Mean fresh tuber yield (FTY) was significantly affected by pot size (p< 0.001) and cultivar (p< 0.001), but not by treatment (p = 0.081) ( Table 2 , Supplementary Table S1 ). There was also a single significant interaction effect between pot size and treatment (p = 0.003) on FTY. Pot size had the greatest effect of the three grouping factors; there was a large (836.8 g, 117.1%) difference in FTY across all plants in 20 L pots x ¯ = 1132.8   g compared to 5 L pots x ¯ = 296.0   g . The difference between cultivars was much smaller (71.8 g, 13%); the mean FTY of all Maris Piper plants x ¯ = 683.1   g was slightly higher than that of Charlotte x ¯ = 611.3   g .

When grouped by pot size, treatment had a significant effect on FTY in 20 L pots (p = 0.001), but not in 5 L pots (p = 1.000). The response to treatment in 20 L pots was dose-dependent ( Figure 1 ). Each increase in irrigation frequency was associated with an increase in FTY, but only the difference between T_1/2 and T₁ or T₂ was significant (p< 0.05). There was a small (63.0 g, 5.8%) difference in FTY between 20 L pots under T_1/2 x ¯ = 1053.7   g and T₁ x ¯ = 1116.8   g , and a larger (114.7 g, 9.8%) difference between the latter and pots under T₂ x ¯ = 1231.4   g .

The analysis of tuber number demonstrated a lack of within-group normality due to the incongruently consistent tuber number within a single group (T_1/2, 5 L, Charlotte). In this group, all but one replicate produced 10 tubers, the other produced 7, causing a significantly non-normal distribution (p< 0.001) that was not present across the whole sample or within any other groups. Further statistical analysis was discarded, but simple summary statistics showed only pot size had a noticeable effect on tuber number; plants in 5 L pots produced an average of 10 tubers, compared to 25 tubers in 20 L pots. When grouped by either cultivar or treatment, average tuber number per plant was within one tuber for each group.

There was sufficient variation in FTY within the non-normal group that further analysis of mean tuber mass was appropriate. Mean tuber mass was only significantly affected by pot size (p< 0.001), with no statistically significant interactions ( Table 2 ). There was a small (13.4 g, 35.8%) difference between the pot sizes; the mean tuber mass of all plants in 20 L pots x ¯ = 44.0   g was slightly higher than that in 5 L pots x ¯ = 30.6   g .

In summary, mean fresh tuber yield (FTY) was significantly affected by pot size and cultivar, but not by treatment ( Table 2 , Supplementary Table S1 ). Pot size had the greatest effect on FTY, with an 836.8 g (117.1%) difference between FTY in 5 and 20 L pots; FTY was greater in the latter. Treatment had a significant effect exclusively in 20 L pots, with each increase in irrigation frequency being associated with an increase in FTY, although the difference in FTY between plants irrigated daily and twice daily was not significant in this pot size ( Figure 1 ). Mean tuber mass was also significantly affected by pot size, but the effect was small (13.4 g, 35.8%).

Mean tuber dry matter percentage (TDM%) was significantly affected by pot size (p< 0.001) and cultivar (p< 0.001), but not by treatment (p = 0.499). There was also a significant interaction between pot size and cultivar (p = 0.003) ( Table 2 ). Cultivar had the greatest effect of the three grouping factors; there was a small (3%, 14.3%) difference in TDM% between Maris Piper x ¯ = 20.7 % and Charlotte x ¯ = 18.0 % . The difference between pot sizes was smaller (1.2% 6.5%); the mean TDM% of all plants in 5 L pots x ¯ = 20 % was very slightly higher than of those in 20 L pots x ¯ = 19 % .

The interaction effect between pot size and cultivar demonstrated a difference in the effect of pot size on TDM% between the two cultivars. There was no significant (p = 1.000) difference in the TDM% of Charlotte between the 5 L x ¯ = 18.0 % and 20 L pots x ¯ = 17.9 % , but there was a significant (p< 0.001) difference (2.3%, 10.9) between Maris Piper in 5 L x ¯ = 21.9 % and 20 L pots x ¯ = 19.6 % . TDM% in Maris Piper was also significantly higher than that of Charlotte in both 5 L (p< 0.001) and 20 L (p< 0.001) pots.

