Site description

The replicated experiment was conducted during the 2021 (year 1), 2022 (year 2) and 2023 (year 3) growing seasons on winter wheat (T. aestivum L. em Thell.) crops grown after winter winter oilseed rape (Brassica napus L. var. napus) at the Teagasc Crops Research Centre Knockbeg site (52°86_87 N, −6°94_14 W, 55m a.s.l), County Carlow, Ireland. The soil type is a Haplic Luvisol (humic epidystric) and is a medium textured clay loam of the Mortarstown series (Brennan et al., Reference Brennan, Hackett, McCabe, Grant, Fortune and Forristal2014; Conry, Reference Conry1987) (Table 1). Mean long-term (1980–2010) annual rainfall and temperature are 840.2 mm and 9.8 °C, respectively (Coonan et al., Reference Coonan, Curley and Ryan2024a; Coonan et al., Reference Coonan, Curley and Ryan2024b). The experiment was located on an existing trial site with a long history of establishment system studies. The site was annually cropped since 1992, and a replicated trial with establishment system treatments was established in 2001 to compare plough and min-till establishment. In 2014, the treatments were altered to include plough, min-till and strip till (with strip till and min-till on previously min-till plots) with sub-plots of rotational crops. Direct drilling was substituted for strip till at the start of the reported experiment (2021).

Table 1. Soil characteristics of the replicated trial experimental site (Knockbeg site) ^a

Notes: ^aSoil texture class – Clay Loam (UK/ADAS Classification). World reference base classification: Haplic Luvisol (humic epidystric); OM, organic matter.

^b Adapted from Brennan et al. (Reference Brennan, Hackett, McCabe, Grant, Fortune and Forristal2014).

Treatments and experimental design

The study was part of a larger field trial that assessed the impact of crop establishment system and rotation in combination on the performance of a range of crops (full trial layout shown in Supplementary Figure 1). The crop establishment systems plough, shallow plough, min-till and direct drill were the main plot treatments on 30 m × 30 m plots. These plots were replicated four times in a randomized block design. All five individual crops of a 5-year rotation – winter oilseed rape (WOSR), winter wheat (WW1), winter oats (WO), winter wheat (WW2) and winter barley (WB), along with a fixed continuous wheat treatment (WW3) – were grown as sub-plots (30 m × 5 m) within each main plot. This study used the winter wheat grown after winter oilseed rape (WW1) in each of the plough, min-till and direct drill crop establishment treatments.

The plough plots were ploughed in mid-September in year 1 and in early October in years 2 and 3, to a depth of 225 mm. Secondary cultivation and sowing were carried with a combined cultivator and drill unit, using a 2.5 m rotary power harrow with vertical tines, working to a depth of 75 mm and a cereal box-type drill fitted to the harrow with seed coulters spaced at 125 mm (Amazone D9; Amazonen-Werke H. Dreyer SE & Co. KG, Germany). The plots were sown on the 14th, 11th and 10th of October, respectively, for years 1, 2 and 3. The min-till plots were cultivated with a tine-type stubble cultivator (Horsch Terrano FX; Horsch Maschinen GmbH, Germany) to a depth of 75–100 mm in the second half of August or the first days of September and consolidated with a ring roller as part of a stale seedbed process. New weed growth was sprayed with glyphosate three to five weeks later. Sowing was on the same date as the plough plots using a cultivator drill with disc coulters (Vaderstad Rapid; Vaderstad AB, Sweden). The direct drill plots were sown with a double disc direct drill using commercial coulter units (Weaving GD; E F Weaving Ltd., UK) on the same day as the plough and min-till plots. For all treatments, sowing depth was 30–40 mm, and straw from the previous crop was removed.

