Plots were established in 2003 and 2004 at the Cavendish Farms Experimental Research Station in New Annan, Prince Edward Island, Canada. The soil at this site is a fine sandy loam (Orthic Podsol in FAO classification; Carter and Sanderson 2001). Plots were planted in areas not planted with potatoes during the two previous years. Two years prior to potato planting, a barley crop was underseeded with a mixed grass/legume crop consisting of Timothy grass and clover.

Certified seed tubers of cvs. Shepody and Russet Burbank were planted in plot islands on 20 May 2003 and 24 May 2004. Potato seed pieces were planted with a 25 cm and 46 cm within-row spacing for Shepody and Russet Burbank, respectively. Each plot consisted of four rows (two rows of Shepody and two rows of Russet Burbank) measuring 6.1 m in length with 91 cm spacing between rows; the two outer rows were used as guard rows. Plot islands were separated by fallow areas approximately 4 m wide to permit the application of chemicals with a tractor-mounted sprayer (Hardi three-point hitch model). This separation of treated blocks reduces drift concerns and prevents mechanical damage to foliage caused by tractor wheels during spraying.

At planting (for both years), 15-15-15 (N-P-K) fertilizer was applied at a rate of 1121 kg ha^‑1 using the banding technique, giving approximately 165 kg ha^‑1 usable N. All plots received standard commercial pesticides to control weeds and insects. The herbicides linuron (3-(3,4-dichlorophenyl)-1-methoxy-1-methylurea) at 1.25 kg a.i. ha^‑1 and paraquat (1,1’-dimethyl-4,4’-bipyridinium) at 750 g a.i. ha^‑1 were applied for pre-emergence weed control. Throughout the growing season, the plots were sprayed one time each with foliar insecticides spinosad (2-{(6-Deoxy-2,3,4-tri- O-methyl-alpha-L-mannopyranosyl)oxy}-13- {{5-(dimethylamino)tetrahydro-6-methyl-2H-pyran-2-yl}oxy}-9-ethyl-) at 72 g a.i. ha^‑1 and imidacloprid ((EZ)-1-(6-chloro-3-pyridylmethyl)-N-nitroimidazolidin-2-ylideneamine) at 48 g a.i. ha^‑1 for control of the Colorado potato beetle, Leptinotarsa decemlineata Say [Coleoptera: Chrysomelidae], and aphids [Homoptera: Aphididae]. Plots were also sprayed post-emergence with clethodim herbicide ((5RS)-2-{(E)-1-[(2E)-3-chloroallyloxyimino]propyl}-5-[(2RS) -2-(ethylthio)propyl]-3-hydroxycyclohex-2-en-1-one) (15 g a.i. ha^‑1) to suppress couch grass.

The experimental design was a randomized block (factorial) with fungicide treatments (control, azoxystrobin or pyraclostrobin) and nitrogen fertility rates (high or low) as factors, with each treatment combination occurring once in each of the four replications. To facilitate mechanical planting, seed of a particular cultivar was planted continuously across successive plot islands. Therefore, cultivars were not randomly assigned to plot locations and could not be considered as a factor in subsequent analyses of variance.

In 2003, the fungicide chlorothalonil (tetrachloroisophthalonitrile) was applied five times at 1 kg a.i. ha^‑1 during the early part of the growing season to prevent the development of late blight. However, because chlorothalonil, even though applied early in the season, could still potentially have had a suppressing effect on the development of early blight, an initial application of chlorothalonil was followed by five applications of fluazinam (3-chloro-N-(3-chloro-5-trifluoromethyl-2-pyridyl)-α,α,α-trifluoro-2,6-dinitro-p-toluidine) at 200 g a.i. ha^‑1 in 2004. Experimental fungicide treatments, in addition to the aforementioned applications, included controls treated with either chlorothalonil (2003) or fluazinam (2004), azoxystrobin treatments (methyl (E)-2-{2-[6-(2-cyanophenoxy)pyrimidin-4-yloxy]phenyl}-3-methoxyacrylate), and pyraclostrobin treatments (methyl {2-[1-(4-chlorophenyl)pyrazol-3-yloxymethyl]phenyl}(methoxy)carbamate). Each of the azoxystrobin and pyraclostrobin plots were sprayed twice (once in late July/early August and once in early September) at a rate of 162.5 g a.i. ha^‑1 and 140 g a.i. ha^‑1, respectively. Fungicides were applied with a tractor-mounted Hardi three-point hitch sprayer calibrated to apply 40 L ha^‑1.

Fertility treatments included two rates of N fertilizer. Initial N application for all treatments was 165 kg ha^‑1 as starter fertilizer banded at planting as described above (standard N application rate). Plots receiving the high rate of N fertilizer were top-dressed with an additional 165 kg ha^‑1 of ammonium nitrate (34% N) in mid-July for a total of 55 kg ha^‑1 available N.

Due to the lack of natural disease development, attempts were made to initiate fungal infections in the research plots by inoculating plants with a conidial suspension of A. solani. Conidia were produced by plating several virulent A. solani isolates obtained locally onto clarified V-8 agar and incubating them in a growth cabinet set at 21°C with alternating exposure to UV light and darkness (12 h UV exposure followed by 12 h darkness). After 12-14 d, the cultures were profusely covered with spores, and inoculum was prepared by flooding the plates with 40-50 mL sterile distilled water and gently rubbing the surface of the plates with a rubber policeman to dislodge the conidia. The resulting suspensions were combined and then mixed with 10 L of sterile distilled water. The concentration of conidia was determined with a hemacytometer and the final concentration was adjusted, with additional sterile distilled water, to 5 x 10³ conidia mL^-1. The isolates were determined to be sensitive to azoxystrobin using an in vitro agar assay which measured inhibition of spore germination in the presence of the chemical (MacDonald et al., unpublished data).