Fresh canopy biomass was significantly affected by pot size (p< 0.001), cultivar (p< 0.001), and treatment (p< 0.001) ( Table 2 ). There was also a significant interaction between pot size and treatment (p = 0.043). Pot size had the greatest effect on canopy biomass, with a very large (934.1 g, 191.9%) difference between 5 L x ¯ = 173.3   g and 20 L pots x ¯ = 953.7   g . Maris Piper x ¯ = 444.8   g produced heavier (73.3 g, 18.0%) canopies than Charlotte x ¯ = 371.5   g and each increase in irrigation frequency was associated with an average increase in fresh biomass, although these were not always significant.

Analysis of the interaction effect between pot size and treatment showed that, when averaged across the two cultivars, canopy biomass increased significantly (p< 0.05) between T_1/2 and T₁ in both 5 L and 20 L pots, with a difference of 45.1 g (27.3%) and 129.0 g (13.9%) between treatments, respectively. In the 5 L pots, there was no significant difference in biomass between the T₁ x ¯ = 187.4   g and T₂ x ¯ = 195.1   g treatments. This effect was consistent in the 20 L pots, where there was no significant difference between the T₁ x ¯ = 1010.3   g and T₂ x ¯ = 993.4   g treatments ( Figure 2 ).

Canopy dry matter percentage (CDM%) was significantly affected by all three grouping factors (pot size, p< 0.001; cultivar, p< 0.001; treatment, p = 0.003) and there was a significant interaction effect between pot size and cultivar (p< 0.001) ( Table 2 ). When averaged across all treatments, pot size had a significant effect on the CDM% of Charlotte (p< 0.001), but not on that of Maris Piper (p = 0.590). The CDM% of Maris Piper in 5 L x ¯ = 10.5 % and 20 L pots x ¯ = 10.8 % were within 1%, while that of Charlotte was significantly lower in 20 L pots x ¯ = 6.7 % than in 5 L pots x ¯ = 8.3 % . Cultivar had the greatest effect on CDM%, with an absolute difference of 3.1% (34.7% difference), compared to a 0.8% (8.7% difference) between the pot sizes. Treatment had a smaller effect, with an absolute difference of 0.5% (5.7% difference) between plants under T_1/2 and T₁, and 0.3% (3.6% difference) between the latter and T₂. Again, there was a significant difference in canopy dry matter percentage between T_1/2 irrigation and T₂ (p< 0.05), but not between either of those frequencies and T₁ (p > 0.05).

Canopy temperature was significantly affected by treatment (p< 0.001), pot size (p< 0.001), cultivar (p = 0.001), and sample date (p< 0.001) and there was a significant (p = 0.006) four-way interaction between cultivar, pot size, treatment, and sample date ( Table 3 ). When this interaction effect was broken down by cultivar, there was a significant (p< 0.001) three-way interaction between pot size, sample date, and treatment in both Maris Piper and Charlotte. When each cultivar was grouped by pot size, there was a significant (p< 0.001) interaction between treatment and sample date in all four groups. Significant effects of treatment were only seen on specific sample dates, which varied between the groups of cultivar and pot size ( Figures 3 , 4 ).

Across all other factors, canopy temperature demonstrated a dose-dependent response to treatment ( Figure 5 ), as each increase in irrigation frequency was associated with a significant decrease in canopy temperature (p< 0.05). Plants under T_1/2 x ¯ = 18.7 ° C were 0.6°C warmer than those under T₁ x ¯ = 18.0 ° C . Plants under T₁ were also 0.3°C warmer than those under T₂ x ¯ = 17.7 ° C . This relationship was consistent within each pot size, although canopy temperatures within each treatment were significantly higher in 5 L pots compared to 20 L pots (p< 0.05).