Crop management

The crops were managed according to normal commercial practice, based on Teagasc guidelines (Collins and Phelan, Reference Collins and Phelan2020), with all crop establishment treatments receiving the same management inputs. Wheat (cv. Graham) grown following a crop of WOSR was sown at 367, 360 and 360 seeds m² on the respective sowing years. Fertilizer nitrogen (N) was applied at a total of 210 kg N/ha in three applications: at Zadoks decimal growth stage (GS) 25 (0.4 of the total N), GS 31 (0.4 of the total N) and GS 37–39 (0.2 of the total N). Phosphorus and potassium were applied in accordance with soil test results. Disease control consisted of a three-spray programme, with fungicides applied when leaf 3 was fully emerged (BBCH 32–33), when the flag leaf was fully emerged (BBCH 39) and at the start of flowering (BBCH 61) (Lancashire et al., Reference Lancashire, Bleiholder, Van den Boom, Langelüddeke, Stauss, Weber and Witzenberger1991). For all systems, weed control consisted of application of residual herbicides (e.g. flufenacet and diflufenican) early post-emergence (late October/early November) for broad-leaved and grass weed control. This was supplemented by spring application of mesosulfuron-methyl and propoxycarbazone-sodium targeting Bromus species and pinoxaden targeting Avena fatua. An insecticide (lambda-cyhalothrin) was applied to all treatments in October/November for aphid control to prevent barley yellow dwarf virus (BYDV) infection.

Data collection

Following crop emergence, plant population density was determined each year by counting plants present along a predetermined length of crop row in six locations within each plot. The area sampled differed by treatment based on drill row spacing; row spacing was 125 mm for plough and min-till treatments and 166 mm for the direct drill treatment. For plough and min-till treatments, four 1 m lengths of a crop row were counted, resulting in area sampled being 0.125 m². For the direct drill system, three 0.75 m lengths of a crop row were counted, resulting in area sampled being 0.1245m². As an indicator of crop growth and biomass development, the fraction of photosynthetically active radiation intercepted (FIPAR) by the crop was determined at growth stages 21–25, 30, 32 and 37. FIPAR was determined by measuring photosynthetically active radiation, both above and below the crop canopy, using a Sunscan Canopy Analysis System (Delta-T Devices, Cambridge, UK) (Gower et al., Reference Gower, Kucharik and Norman1999).

$$FIPAR = 1 - \left( {{{PARBelowCanopy} \over {PARAboveCanopy}}} \right)$$

At crop maturity, samples of a given area (outlined above for establishment counts) were hand harvested (clipped at ground level and secured in hessian bag) from which ears per m², grains per ear and harvest index were subsequently determined. Plots were harvested using a Deutz–Fahr plot combine (SDF Group, Treviglio, Italy) fitted with a Harvestmaster weighing system (Juniper Systems & Harvestmaster Inc., USA) with harvest dates of the 16th, 8th and 4th of August for the 3 years, respectively. Plot yields were recorded and adjusted to 15% moisture content with samples taken for grain quality analysis.

Statistical analysis

Data analysis was carried out using R, version 4.1.0 (R Core Team, Reference Core Team2024). Linear mixed effects models were fitted using plant population density, FIPAR and grain yield data for the 3 years with the ‘lmer’ function from the ‘lme4’ package (Bates et al., Reference Bates, Mächler, Bolker and Walker2015). The models included system and year and interaction of system and year as fixed effects. Random effects were included to account for variation associated with the interaction between year and block, and a nested random effect was included to account for variation among treatment plots within each block (block and column location taken into account). The significance of fixed effects and interactions (P values) was calculated using type III sums of squares with the ‘Anova’ function from the ‘car’ package (Fox and Weisberg, Reference Fox and Weisberg2018). Where significant effects were detected, estimated marginal means were obtained using the emmeans package (Lenth, Reference Lenth2025), and pairwise comparisons were performed using the least significant difference (LSD) method. The same analysis method was also carried out on the same data at an individual year level with system included as a fixed effect and block and column location included as random effects.

To ensure the validity of the linear mixed effects models used in this study, key statistical assumptions were assessed. An analysis of residuals was performed to evaluate normality, homogeneity of variances and independence. Normality of residuals was evaluated visually using quantile-quantile (Q-Q) plots. Model residuals were visually inspected through residuals versus fitted values plots to confirm homogeneity of variances. The assumption of independence of residuals was checked by examining residual plots for patterns that might indicate temporal or spatial autocorrelation.

