Reference Reberg-Horton, Grossman, Kornecki, Meijer, Price, Place and Webster^25–Reference Shirtliffe and Johnson²⁹. European researchers are no less motivated than their North American colleagues in developing viable conservation tillage practices for adoption by organic farmers, but their approach is different and focused on reducing, but not eliminating, tillage when farming organically.

The papers included in this special issue are intended to provide readers with an overview of recently completed and ongoing efforts by North American scientists to develop viable organic no-till systems, and by their European counterparts to develop farming systems that require less tillage when growing organic cash crops. Benefits from adopting reduced tillage and no-till methods for farming organically are identified, as are obstacles that must be overcome before these practices are adopted by large numbers of organic farmers. Multi-disciplinary teams of scientists and organic farmers are needed to solve the problems that are encountered when tillage is reduced or eliminated, and organic cash crops are grown. Our hope is that collaborations among those interested in this topic will be spurred as a result of this special issue, including trans-Atlantic efforts between European and North American researchers.