Plants under T_1/2 in 5 L pots x ¯ = 19.3 ° C were 1.3°C warmer than those under the same conditions in 20 L pots x ¯ = 18.0 ° C . Plants under both T₁ and T₂ were both 0.4°C warmer in 5 L pots ( x ¯ = 18.2 ° C  and  17.9 ° C , respectively) compared to 20 L pots ( x ¯ = 17.8 ° C  and  17.5 ° C , respectively). Canopy temperatures in each group of pot size and treatment were significantly different from all other groups (p< 0.05), except for T_1/2 in 20 L pots and T₁ in 5 L pots.

This relationship between canopy temperature, treatment, and pot size was similar between the cultivars. There was a larger difference in canopy temperature between plants under T₁ and T_1/2 in 5 L pots compared to 20 L pots, in both Maris Piper ( Δ x ¯ = + 1.2 ° C  and + 0.2 ° C , respectively) and Charlotte ( Δ x ¯ = + 0.9 ° C  and + 0.2 ° C , respectively). The temperature differences between plants under T₂ and T₁ were more consistent, with a 0.3°C increase in canopy temperature in Maris Piper and a 0.4°C increase in temperature in Charlotte, both regardless of pot size.

The relationships between canopy temperature, treatment, pot size, and cultivar were particularly evident when grouped by sample date ( Figures 3 , 4 ). The difference in canopy temperature between plants under T_1/2 and T₁ was frequently much larger, and more likely to be significant, in 5 L pots than 20 L pots, regardless of cultivars.

In summary, canopy temperature was significantly affected by treatment, pot size, cultivar, and sample date, with a significant interaction effect between all four factors ( Table 3 ). Across all other factors, canopy temperature demonstrated a dose-dependent response to treatment, as each increase in irrigation frequency was associated with a significant decrease in canopy temperature ( Figure 5 ). This relationship was consistent within each pot size, although canopy temperatures within each treatment were significantly higher in the smaller pots. All these groups were significantly different from one another, except for plants irrigated every other day in 20 L pots and every day in 5 L pots. When grouped by sample date, the difference in canopy temperature between plants irrigated every other day and daily was more likely to be significant in the smaller pots; this effect was consistent between the cultivars.

Average canopy SPAD was significantly affected by cultivar (p< 0.001) and sample date (p< 0.001) but not by pot size (p = 0.502) or treatment (p = 0.612) ( Table 3 , Supplementary Table S1 ). The four-way interaction was not significant (p = 0.779), but there was a significant interaction between pot size, cultivar, and sample date (p = 0.001). When grouped by sample date, there were significant (p< 0.05) interactions between pot size and cultivar on thirteen of the twenty-two sample dates. Post-hoc pairwise comparisons for each sample date with a significant interactions demonstrated that Charlotte had consistently higher SPAD values in both pot sizes, Charlotte in 5 L pots began the experiment with significantly (p< 0.05) higher SPAD values than Charlotte in 10 L pots and Maris Piper in both pot sizes, and Maris Piper ended the experiment with significantly (p< 0.05) lower SPAD values than the other three groups ( Figure 6 ).

Digital canopy biomass ( Figure 7 ) was also significantly affected by pot size (p< 0.001), cultivar (p< 0.001), and treatment (p = 0.003). In contrast to fresh canopy biomass, there was also a marginally significant interaction between all three grouping factors (p = 0.05), and significant interactions between each pair of factors ( Table 4 , Supplementary Table S1 ). Again, pot size had the greatest effect, with a difference of 163.23 dm³ (138.1%) in digital biomass between 5 L x ¯ = 36.60   d m 3 and 20 L pots x ¯ = 199.83   d m 3 .

When grouped by cultivar, there was a significant interaction between pot size and treatment on digital canopy biomass in Maris Piper (p = 0.003) but not in Charlotte (p = 0.246). When grouped further by pot size, treatment had a significant effect on Maris Piper in both 5 L (p = 0.004) and 20 L pots (p = 0.002). There was no interaction between pot size and treatment in Charlotte as the effect of treatment on digital canopy biomass was insignificant in 20 L pots (p = 1.000).

