1. Introduction
Cyperus esculentus L. (yellow nutsedge) is a perennial weed which is very prolific and hard to control in many crops. It is reported as the sixteenth worst weed in the world [
1] and can lead to huge losses in arable crops (e.g., 60% in sugar beets [
Beta vulgaris L.] and 40% in potatoes [
Solanum tuberosum L.]) [
2]. In leek [
Allium porrum L.], onions [
Allium cepa L.], and Brussels sprouts [
Brassica oleracea var.
gemmifera (de Candolle) Zenker], high infestation levels (80–100% of the field covered with
C. esculentus) may cause losses of 86, 90, and 93%, respectively [
3]. Reproduction occurs mainly via axillary buds on tubers and basal bulbs, both of which are formed underground at the tips of rhizomes [
4]. In a temperate climate, one mother tuber is able to generate 700 or more daughter tubers during one growing season [
5]. Moreover, shoot formation (shoots arise from basal bulbs) is very intensive. De Cauwer et al. [
6] planted mother tubers of genetically different clones in a 10 L pot (1 mother tuber per pot). At the end of the growing season, 29 to 91 shoots (depending on the clone) were counted. In Western European conditions, mother tubers start to germinate during April and initiate a process of intensive shoot formation. Formation of daughter tubers starts in May or June and continues until autumn. Tubers can survive low temperatures (up to −10 °C on soil surface) [
5] and the most persistent may remain germinative for 10 years [
7].
C. esculentus also produces seeds, but these rarely germinate in the field [
8,
9].
In Belgium, over 50,000 hectares of cropland is infected with
C. esculentus (Feys, pers. comm.). Successful control of
C. esculentus tuber banks in cropped areas requires years of intensive control. As a consequence of the insufficient efficacy of single control measures against
C. esculentus, integrated weed management systems combining mechanical, chemical, and cultural control measures are required [
5,
10,
11]. However, current
C. esculentus control strategies in conventional agriculture are still very much herbicide-based despite the European Commission’s plans to halve the risk (to human health and the environment) and overall use of chemical pesticides by 2030 as stated in the EU Green Deal framework launched in 2020. One way to decrease the overreliance on herbicides is to implement alternative curative strategies. Up to now, mostly soil-disturbing mechanical methods have been implemented but these techniques require multiple passes to exhaust carbon resources stored in the mother tubers [
12] and also entrain a high risk of tuber dispersal [
13]. One promising alternative to chemical or mechanical weed management is management via electricity. The use of electric energy to control weeds was first mentioned at the end of the 19
th century [
14] and has recently gained a lot of interest from machine developers. After direct contact between aerial plant parts and a high-voltage electrode, a current flow is established that is directed via aerial parts into belowground plant parts. As a result of the electric resistance of the plant, electric energy is converted to heat [
14]. This heat causes damage to cell membranes, which leads to an accelerated loss of plant moisture [
15]. So far, electrocution has hardly been practiced by farmers despite (1) the commercial availability of different types of electric weeding devices, (2) the lack of soil disturbance, and (3) its applicability in zones where herbicide use and soil tillage are legally not allowed [
16].
A possible reason for the lack of implementation aside from energy input, hazard concerns, and the high equipment cost [
17], might be the lack of academic literature on the use, efficacy, and efficacy-influencing factors of high energy electricity for controlling weeds and
C. esculentus in particular.
Diprose et al. [
18] and Sahin [
19] concluded that small electric currents (50–100 V, 1-2 µA) might increase plant growth, while very large currents (5000–15,000 V) result in fast weed destruction. Moreover, the longer the electrocution time (duration of the contact between plant and electrode), the higher the electrocution effectiveness. According to Sahin and Yalınkılıc [
20], the electric resistance of the plant, which is positively correlated with the plant growth stage, is an important parameter to take into account.