Field selection and experimental design

To determine the impact of crop establishment system on ‘first’ wheat crops (i.e. those grown subsequent to a break crop) grown on farms, growers using plough, min-till and direct drill systems with a suitable cropping sequence, were recruited from the networks of Teagasc (Irish state-funded research and farm advisory organization) advisors and commercial crop advisors/consultants. Study fields were located within a 65 km radius of Teagasc Oak Park research centre, Carlow, Ireland, which is in the main cereal growing area of Ireland (Figure 1). Twenty-one growers participated each year; seven using each crop establishment system (plough-based, min-till and direct drill). This study was conducted during the same growing seasons as the replicated trial: 2020/2021, 2021/2022 and 2022/2023. A different field was monitored each year with each grower due to rotation constraints, giving a total of 63 monitored fields over the three years. If a grower didn’t have the target crop available, a new grower was subbed in. Soil texture and rotation sequence information is given in Table 2. All fields were managed under their respective crop establishment system for a minimum of 5 years for plough and min-till and 3 years for direct drill in advance of the reported study. The minimum number of years was reduced for direct drilling compared to other systems as there were very few growers in Ireland with a history of direct drilling that was greater than 3 years at the time of the study. The study fields also had combinable crops (cereals, oilseeds and grain legumes) grown for a minimum of 10 years prior to the experimental period. The mean field size was 11.86 ha (range: 2.06–50.40 ha). Plough-based establishment on farms was very similar to that implemented in the replicated trial. However, cultivation depth for min-till growers ranged from 50–150 mm, and most direct drill growers used a very shallow (∼20–30 mm) stubble cultivation/straw harrow operation to encourage germination of weed seeds and volunteers before glyphosate application in advance of planting.

Figure 1. Study site area: all sites were within the marked area.

Table 2. Soil texture analysis and preceding crops for on-farm fields

^a Soil texture based on UK soil texture classifications (Natural England, 2008).

^b Oats is considered a break crop in Ireland as it is not susceptible to the same take-all (Gaeumannomyces graminis) disease strain as wheat or barley, conferring a disease break to the following wheat or barley crop.

Data collection, establishment and growth

At the start of each year, 10 positions within each study field were selected using a ‘W’ pattern, with all points adjacent to crop tramlines and located subsequently by their satellite-determined co-ordinates and a field marker. Crop information was collected at these positions throughout the growing season. Field headlands were avoided due to variability in both management and crop performance associated with these areas. Following crop emergence (autumn), plant population density was determined by counting plants present along a predetermined length of crop row at each of the 10 points in each field; the length of row sampled depended on the row spacing of the drill used to establish that field. The FIPAR by the crop was determined at each of the 10 points at growth stage 21–25, 30, 32 and 37 as outlined previously where data collection methodology of the replicated trial is described.

Yield estimation in growers’ fields

As it was not feasible to use a plot combine to assess yields in each of the 21 fields due to the crop ripening in a short time period at crop maturity across all the locations, a detailed manual yield estimation technique was used, which allowed a wider sampling time window. The technique developed by Ward et al. (Reference Ward, Forristal and McDonnell2020) was adapted to account for differences in row widths, meaning a predetermined number of row lengths, adopted for the row width of the drill, were harvested to give a precise sample size in the range: 0.25–0.3 m². Whole crop samples were harvested from the sample positions. The samples were dried in a glasshouse, weighed, heads removed and threshed (Saatmeister Kurt Pelz, Maschinenbau, Germany) and the resulting grain cleaned (Laboratory seed winnower, type 4111.10.00, Seed Processing Holland, Enkhuizen, the Netherlands). All yield components were weighed and dry matters determined. This technique generated a yield figure (t/ha) for each of the in-field sample points. These yield estimates tend to be higher than total field yield estimates as headland areas are avoided and no allowance for uncropped tramlines is made (Ward et al., Reference Ward, Forristal and McDonnell2020). Harvest parameters including ears per m², grains per ear and harvest index were determined.

Crop management

As this study was carried out in commercial fields, crop management and husbandry practices varied both within and among crop establishment system groups. To account for potential effects on crop performance these variations in crop management and husbandry practices may have had, detailed records of all management actions, including input types and quantities, application rates and timings and all machinery operations were obtained from growers.

Statistical analysis

Comparisons between the different crop establishment system groups must be considered carefully, due to the limited number within each group, variations in management practice and site differences.