In 5 L pots, there was a significant, strong, positive correlation between fresh canopy biomass and digital canopy biomass (r (16) = 0.780, p< 0.001). However, in 20 L pots, this correlation was not significant (r (16) = 0.015, p = 0.952) ( Figure 8 ). A similar correlation was found between manual and digital measurements of plant height. In 5 L pots there was a significant positive correlation (r (16) = 0.896, p< 0.001), but in 20 L pots, this correlation was not significant, (r (16) = -0.390, p = 0.110).

Average greenness was significantly affected by pot size (p< 0.001) and cultivar (p = 0.001), but not by treatment (p = 0.896) ( Table 4 ). There was also a significant three-way interaction between all three grouping factors (p< 0.001). When grouped by cultivar, there was a significant interaction between pot size and treatment in Charlotte (p< 0.001) but not Maris Piper (p = 0.204). The effect of treatment on Charlotte was only significant in 20 L pots (p< 0.001). Within this group, average greenness was significantly (p< 0.05) higher with under T_1/2 compared to T₁ and T₂, which were not significant different from each other. Overall, Maris Piper x ¯ = 0.33 had a slightly (0.04 index units, 4.5%) higher average greenness than Charlotte x ¯ = 0.31 and plants in 20 L pots x ¯ = 0.35 had a higher (0.06, 17.7%) average greenness than those in 5 L pots x ¯ = 0.29 . Overall, there was no significant correlation between average greenness and average canopy SPAD values (r (16) = -0.213, p = 0.213). When broken down by pot size, there was a significant, very strong, negative correlation between these two variables in 5 L pots (r (16) = -0.864, p< 0.001), but not in 20 L pots (r (16) = 0.344, p = 0.162).

Average hue was significantly affected by all three grouping factors (pot size, p< 0.001; cultivar, p< 0.001; treatment, p = 0.001) and there was a significant three-way interaction (p = 0.002) ( Table 4 ). When grouped by cultivar, there were significant interactions between pot size and treatment in both Maris Piper (p< 0.001) and Charlotte (p = 0.012). Treatment had a significant effect on Charlotte in 5 L (p = 0.008) and on Maris Piper in 20 L pots (p< 0.001), but not on Charlotte in 20 L pots (p = 0.788) or on Maris Piper in 5 L pots (p = 0.696). However, the differences in average hue between treatments within these groups were very small (≤ 5.3%).

Whole-plant average NDVI was significantly affected by treatment (p< 0.001) and pot size (p< 0.001), but not by cultivar (p = 0.280) ( Table 4 ). There was a significant three-way interaction between all three grouping factors (p< 0.001). When grouped by cultivar, there were significant two-way interactions between treatment and pot size in both Maris Piper (p = 0.048) and Charlotte (p< 0.001). Within each cultivar, the effect of treatment was only significant in 20 L pots (Maris Piper, p< 0.001; Charlotte, p< 0.001). However, the percentage differences between treatments within these groups were small (< 5%).

Whole-plant average PSRI was significantly affected by treatment (p = 0.001), pot size (p< 0.001), and cultivar (p< 0.001) and there was a significant three-way interaction between all three grouping factors (p = 0.002) ( Table 4 ). When grouped by cultivar, there were significant interactions between treatment and pot size in both Maris Piper (p< 0.001) and Charlotte (p< 0.001). Within each cultivar, the effect of treatment was significant in both cultivars in both pot sizes (Maris Piper: 5 L, p< 0.001; 20 L, p< 0.001; Charlotte: 5 L, p< 0.001; 20 L, p< 0.001). The percentage differences between these groups were large, but the absolute differences between significantly different groups were still small (< 0.03 index units).

Leaf angle was not significantly affected by any of the grouping factors and there were no significant interactions ( Table 4 ).

