INTRODUCTION
The demand for environmentally friendly food production processes has increased in recent years. Greenhouse productions commonly use highly toxic agrochemicals for soil disinfection. Methyl bromide is one of the most widely used agrochemicals in horticulture production and is an agent that damages the ozone layer (Bernal, 2008). The bromine atoms released into the atmosphere react with ozone to form chlorine or bromine monoxide (Vuelta Lorenzo, 2014). It is a challenge to control crop pests and diseases without using agrochemicals.
An alternative to soil chemical treatment is solarization, which is a process of hydrothermal disinfection of the soil. To achieve high disinfection values, the soil or substrate must be moistened, covered with a transparent polyethylene sheet and exposed to solar radiation during the hottest months.
Soil is a complex ecosystem made of mineral, organic and biological compounds. Likewise, it has a diverse community of microorganisms, some of which are beneficial and other pathogens.
According to their growth temperature, the bulk of these microorganisms is mesophile (with optimum growth temperature between 30 and 40 °C). However, temperatures above 45 °C or higher during a period of time are lethal for these types of microorganisms (Arboleya et al., 2008).
For an effective solarization process, the temperature inside the solarization soil profile or substrate must reach 40 °C-55 °C for more than five hours during the day (Bettiol et al., 2014; Jiménez Rodríguez, 2019; Marín-Guirao et al., 2019; Al-Shammary et al., 2020). Solarization efficacy depends on the soil or substrate depth, moisture content and surrounding air temperature below the polyethylene sheet (D'Addabbo et al., 2010). Moisture content is crucial because it increases thermal conductivity and heat transfer affecting solarization efficiency (Al-Shammary et al., 2020).
Solarization reduces pest, pathogens and weeds pressure (Parra et al., 2015) and improves physical and chemical properties of soil and nutrient availability (Wang et al., 2016; Jiménez Rodríguez, 2019; Marín-Guirao et al., 2019 and Al-Shammary et al., 2020). Organic matter, nitrogen (NH4+, NO3-) and some macronutrients and micronutrients (K, Mg, Ca, Na) ¡ncrease after solarization, All these changes ¡mprove agricultural productivity (Simmons et al,, 2016), In addition, solarization has been documented to ¡ncrease the water holding capacity of soils (Al-Shammary et al,, 2017),
Greenhouse production was affected by Verticillium spp., Sclerotium spp., Fusarium spp,, Aspergillus spp, and Alternaría spp, Soil solarization practices could reduce their impact because they are heat-sensitive microorganisms (Katan et al,, 1989 and Marín-Guirao et al,, 2019), Solarization also eliminates bacteria or reduces its abundance and diversity. In contrast with chemical disinfection that produces a biological vacuum, solarization allows some saprophytic organisms to survive and colonize the soil avoiding a re-¡nfestat¡on with unwanted organisms (Jiménez Rodríguez, 2019), The objective of this work was to evalúate the effect of solarization on a substrate for a greenhouse experiment in Córdoba, Argentina.
MATERIALS AND METHODS
Plot location
The solarization process was conducted from December 2021 to May 2022 at the Agricultural Experimental Station (AES) INTA Manfredi (latitude 31° 51' 31,99” S, longitude 63° 44' 29,20” W) (Figure 1), Daily temperature and solar radiation were obtained from the meteorological station located at the INTA Manfredi AES.
Coverage materialsThe substrate was covered using two different polyethylene sheets, A 250 pm thick low-density polyethylene sheet was placed at the bottom to achieve correct waterproofing, preventing deep infiltration. This material (silo bag) has layers, the white outer side with additives, UV filters and titanium dioxide. The inner side is black and was placed upwards (Azcona et al,, 2009) (Figure 2-A). The top layer of the solarized structure was a section of 150 |um thickness crystal polyethylene derived from petroleum and obtained by polymerization of ethylene (Lenscak and Iglesias, 2019). Finally, it was closed by folding it underneath the first plastic to achieve a nearly airtight seal (Figure 2-B).
Figure 1: Location of the solarization plot at the AES INTA Manfredi delimited by the yellow polygon
Substrate and irrigation systemThe substrate was obtained from the mixture (50:50 v/v) of 6 m3 of black soil from horizon A (obtained from a field located near the city of Pilar) and the same volume of sand (Lanfranco et al., 2014), making a total of 12 m3. A 15 cm thickness substrate was spread over the black silo bag cover. Then a drip tape (holes spaced at 20 cm) was placed to apply an irrigation rate of 2 L/h. The irrigation system covered the entire substrate to achieve a vapor chamber that allows greater vapor diffusion in the substrate (Figure 3).