Plots were artificially inoculated on 3 September 2003 and 21 August 2004 with the conidial suspensions using a hand-held sprayer. A total of 200 mL of inoculum was applied per row. Inoculations were performed at dusk so that leaves would remain wet for several hours following inoculation.

At the end of the season, while the foliage was still green, early blight disease severity was assessed visually in each plot. The assessments were made first by estimating the percentage of foliage showing early blight lesions and assigning a disease rating based on the Horsfall-Barratt disease assessment scale (Horsfall and Barratt 1945).

Prior to harvest, plots were vine-killed with diquat (9,10-dihydro-8a,10a-diazoniaphenanthrene) at 300 g a.i. ha^‑1. Tubers from plots were machine-harvested from the two inner rows, one each of Russet Burbank and Shepody, on 8 October 2003 and 7 October 2004. All tubers harvested from each plot (6.1 m row) were graded for size distribution and weight based on three categories: <2 in. (5.08 cm) diameter; >2 in. (5.08 cm) diam but less than 10 oz. (283.5 g); and >10 oz. (283.5 g). These data were used to calculate total tuber yield in each plot. A sub-sample of 25 tubers was taken from each plot to determine specific gravity, fry colour, and internal defects (hollow heart, etc.). The prime tuber yield, often referred to as the pay weight, was determined by subtracting small (<2 in. (5.08 cm) diam) and defective tubers from the total yield. Furthermore, economic return values, measured in Canadian dollars ha^‑1, of harvested tubers were generated based on Cavendish Farms contract criteria. Based on these criteria, increased payments are made for potato samples with increased weight of tubers >10 oz. (283.5 g), increased specific gravity, and uniform light fry colour, while potato samples with internal defects (hollow heart, etc.) are subject to dockage.

Following tests for homogeneity of variance and due to the presence of significant interactions of the repeated experiments with main effects or with interaction terms, data for each field season was analyzed separately. Since Shepody and Russet Burbank plot locations were not randomly assigned, data for each cultivar within a field season was analyzed separately to examine differences among fungicide and N fertility treatments within a cultivar. Testing for statistical significance of fungicide treatment, N rate and interactions between these two factors was achieved by using a two-way analysis of variance (ANOVA). The analyses were conducted with SPSS statistical software (SPSS^® for Windows^®, Chicago, IL, USA).

The total yield of tubers, measured in tonnes ha^‑1, was influenced by the fungicide treatment. In 2003, there was a significant fungicide effect on the total tuber yield of Russet Burbank, while in 2004, a significant fungicide treatment effect was observed for the total yield of Shepody (Table 1). In both instances, azoxystrobin and pyraclostrobin treatments were linked to significantly higher yields compared with the untreated control plots (Figs. 1A and 1B).

There were no significant differences in total tuber yield based on the N fertility regimes in either 2003 or 2004 (Table 1). Similarly, there were no significant interactions between fungicide treatment and N rate in both years of the study (Table 1), indicating that the effect of fungicide treatment was independent of N fertility regime.

A significant fungicide treatment effect was observed for the pay weights, measured in tonnes ha^‑1, of Russet Burbank in 2003 and Shepody in 2004 (Table 1). Plots of Russet Burbank treated with azoxystrobin or pyraclostrobin yielded significantly higher pay weights compared with the untreated control plots (Fig. 1C). However, a post hoc analysis of the 2004 Shepody pay weights revealed that only the azoxystrobin treatment gave a significantly higher pay weight compared with the untreated control plots (Fig. 1D). Although the average pay weight for the pyraclostrobin treated plots was higher than that in the control plots, this difference was not significant.

Similar to the results obtained for total tuber yield, pay weights were not influenced by the level of N fertility and no significant interactions between fungicide and N fertility programs were observed in either year of study (Table 1).

As stated previously, economic return is based on a series of criteria including tuber size/weight categories, specific gravity, fry colour, and internal defects. It is the economic return that determines what the grower will receive, in terms of dollars, for a particular yield of tubers. Although azoxystrobin and pyraclostrobin always gave higher monetary returns compared with the controls (Table 2), the only significant increases in return were observed in the 2003 Russet Burbank crop and the 2004 Shepody crop (Tables 1 and 2). Again, there was no effect of N fertility on financial returns, and no interactions between fungicide and N fertility regimes were observed (Table 1).

Natural early blight disease pressure was negligible in both years of the study. For this reason, plots were artificially inoculated in an attempt to induce the disease. In 2003, no early blight symptoms developed despite artificial inoculation. In 2004, leaf lesions induced by inoculation were visually apparent in the untreated controls about three weeks after artificial inoculation. Lesion areas, based on Horsfall-Barratt ratings, ranged from 1-5 (3-50%) in Russet Burbank controls (Fig. 1E) and from 4-6 (25-75%) in Shepody controls (Fig. 1F). In plots treated with azoxystrobin and pyraclostrobin, leaf area with lesions of early blight was consistently 0 or 1 (less than 3%) (Figs. 1E and 1F). Disease severity was consistently similar in replications of the same treatment.

The effect of N rate was less marked than the effect of fungicide treatment. However, Russet Burbank check plots treated with the low N rate had an average Horsfall-Barratt rating of 4.2, where 4 corresponds to 12–25% of lesion area, compared with the high N rate which had an average rating of 2.2, where 2 corresponds to 3–6% of lesion area (Fig. 1E). The severity of early blight was low at both rates of N fertility when azoxystrobin or pyraclostrobin were used as a component of the fungicide program (Fig. 1E). As expected, Russet Burbank control plots generally had lower severity of early blight compared with Shepody control plots (Figs. 1E and 1F).