Light penetration depth was significantly affected by treatment (p = 0.013) and pot size (p< 0.001), but not by cultivar (p = 0.179) ( Table 4 ). There was a single significant interaction between pot size and cultivar (p = 0.001); the effect of cultivar was significant in 5 L pots (p = 0.004), but not in 20 L pots (p = 0.262). The difference in light penetration depth between Maris Piper and Charlotte was 82.49 mm (46.7%) in 5 L pots, compared to only 36.61 mm (11.7%) in 20 L pots. Light penetration depth was shorter for Charlotte in 5 L pots x ¯ = 135.52   m m compared to Maris Piper x ¯ = 218.01   m m , but longer in 20 L pots (Charlotte, x ¯ = 331.47   m m ; Maris Piper, x ¯ = 294.86   m m ). Light penetration depth also increased with increasing irrigation frequency, but the only significant difference occurred between T_1/2 and T₂ (p< 0.05).

This experiment aimed to investigate the water availability hypothesis of pot binding in potato. The hypothesis states that pot binding, i.e., the confounding effects of small pots on plant morphophysiology, is primarily a result of an unintentional drought stress experienced by purportedly well-watered plants (Sinclair et al., 2017). Pot binding is thought to occur when the water holding capacity of a potted substrate is insufficient to prevent drought stress between irrigation periods (Turner, 2019). Previous research has suggested that pot binding can be mitigated by providing plants with 1 L of substrate for every gram of dry biomass that a plant is expected to produce (Poorter et al., 2012). As potato has been observed to generate over 1,000 g of dry biomass (Wheeler and Tibbitts, 1987), this recommendation is impractical for this crop in most controlled environmental facilities.

To test this hypothesis, we grew two cultivars of potato, Maris Piper and Charlotte, in two pot sizes, 5 and 20 L, each under one of three water treatments: irrigation to saturation twice daily (T₂), daily (T₁), or every other day (T_1/2). If pot binding is a product of water unavailability under T₁ conditions, then morphophysiological indicators of drought stress should be observed in both T_1/2 and T₁ plants. This effect should be mitigated by increasing the pot size (Poorter et al., 2012; Turner, 2019) or by increasing the irrigation frequency (Sinclair et al., 2017; Turner, 2019).

Therefore, we hypothesised that there would be greater similarities in traits known to be affected by drought stress between T₁ and T_1/2 treatments in the smaller pots. We also hypothesised that this effect would be mitigated in the larger pots, and by increasing the frequency of irrigation from T₁ to T₂. We assessed several morphophysiological indicators of drought stress that have previously been shown to affect potato, including tuber yield, canopy biomass, canopy and tuber dry matter (Obidiegwu et al., 2015; Hill et al., 2021), average canopy temperature (Stark et al., 1991; Ninanya et al., 2021) and SPAD values (Li et al., 2019).

Fresh tuber yield and canopy biomass are the two morphological traits most sensitive to water-restriction in potato (Jefferies and Mackerron, 1987, Jefferies and Mackerron, 1993). As plant tissue growth is primarily a result of cell elongation (Shao et al., 2009), which is driven by high turgor pressure (Lockhart, 1965), water deficits result in reduced growth of many tissues. Canopy biomass is also particularly affected by water-restriction in potato, compared to other crops. Leaf growth in most crop species ceases when the fraction of transpirable soil water drops below 40-50%; in potato leaves, growth is negligible once the available soil water reaches 60% (Weisz et al., 1994).

In this experiment, fresh tuber yield was significantly reduced by decreasing irrigation frequency from T₁ to T_1/2, but only in the larger, 20 L pots. In the 5 L pots, there was no meaningful difference in tuber yield between T₁ and T_1/2 ( Figure 1 ). This is consistent with the water availability hypothesis of pot binding, as the difference in yield between the hypothetically well-watered and intentionally drought stressed plants was minor compared to the yield difference in the large pots. This also supports previous research, which found that potato yield reductions associated with water-restriction increased with pot size (Hill et al., 2023) ¹ .

Increasing irrigation from T₁ to T₂ was not sufficient to increase fresh tuber yield in 5 L pots ( Figure 1 ), suggesting that saturation twice per day in very small pots is still insufficient to prevent pot binding in potato. It could be suggested that yields in the small pots were limited by the pot volume, rather than drought stress. However, there was no evidence that this was the case as yields in the small pots were very low (296.0 g) and the tubers occupied only a small amount of the pot volume. There was also a further, albeit not significant, increase in yield between T₁ and T₂ in 20 L pots. This suggests that, while larger pots may prevent pot binding well enough to detect significant yield differences between T_1/2 and T₁, they may not eliminate it altogether under daily irrigation.