Schreier et al. [
21] performed some field experiments in soybean (
Glycine max (L.) Merr.) and concluded that electrocution could be part of an integrated weed management system, because it can eliminate late-season herbicide-resistant weeds. Moreover, they concluded that the effectiveness of electrocution (evaluated by visual control ratings 3 or 42 days after treatment) on some annual weed species
(Amaranthus tuberculatus (Moq.) Sauer [waterhemp],
Xanthium strumarium L. [cocklebur],
Ambrosia trifida L. and
Ambrosia artemisiifolia L. [giant and common ragweed],
Conyza canadensis (L.) Cronquist [horseweed],
Setaria faberi Herm. and
Setaria pumila (Poir.) [giant and yellow foxtail], and
Echinochloa crus-galli (L.) P. Beauv. [barnyardgrass]) is most strongly correlated to plant height and plant moisture content at the time of electrocution. The Pearson correlation coefficient between weed control (42 days after treatment) and plant height or plant moisture content was, respectively, −0.54 and −0.26. Two electrocution passes led to a better control compared to one pass. This last result is confirmed in earlier research by Diprose et al. [
22] on the control of sugar beet (
Beta vulgaris L.) bolters. According to the French Wine Institute [
23], electrocution speed, which determines the contact time between electrode and plant leaves, had a significant effect on the effectiveness of electrocution for all weed species (mainly grasses) included in its study. Efficacy significantly improved by reducing speed from 3.5 km·h
−1 to 2.5 km·h
−1. According to Vigneault and Benoît [
14], soil moisture content negatively affects the effectiveness of the electrocution technique. In dry soils, more current flows through the belowground plant parts (and not through the soil volume), which leads to an increased damage to the plant root system.
To our knowledge, there are no scientific reports on the effects of a single treatment on vitality of belowground C. esculentus plant parts capable of vegetative reproduction (basal bulbs and mother tubers) and on efficacy-influencing (a)biotic factors. Optimization of the efficacy of a single treatment is a prerequisite to keeping the number of passes required to exhaust C. esculentus as low as possible.
In our study, we evaluated the effect of a single electrocution treatment on C. esculentus shoot and mother tuber vitality. The following hypotheses were formulated: (H1) Electrocution effectively controls both primary C. esculentus shoots and corresponding mother tubers, irrespective of tuber burial depth and clone, (H2) Efficacy of electrocution is better when applied on dry soils and on small targets, and (H3) Efficacy of electrocution is enhanced by increasing the electrical dose by decreasing application speed or by increasing voltage. To address these hypotheses, the following research questions were formulated: (i) What is the impact of electrocution on the vitality of primary shoots and their corresponding mother tubers? (ii) Do growing location and the biotic factors of clone, plant growth stage, and vertical tuber position affect electrocution efficacy? (iii) What is the effect of application speed (exposure duration) and voltage on electrocution efficacy? Hereto, aboveground shoots from artificially buried mother tubers were treated with electricity delivered from two commercially available electric weeding devices applying alternating current via a handheld applicator (Rootwave) or applying phased direct current via a tractor-mounted applicator (Zasso XP300).
4. Discussion
Hypothesis 1 was partly supported. In both the Zasso and the Rootwave experiments, a single electrocution treatment did not affect the vitality of the mother tubers. In the Zasso experiment, tuber vitalities obtained for electrocuted plants (84.0 to 100.0%) were comparable to the ones obtained for untreated control plants (88.3 to 100.0%). Additionally, in the Rootwave experiment, tuber vitalities obtained for plants electrocuted at a voltage of 3000 to 5000 V (72.9 to 93.2%) were comparable to the ones obtained for untreated control plants (77.2 to 100.0%). Seemingly, the electric current was not able to lethally harm mother tubers even when planted at a superficial depth of 5 cm. Most likely the vertical rhizome connecting the mother tuber with the basal bulb of the primary shoot constitutes a poor conductor of electricity in comparison with the conductivity of the surrounding soil substrate as a result of its thinness (1–2 mm), low water content (<50%), and fibrousness. Indeed, the inner cortical cells of rhizomes are often thick-walled and lignified [
28]. In both the Zasso and the Rootwave experiment, both shoot and mother tuber vitality of treated plants was not affected by clone. Hence, the two genetically different
C. esculentus clones showed similar sensitivity to electricity, irrespective of the weeding device.
Hypothesis 2 was also partly supported. Mother tuber vitality of electrocuted plants was high (72.9 to 100%), irrespective of location, plant growth stage, and electric weeding device, and did not differ significantly from the mother tuber vitality of the untreated control plants (77.2 to 100%). On the other hand, shoot vitality of electrocuted plants differed among the plant growth stage and the location.