To determine if plant establishment was more variable in certain systems, the coefficient of variation of the plant density figures from the ten positions within each study field was used. The coefficient of variations of the different systems were then compared by carrying out an analysis of variance using the ‘aov’ function from the ‘stats’ package (R Core Team, Reference Core Team2024). Analysis of variance was also carried out on FIPAR and yield component (harvest index, ears/m², grain/ear, thousand-grain weight [TGW], HL weight and protein) data to determine if there were significant differences between the different systems. For these analyses of variance, for the all-years data, system, year and the interaction of systems and year were included as effects. When significant effects were found, a post hoc Tukey multiple comparison of means was used (TukeyHSD function from the ‘stats’ package, R Core Team, Reference Core Team2024). Analyses of variance were also carried out on the data at an individual year basis with system only included as an effect. Prior to conducting the analysis of variances, the data were examined to ensure compliance with the key assumptions of normality, homogeneity of variances and independence. Normality of residuals was evaluated visually using quantile-quantile (Q-Q) plots. Homogeneity of variances was assessed by visual inspection of residuals versus fitted values plots, and independence of residuals was verified by examining residual plots for patterns that might indicate temporal or spatial autocorrelation.

To determine the factors that may impact on crop yield, a linear mixed effects model was fitted using 3 years data as described previously for the replicated trial. System, year and the interaction of system and year were included as fixed effects. Nitrogen application rates and fungicide expenditures were grouped into bands of 10 units (e.g. kg N/ha for nitrogen, €/ha for fungicides), with growers assigned to categories based on their respective input levels. These groupings were included as random effects along with soil texture (its effect was allowed to vary by year). As previously described, p-values were computed for the final model, and where significance was detected, pairwise comparisons were carried out using the LSD method. The same analysis method was also carried out on the same data at an individual year level with system included as a fixed effect and nitrogen application rate, grower fungicide spend and soil texture included as random effects. Prior to conducting the linear mixed effects model analysis, the data were evaluated to ensure that key assumptions were met as previously described.

A nitrogen application rate per hectare for each grower was established by calculating the nitrogen supplied by chemical and organic fertilizers. These nitrogen application rates were then adjusted based on the amount of nitrogen that was estimated to have been supplied by the preceding crop (e.g. legume or oilseed rape vs oats) type based on the guidelines in the Teagasc Winter Wheat Guide (Lynch et al., Reference Lynch, Spink, Doyle, Hackett, Phelan, Forristal, Kildea, Glynn, Plunkett, Wall and Hutton2016). A fungicide spend per hectare for each grower was established by multiplying the fungicide product rates used by growers by the recommended retail prices for these products.

With growers free to manage their crops as they normally would, there were inevitable differences in management between growers. If these differences were associated with establishment system, then they could be confounding the results. Therefore, key yield influencing inputs, in this case nitrogen application rate and grower fungicide spend, were tested to see if they were confounded with crop establishment system as failing to identify confounders can bias results and attribute effects to system that are actually due to other factors. To robustly assess potential confounding, we employed several complementary methods to test whether input application rates were confounded with system. The Kruskal–Wallis test (kruskal.test function) was used to test for associations between crop establishment system and input levels; kruskal.test function is from the ‘stats’ package (R Core Team, Reference Core Team2024), and associations of nitrogen application rate and grower fungicide spend with the system would indicate possible confounding. Spearman correlations (cor.test function) were used to test whether nitrogen rate and fungicide spend were correlated with yield; correlations of these factors with yield would indicate possible confounding, and cor.test function used is from the ‘stats’ package (R Core Team, Reference Core Team2024). A linear fixed effects model was fitted using the lm function (Lenth, Reference Lenth2025) with nitrogen application rate and grower fungicide spend as fixed effects to test whether these effects were significant predictors of yield; effect significance was calculated using type III sums of squares as previously described. These factors being significant predictors of yield would indicated possible confounding. Another approach was to fit 2 linear fixed effects models, one including system, year, the interaction of system and year, nitrogen application rate and grower fungicide spend as fixed effects and another that included system, year, the interaction of system and year as fixed effects, these models were then compared to assess how the estimated effect of system changes when nitrogen application rate and grower fungicide spend were included. A change by more than 10% in the estimated effect of system would indicate possible confounding. This multifaceted approach is consistent with recommendations in the literature to confirm confounding from multiple perspectives (Mickey and Greenland, Reference Mickey and Greenland1989; Maldonado and Greenland, Reference Maldonado and Greenland1993; Brookhart et al., Reference Brookhart, Schneeweiss, Rothman, Glynn, Avorn and Stürmer2006).