In contrast with fresh tuber yield, canopy biomass was similarly affected by water restriction in the two pot sizes, with a significant decrease in biomass between T₁ and T_1/2 occurring in both. This finding is inconsistent with the water availability of pot binding, as are the percentage differences in biomass between T₁ and T_1/2 in the two pot sizes. Canopy biomass was more effected by water-restriction in 5 L pots (27%), compared to 20 L pots (16%) ( Figure 2 ). Increasing irrigation frequency from T₁ to T₂ had an insignificant effect on canopy biomass in both pot sizes, although it was associated with a slight increase in biomass in 5 L pots, which suggests that T₁ might be unable to maintain maximum canopy biomass accumulation in the smaller pots.

It is not clear why fresh tuber yield and canopy biomass are affected differently by water restriction in the two pot sizes. It is possible that, due to extremely limited water availability, yield was maintained at the expense of biomass under T_1/2 in the smaller pots. This seems unlikely as both fresh tuber yield and canopy biomass have previously been shown to decrease in 4.7 L pots from a similar treatment to T_1/2 (irrigation to saturation every other day) to a treatment that restricts water even further (Rolando et al., 2015).

Both canopy and tuber dry matter percentages were primarily affected by cultivar, with pot size and treatment having small effects. Maris Piper had a significantly higher dry matter concentration than Charlotte in both the canopy and tubers ( Table 2 ). Dry matter content is known to vary between potato cultivars (Navarre et al., 2009), and is related to cultivar maturation. Researchers have previously defined maturation in potato as the point of maximum dry matter accumulation (Sabba et al., 2007), which, in the absence of stress, is dependent on life cycle length. Late maturing cultivars, including Maris Piper, can delay senescence for longer than early cultivars, including Charlotte, facilitating greater radiation interception and photosynthesis over time (Aliche et al., 2019). This allows dry matter production to continue for longer in late maturing cultivars, which accounts for the differences observed here.

The canopy and tuber dry matter percentages of both cultivars were relatively unaffected by treatment ( Table 2 ), with a significant but small decrease in the former with increasing irrigation frequency and no effect in the latter. Above- and below-ground dry matter accumulation responses to water-restriction are known to vary greatly between cultivars (Hill et al., 2021). However, the differences observed between the cultivars were significantly confounded by pot size, both in the canopy and tubers. The tuber dry matter of Charlotte was identical in both pot sizes, whereas that of Maris Piper was significantly higher in the smaller pots compared to the larger pots. Above ground, this was completely reversed, as the canopy dry matter content of Maris Piper being unaffected by pot size and an association between small pots and higher dry matter concentration in Charlotte. This suggests that something other than water availability is causing the confounding effects of small pots on potato morphophysiology.

Previous research in tall but narrow 11.8 L pots (⌀ = 10 cm) has shown that both self- and reciprocally grafted potato canopies elicit greater control over dry matter accumulation than root stocks (Jefferies, 1993). This, coupled with the small and non-interactive effects of water-restriction in both pot sizes, suggests that pot binding may have a confounding effect on potato canopies that is not related to inadvertent drought stress. The cause of this is beyond the scope of this experiment, but previous research with five cowpea cultivars in 11, 17, and 76 L pots, suggested that small pots were associated with greater root abscisic acid production, and downstream reductions in canopy and root biomass, even under well-watered conditions (Ismail et al., 1994). Similar findings have also been found in tomato, where shoot growth was restricted in small pots despite “great care” (Turner, 2019) to maintain consistent water and nutrient availability between pot sizes (Hurley and Rowarth, 1999).

To provide an indication of drought stress during the experiment, average canopy temperature was measured throughout. In plants, canopy temperature is kept within the lethal limits for a particular species through transpiration (Gates, 1964). As relatively cool groundwater is taken up by the roots and moved through the plants to the leaves, it absorbs the excess thermal energy generated by solar radiation from the surrounding tissue and removes it from the plant by evaporating through the stomata (Lin et al., 2017). Even tiny amounts of transpiration can dissipate significant amounts of thermal energy and cool plant canopies by a few degrees (Gates, 1964).