SamplingSix composite samples were taken (each composed of 30 subsamples) for the biological and chemical determinations. Three were collected before solarization (non-solarized substrate) and three after the solarization process. Samples were maintained at 4 °C during transport to the Microbiology Laboratory, Faculty of Agricultural Sciences of the National University of Córdoba (FCA-UNC, for its initials in Spanish).
Determinations
Meteorológica! parameters
Meteorological data were obtained from the meteorological station located at the AES INTA Manfredi, the sensors surveyed were air temperature and solar radiation during the months of the solarization.
Biological parameters
Substrate samples were air-dried for 24 h and sieved through a 2-mm mesh. The soil microbial groups like cellulolytic, ammonifiers and nitrifiers were estimated according to Abril (2003), using the most probable number technique (MPN) in specific liquid cultivated médiums. Counts of aerobic mesophilic bacteria, fungi and yeasts, proteolytic microorganisms, Bacillus spp., and free-living nitrogen-fixing microorganisms were determined by quantitative enumeration using the pour-plated method. Ten grams of each sample were blended and homogenized in 90 mL peptone water sterile (0.1 g/100 mL). For the mesophilic bacteria the plates were incubated for 48 h at 28-30 °C in culture médium Píate Count Agar (PCA, Britania Lab) (Merlo et al., 2011). The free-living nitrogen-fixing microorganisms were cultivated in a culture médium without free nitrogen for 5 days at 28-30 °C according to Abril et al. (2010).
Fungi and yeasts were evaluated using Chloramphenicol Glucose Agar (YGC) and were incubated for 5 to 7 days at 28-30 °C (Díaz et al., 2014). Proteolytic microorganisms were determined using a specific medium rich in peptone and incubated for 48 h at 37 °C. As for Bacillus spp., the samples were exposed to 80 °C for 12 min. Then, aliquots of 1000 pL were seeded in Petri dishes with Nutritive Agar médium and incubated at 2830 °C for 24 h (Rocha et al., 2017). All the results were expressed as colony forming units per g of substrate (CFU/g).
Figure 2: Assembly of the solarization system. A. Section of silo bag placed with its black side up. B. Upper covering of the solarized with polyethylene crystal
Figure 3: Drip tape installation in the solarization substrate
The solarization weed control was estimated. Fifteen pots of 3L capacity were filled with substrate before and after solarization. The pots were maintained for 30 days in a culture chamber at 25 °C at 70 % field capacity with a 12-hour photoperiod. Finally, the number of weeds was counted.
Chemical parameters
pH measurement
A substrate water suspension (1:2.5) was made by placing a fraction of the sample in water and shaking it vigorously for 5 min. The pH valué was determined in the supernatant with a multiparameter Phmeter Adwa AD1030 (Zagal and Sadzawka, 2007).
Eléctrica conductlvlty and total dissolved sollds
Electrical conductivity (EC) and total dissolved solids (TDS) were measured by the saturated paste extract technique using distilled water for soil saturation and a vacuum pump to obtain the extract (Zagal and Sadzawka, 2007; Clausi and Andreau, 2015 and Larrieu et al., 2016). EC and TDS were determined using a Hannah HI 98311 digital conductivity meter.
Statistical analysisData were analyzed by a one-way analysis of variance (ANAVA) followed by Fisher's LSD posteriori test (LSD; p < 0.05). The Shapiro-Wilk test was employed to determine the normality of the experimental data, and variance homogeneity assumptions were corroborated by constructing QQ-plot figures. Statistical analyses were performed using the InfoStat program (Di-Rienzo et al., 2017).
RESULTS AND DISCUSSION
During the solarization process the meteorological conditions were measured daily. The average air temperaturas ranged from 32 °C to 10 °C, while incoming solar radiation ranged from 100 W.m-2 to 410 W.m-2, with a total accumulated radiation of 50155 W.m-2 (Figure 4).
Solarization reduced the abundance of microorganisms. Solarized substrate showed the lowest values for all the parameters measured compared to the non-solarized substrate. Proteolytic (90 %), mesophiles (93 %) and fungi (100 %) were the groups that exhibited more significant reductions. The other groups like ammonifiers and nitrogen-fixing bacteria (NFB), decreased by 78 %, while yeasts and Bacillus spp., decreased by 64 and 69 %, respectively. In addition, nitrifiers decreased by 81 %, and cellulolytic by 54 %, in comparison to the non-solarized substrate (Table 1). It should be taken into consideration that the differences were statistically significant in all the functional groups analyzed. Soil solarization was found to be highly effective in reducing the population of the microbial groups analyzed in this work. Decrease in the microbial population has also been reported in several studies (Sharma and Sharma, 2002; Simmons et al., 2014 and Jiménez Rodríguez, 2019). Sharma and Sharma (2002) reported that a temperature of 40 °C under a 25 pm-thick mulch showed a lethal effect on the bacterial, fungal, and actinomycetes population under irrigated soil conditions.