In the Zasso experiment, electrocution efficacy clearly depended on the plant type. At Bree, effects of plant type on efficacy of electrocution were more pronounced at lower application speeds (1.1, 1.5, and 2.2 km·h
−1) than at the highest speed (3.0 km·h
−1), at which no significant differences in shoot vitality were observed among plant types. At a speed of 1.1 km·h
−1, shoot vitality was significantly higher within plant type 4 compared to plant type 1 (difference of 36.3%). Additionally, shoot vitality was significantly higher within plant type 4 compared to plant type 2 if a speed of 1.5 km·h
−1 was applied (difference of 20.5%). At a speed of 2.2 km·h
−1, differences were even more apparent. Shoot vitality was significantly higher within plant type 4 compared to plants type 1 and 2 (difference of, respectively 20.5% and 23.4%). Moreover, shoot vitality was significantly higher within plant type 3 compared to plant type 2 (difference of 17.6%). Similar but smaller effects of plant type were observed at Bocholt. Differential sensitivity of plant types to electricity reflects differential leaf number of treated plant types. At time of electrocution, plants belonging to plant types 1 and 2 had on average 0.7 leaves more than plants belonging to plant type 3 and 4. Additionally, in the experiment of Schreier et al. [
21], there was a trend towards greater weed control when electrocution was performed on larger weed targets.
In the Zasso experiment, shoot vitality of treated plants was lower at Bree (a relatively wet soil) than at Bocholt (a relatively dry soil). The shoot vitality of treated plants varied from 3.4 to 42.4% at Bree, and from 10.2 to 73.1% at Bocholt. This contradicts the expectation that the control efficacy of electrocution is higher when soil moisture content is low [
14]. Under dry soil conditions, more current flows through the plant and not through the soil as a result of the high electrical resistivity of the soil that non-linearly increases with decreasing soil moisture content [
29,
30]. However, apart from soil electrical conductivity, conductivity or resistivity of the plant itself is also an efficacy-determining factor. Indeed, Nadler et al. [
31] performed some experiments with trees (mango [
Mangifera indica L.], banana [
Musa spp.], date [
Phoenix dactylifera L.], and olive [
Olea europaea L.]) and observed a positive correlation between stem water content and stem electrical conductivity. The differential efficacy of electrocution between locations may possibly be explained by a differential electrical conductivity of the plants. In contrast with plants growing on the wetter and heavier soil of Bree, plants growing on the drought-sensitive, light-textured soil of Bocholt most likely experienced (more) heat and water stress resulting in a thicker cuticle and/or lower plant moisture content hampering the entry or transport of the electric current into the plant. Indeed, during the experimental period (12 May–10 June), weather conditions were relatively dry (20–30 mm less rain compared to average years). Moreover, the first ten days of June were very warm for Belgian standards (around 4 °C warmer compared to average years). The higher electric resistivity of the plants at Bocholt might also be explained by the time of electrocution. The electrocution treatments at Bree and Bocholt took place from 9 AM till 11 AM, and from 11 AM till 1 PM, respectively. As a result, the treatment at Bocholt took place at warmer and drier conditions (difference of 2.3 °C and 6.5% relative humidity).
Contrary to the Zasso experiment, no significant differences in shoot vitality between locations were observed in the Rootwave experiment, despite the slightly lower shoot vitalities at Bree. Shoot vitality of treated plants varied from 7.1 to 33.3% at Bocholt, and from 0 to 13.4% at Bree. The differential significance of the location factor between both experiments could be explained by differential weather conditions and soil water status around the time of electrocution and their impact on the plant’s sensitivity to electricity. In the Rootwave experiment, C. esculentus shoots growing at Bree and Bocholt did not encounter any heat or water stress. On both locations, the experimental period (25 June–16 July 16 2022) was characterized by very wet weather (±150 mm of rainfall) and average daily maximum temperatures (around 23 °C). Moreover, soil water content (soil layer 0–20 cm) around the time of electrocution was high with only small differences between locations (18.9 and 14.6% for Bree and Bocholt, respectively). Hence, heat and water stress levels were very low and similar at both locations, which most probably led to a similar electric resistivity of the plants at both locations. This was clearly not the case in the Zasso experiment, where a difference of electric resistivity between locations was very likely.