Measuring potato canopy temperatures under well-watered conditions was evaluated as a method of evaluating drought tolerance between cultivars over 30 years ago (Stark et al., 1991). The method was successful in potato and other crops, as canopy temperature and water use are negatively correlated under well-watered conditions (Keener and Kircher, 1983; Chaudhuri and Kanemasu, 1985), and canopy temperature and drought susceptibility are positively correlated under water-restricted conditions (Blum et al., 1989; Stark et al., 1991).

With recent advancements in remote sensing, ground and aerial measurements of canopy temperature have been investigated as methods of estimating drought stress in potato (Rud et al., 2014). Previous research has demonstrated that canopy temperature can be integrated within a water stress index that is strongly correlated with stomatal conductance (Rud et al., 2014). This index was also shown to increase under water-restricted conditions compared to well-watered controls (Rud et al., 2014).

Across this experiment, each increase in irrigation frequency was associated with a significant decrease in canopy temperature ( Figure 5 ). The differences between the treatments were smaller than previously suggested (Gates, 1964), varying by ~1°C above or below the daily irrigation treatment (T₁). This is related to climatic conditions, as the mean ambient air temperature at 09:00, one hour before canopy temperatures were measured, was only 17.8 ± 0.5°C. Within each treatment, canopy temperature was consistently higher in the smaller pots than in the larger pots ( Figure 5 ). Again, the differences were small (< 1.5°C) due to the low potential evapotranspiration early in the photoperiod.

The difference between T₁ and T_1/2 was significantly larger in the smaller pots compared to the larger pots ( Figure 5 ). This seems contrary to the prediction of the water availability hypothesis of pot binding. If pot binding was a result of the relative inability of daily irrigation to maintain potential evapotranspiration in small pots, then canopy temperatures should be more similar between T₁ and T_1/2 in smaller pots than in larger pots. However, the high canopy temperatures under T_1/2 conditions in 5 L pots shows that this treatment produces much more severe drought stress than the same treatment in 20 L pots. Importantly, canopy temperatures decreased relative to T₁ under T₂ in both pot sizes, suggesting that neither pot size could sustain potential evapotranspiration under T₁ conditions.

The only combinations of pot size and treatment that were not significantly different from each other were T₂ in 5 L pots and T_1/2 in 20 L pots. This shows that the effects of pot binding do result from water unavailability can be mitigated to some extent by increasing irrigation frequency. However, canopy temperatures under T_1/2 conditions in 20 L pots were still significantly higher than under T₁ and T₂ conditions, which demonstrates that maintaining adequate water availability for maximum transpiration is not possible in 5 L pots with twice daily watering to saturation.

Canopy temperatures in both cultivars responded similarly to each treatment, with Maris Piper being significantly warmer under each ( Figure 5 ). This is a result of Maris Piper being a later maturing cultivar than Charlotte. Late cultivars produce larger canopies (Hill et al., 2021) and thus require greater volumes of water to maintain potential transpiration (Fandika et al., 2016). The canopy temperature of Maris Piper was also more affected by water-restriction from T₁ to T_1/2 than Charlotte in 5 L pots (+1.2°C versus +0.9°C), but similarly affected by water-restriction in 20 L pots (+0.2°C in both). This highlights the necessity of considering cultivar specific water requirements when selecting experimental pot sizes to prevent pot binding in potato.

When broken down by sample date, canopy temperature was affected by treatment more frequently in the 5 L pots ( Figure 3 , Figure 4 ). Although the differences across the whole experiment were typically significant, the effects of treatment on canopy temperature were only significant on 3 or 4 days in 20 L pots in Maris Piper and Charlotte, respectively. This contrasts with the 9 and 6 days where treatment had a significant effect on canopy temperature in 5 L pots in same cultivars, respectively. This is indicative of the extreme drought stress experienced by plants under T_1/2 conditions in 5 L pots, which have previously been used as a well-watered control condition (Li et al., 2019; Hill et al., 2023) ¹ .