This study agrees with results recorded in other greenhouse triáis, where fungi were one of the most affected groups in the solarized substrate (Jiménez Rodríguez, 2019). The author reported a reduction of oomycetes to analytical zero in a solarized substrate. Marín-Guirao et al. (2019) determined a 78 % decrease of Aspergillus spp. and 100 % of Alternaria spp. and Fusarium spp in solarization triáis. Other studies performed on solarized substrates showed a 69.57 % and 75 % decline in the abundance of Fusarium solani and Fusarium oxysporum, respectively, after 30 days of solarization (Dwivedi and Dwivedi, 2020). In addition, trials conducted on onion seedlings detected a 62 % reduction in the number of sclerotia per 100 g of the soil produced by Sclerotium cepivorum (Arbol eya and Maeso, 2018). The results obtained in the present study reveal that the bacterial groups analyzed were significantly reduced (ranging from 54 % to 100 %) when compared with non-solarized soil. Jiménez Rodríguez (2019) reports a 60 % reduction of bacterial CFU regarding the control on a substrate subjected to 72 days of solarization. After 22 days of solarization, Simmons et al. (2014) found a 66 % reduction for Rubrobacter and 100 % for Flexibacter flexilis, Aeromicrobium marinum, Flavobacterium gelidilacus and Cellvibrio japonicus species. Besides, these authors detected the increase of some species like Bacillus thermoamylovorans, a thermophilic bacterium with an optimum growth temperature of 50 °C. Other authors conducted triáis in a greenhouse with tomatoes in Italy and evaluated the effects of Pseudomonas fluorescens as a phytopathogen, reporting a 90 % decrease in disease incidence after solarization
Figure 4: Meteorological data obtained from the station located at the AES INTA Manfredi during the months of the trial. Radiation: W.m-2. Average temperature: °C
Table 1: Biological parameters of the substrate before and after the solarization prooess
In the solarization process, direct and indirect mechanisms explain the decrease in the number of microorganisms. Within the direct ones, we can name death by high temperatures or inactivation by sublethal temperatures. While the reduction by indirect mechanisms is due to the subsequent colonization of the solarized substrate by antagonistic microorganisms such as thermophiles or thermotolerant ones, including Bacillus spp, Pasteuria penetrans and Trichoderma harzianum (McGovern and McSorley, 2018).
The solarization process had a significant reduction in the weed substrate pressure. The number of weeds was reduced by 99 % regarding the non-solarized substrate. The weed count before solarization showed an equivalent average valué of 394 weeds.m-2. At the end of the solarization process, only one dicotyledonous weed seedling was observed in one of the pots. A research study carried out in Santiago del Estero (Argentina) reported a 90 % reduction of weeds in four substrates subjected to solarization for 50 days (Parra et al., 2015). In addition, in other research in southern Uruguay, weed reduction/m2 was 98-99 % in solarized treatments (Arboleya et al., 2018). Gilí et al., (2017) also report reductions of 98 % of weeds after solarization in India. These findings agree with our work which points at a 99 % weed reduction.
The pH showed a decrease of 1.9 % for the solarized treatment. EC increases 5.91 % with respect to the solarized substrate. The TDS parameter was a 169 % higher in the solarized substrate compared to the non-solarized (Table 2). It has been reported, that the increase of soil temperature during solarization generates an increase in the content of soluble nutrients, dissolved organic matter, inorganic nitrogen forms (NH4+, NO3-), and some cations (K, Mg, Ca, Na), correlated with the values measured in this work (Chen and Jatan, 1982; Ghini, 1997; Chellemi and Mirusso, 2006; D'Addabbo et al., 2010; Simmons et al., 2016).
Table 2: Chemical parameters of the substrate before and after the solarization process
The relative reduction (81 %) of nitrifying microorganisms promotes the accumulation of soluble ammoniacal nitrogen (D'Addabbo et al., 2010). All these changes explain the changes in pH and TDS, and also ¡nfluence the variation of electrical conductivity, which is related to the release of high amounts of ions due to the decomposition and mineralization of organic matter (Gilí et al., 2017).
CONCLUSIONS
The implementation of solarization in greenhouse production is possible and necessary. Solarization reduced the abundance of fungal and bacterial species ¡n the substrates, it also made ¡t possible to reduce weed pressure. This research showed the ¡mportance of using this technique to disinfect the substrate before planting, thus reducing the use of chemical inputs.
Fecha de recepción: 21/02/2023
fecha de aceptación: 06/05/2023