Hypothesis 3 was partly supported. In the Zasso experiment at Bree, shoot vitality of electrocuted plants varied from 3.4 to 42.4%, but no significant differences were observed between applied speeds. This is contradictory with the results of the French Wine Institute [
23], where weeds (mainly grasses) were better controlled when applying a speed of 2.5 km·h
−1 compared to 3.5 km·h
−1. However, at Bocholt, plants belonging to plant types 2 or 3 were significantly better controlled when treated at 1.1 or 1.5 km·h
−1 (shoot vitality from 10.2 to 34.0%) than at 2.2 or 3.0 km·h
−1 (shoot vitality from 53.9 to 73.1%). Within plant types 1 and 4, differences were still present but smaller and not significant. A possible explanation for the differential effect of speed between locations could be that the control levels obtained at Bocholt were much lower (Bocholt: shoot vitality from 10.2 to 73.1%, Bree: shoot vitality from 3.4 to 42.4%). As a result, the potential effect of the factor speed became more apparent at Bocholt.
The effect of voltage on electrocution efficacy was evaluated in the Rootwave experiment. The applied voltage clearly had no effect on both mother tuber and shoot vitality. After electrocution, mother tuber vitality varied from 72.9 to 93.2%, irrespective of the applied voltage. This result is not surprising because it was already clear that electrocution is not able to lethally heat mother tubers, presumably as a result of the low electric conductivity of the vertical rhizome connecting the basal bulb with the mother tuber. Shoot vitality of treated plants varied from 0 to 31.6%, irrespective of the voltage. An applied voltage of 3000 V already led to relatively low shoot vitalities; increasing the voltage with 1000 or 2000 units had no effect. Increasing voltage may further reduce shoot vitality as a higher voltage leads to an increased amount of transferred energy [
14], but on the other hand it may increase shoot vitality when the amount of energy may become so high that it may cause leaf tissue breakage, thus hampering energy transport to the basal bulb.
To conclude, electrocution had no effect on mother tuber vitality but exhibited a strong effect on the vitality of exposed shoots, regardless of the type of electric current. This implies that several electrocution passes are required to exhaust energy reserves of the mother tuber by killing successive flushes of newly initiated or regrowing shoots. According to Matthiesen [
32], a mother tuber is able to resprout up to six times depending on tuber size and clone. The first, second, and third resprouting consumes about 60, 10, and 10% of energy reserves of the mother tuber, respectively [
33].
In absence of a crop, electrocution should preferably be repeated on regrowing shoots which have around five leaves, as the electrocution efficacy was highest at this growth stage. Applying electricity at this particular stage also implies maximum depletion of energy reserves stored in belowground tissues. Indeed, at the five-leaf stage the plant has reached its compensation point (i.e., the minimum level of belowground reserves) as indicated by Schröder et al. [
34]. In naturally infested fields, primary shoots do not emerge simultaneously as tubers may exhibit differential degrees of tuber dormancy or emerge from differential depths. Generally, 80 to 85% of the tubers are located in the upper 15 cm soil layer, and more than 95% are located in the upper 45 cm soil layer [
35,
36]. Possibly, tuber dormancy may be released by an electric current flowing in the soil matrix in accordance with the findings of Kocaçcalişkan et al. [
37] showing that dormant seed tubers of potato (
Solanum tuberosum L.) resprouted after treatments with a low voltage current of 50 and 100 V. Hence, successful
C. esculentus control with electricity requires season-long repetitive electrocution passes targeting shoots from newly sprouting tubers or resprouting tubers. Repeated passes at the two–five-leaf stage have also been advised for mechanical methods [
38]. However, in contrast with mechanical methods based on tillage, electrocution does not disturb the soil, thus avoiding tuber dispersal across the whole field [
10], nor does it stimulate soil mineralization. Löbmann et al. [
39] found no evidence that electrocution treatments might negatively impact soil organisms. In contrast with chemical
C. esculentus control, electrocution leaves no potentially harmful chemicals in food or the environment, and its control efficacy is not affected by clone origin. Herbicide efficacy indeed widely varies across
C. esculentus clones as shown by De Cauwer et al. [
6]. However, there are still some challenges. Intensive weed control with electrocution requires season-long black fallow, which may increase the risk of soil erosion [
40]. Moreover, the technique is still quite expensive and requires stringent safety procedures.