As the differences in canopy temperatures between treatments were significant across the experiment, it is likely that significant differences on individual sample dates may have been more frequent with greater sample sizes. This demonstrates the potential utility of canopy temperature as a metric by which potato irrigation systems can be controlled. If slight differences between canopy temperatures in the field and a concurrent or historical well-watered population can be detected, then irrigation could be scheduled when canopy temperatures begin to rise.

SPAD meter readings are a reliable proxy for chlorophyll content (Borhan et al., 2017), and have been shown to be very strongly correlated with chlorophyll content in wheat, rice, and soybean, R² = 0.93 (Monje and Bugbee, 1992); and Arabidopsis thaliana, R² = 0.98 (Ling et al., 2011). In potato, SPAD values have been closely approximated with a computer imaging technique (Borhan et al., 2017), demonstrating the possibility of crop water- and nutrient-management with remote measures of canopy greenness.

Potato SPAD values have previously been shown to increase due to water-restriction (Ramírez et al., 2014; Rolando et al., 2015; Rudack et al., 2017; Li et al., 2019), probably due to decreasing leaf water contents increasing chlorophyll concentrations (Rolando et al., 2015; Gervais et al., 2021). However, more recent work has shown that the effects of water deficits on chlorophyll content in potato varies greatly depending on cultivar and growth stage (Mthembu et al., 2022).

For example, chlorophyll content in the Solanum tuberosum cv. Panamera increased with water-restriction during tuber initiation but decreased with water-restriction in the vegetative, tuber bulking, and maturation stages. In contrast, chlorophyll content in the cv. Bikini increased under water-restriction in every growth stage other than tuber initiation (Mthembu et al., 2022). This variability may explain why no effect of treatment was observed here, with no interactions between treatment or any other grouping factor.

Average canopy SPAD was affected by an interaction between cultivar, pot size, and sample date ( Table 3 ). Charlotte was greener than Maris Piper, demonstrating the variability in SPAD values between cultivars, regardless of treatment, previously observed (Mthembu et al., 2022). It is unclear why Charlotte in 5 L pots had significantly higher SPAD values than Charlotte in 20 L pots at the beginning of sampling. However, after 9 days the difference between pot sizes in Charlotte had disappeared, and SPAD values in both pot sizes remained similar for the duration of sampling ( Figure 6 ).

In Maris Piper, average SPAD values decreased at a faster rate in the larger pots ( Figure 6 ). This was associated with the faster rate of senescence observed with Maris Piper in the 5 L pots, an effect that has been observed before (Hill et al., 2023) ¹ . It is unlikely that early senescence in Maris Piper is a result of water unavailability in smaller pots, as senescence did not occur at a faster rate in the water-restricted plants. Instead, it is possible that the early onset of senescence was a product of nutrient unavailability, another proposed cause of pot binding (Poorter et al., 2012).

Root volume restriction in aerated liquid culture has previously been observed to reduce chlorophyll content and cause early senescence in alder (Alnus glutinosa) seedings (Tschaplinski and Blake, 1985) reduced leaf water potential due to an imbalanced root/shoot ratio (Tschaplinski and Blake, 1985). Research with starfruit (Averrhoa carambola) has also shown reduced leaf water potential and photosynthetic rate with root restriction, but this effect was compounded by water-restriction (Ismail and Noor, 1996). Root restriction also increased the rate of maturation in starfruit.

If an imbalanced root/shoot ratio is a component of pot binding, then increasing irrigation frequency to mitigate water unavailability will be limited in its capacity to alleviate pot binding in small pots. As average canopy SPAD values were unaffected by treatment in this experiment, it is possible that chlorophyll content was more affected by root restriction than water-unavailability. This would explain why Maris Piper was more affected than Charlotte here, as the former produced larger canopies in both pot sizes. However, as neither leaf water potential or root/shoot ratios were measured here, further research is needed to assess the relative effects of root- and water-restriction on leaf chlorophyll content in potato.