Mulching materials and wetted soil percentages on zucchini cultivation

Silva, Gustavo Henrique da; Cunha, Fernando França da; Morais, Caio Vieira de; Freitas, Agnaldo Roberto de Jesus; Silva, Derly José Henriques da; Souza, Caetano Marciano de

doi:10.1590/1413-7054202044006720

ABSTRACT

Polyethylene mulch can cause serious problems in the environment. A promising alternative to polyethylene mulch is biodegradable mulch. Therefore, a two-year experiment was carried out with zucchini (Cucurbita pepo L.) during the cropping seasons of 2017 and 2018 in Southeast Brazil to investigate the effects of four soil mulching treatments (white polyethylene mulch: WP, black polyethylene mulch: BP, biodegradable mulch of brown recycled paper: RP and nonmulched: NM) and two wetted soil percentages (50 and 70% of the soil surface) using a randomized block design with five repetitions. The average water consumption of the zucchini was 157 mm in the WP treatment, 155 mm in the BP treatment, 155 mm in the WP treatment and 215 mm in the NM treatment. The yield was higher in the WP (78.1 ton ha^-1) and BP (69.1 ton ha^-1) treatments than in the RP (66.6 ton ha^-1) or NM (52.4 ton ha^-1) treatments. The daily thermal amplitude was lowest in the RP treatment (3.6-6.0 °C) and highest in the BP treatment (7.3-9.0 °C). The lower wetted soil percentage (50%) reduced water consumption (by 5-7%) and improved water-use efficiency (by 11%). Weeds, including Cyperus roduntus, were more efficiently controlled in the RP treatment than in the WP and BP treatments. In general, compared to the nonmulched treatment, mulches were effective in reducing weed infestation (95%), increasing yield (36%) and improving water-use efficiency (94%). RP, as an alternative to polyethylene mulch, can save water and control weeds in zucchini crops. These results represent useful information that extends the mulching options for technicians and farmers.

Index terms:
Biodegradability; Cucurbita pepo; drip irrigation; water saving.

RESUMO

Mulch de polietileno pode causar sérios problemas ao meio ambiente. Uma alternativa promissora para a mulch de polietileno é o mulch biodegradável. Por isso, um experimento de dois anos foi realizado com abobrinha (Cucurbita pepo L.) durante as safras de 2017 e 2018 no Sudeste do Brasil para avaliar os efeitos de quatro tratamentos de cobertura do solo (mulch de polietileno branco: WP, mulch de polietileno preto: BP, mulch biodegradável de papel reciclado (cor marrom): RP e sem-mulch: NM) e duas porcentagens de área molhada (50 e 70% da superfície do solo molhada) usando o delineamento de blocos ao acaso com cinco repetições. O consumo de água médio das safras de abobrinha foram 157 mm em WP, 155 mm em BP, 155 mm em WP e 215 mm in NM. A produtividade foi maior em WP (78,1 ton ha^-1) e BP (69,1 ton ha^-1) de que em RP (66,6 ton ha^-1) e NM (52,4 ton ha^-1). A amplitude da temperatura do solo média foi menor in RP (3,6-6,0 ºC) e maior em BP (7,3-9,0 ºC). A porcentagem de área molhada menor, 50%, reduziu o consumo de água (5-7%) e melhorou a eficiência do uso da água (11%). As plantas daninhas, incluindo Cyperus Roduntus, foram controladas de forma eficiente em RP comparado com WP e BP. Em geral, os mulches foram eficientes para reduzir a infestação de ervas daninhas (95%), aumentar o rendimento (36%) e melhorar a eficiência do uso da água (94%) em comparação com sem-mulch. RP é uma alternativa ao mulch de polietileno visando economia de água e controle de plantas daninhas em abobrinha. Em geral, esses resultados representam informações úteis que ampliam as opções para técnicos e agricultores.

Termos para indexação:
Biodegradabilidade; Cucurbita pepo; irrigação por gotejamento; economia de água

INTRODUCTION

Zucchini (Cucurbita pepo L.) is an important horticultural crop globally. In Brazil, 135,752 tons of zucchini fruit, equivalent to US $55.54 million, was produced in 2019 (Prohort, 2019PROHORT. Programa Brasileiro de Modernização do Mercado Hortigranjeiro - PROHORT. 2019. Available in: <Available in: http://dw.ceasa.gov.br/ >. Access in: September, 16, 2019.
http://dw.ceasa.gov.br/... ). Zucchini crops are sensitive to water deficits (Contreras et al., 2017CONTRERAS, J. I. et al. Irrigation management of greenhouse zucchini with different soil matric potential level. Agronomic and environmental effects. Agricultural Water Management , 183:26-34, 2017.) and weeds (Coleman et al., 2015COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.). Because of this, polyethylene mulch is frequently used in zucchini cultivation. Plastic film mulching can control weeds (Coleman et al., 2015), COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.conserve soil moisture and save water by reducing soil evaporation (Liu et al., 2013LIU, M. X. et al. Numerical simulation of soil water dynamics in a drip irrigated cotton field under plastic mulch. Pedosphere, 23(5):620-635, 2013.), modify soil temperature (Ribas et al., 2015RIBAS, G. G. et al. Temperatura do solo afetada pela irrigação e por diferentes coberturas. Engenharia Agrícola, 35(5):817-828, 2015.), increase irrigation and fertilization efficiency (Biswas et al., 2015BISWAS, S. K. et al. Effect of drip irrigation and mulching on yield, water-use efficiency and economics of tomato. Plant, Soil and Environment, 61(3):97-102, 2015.; Yang et al., 2015YANG, N. et al. Plastic film mulching for water-efficient agricultural applications and degradable films materials development research. Materials and Manufacturing Processes, 30(2):143-154, 2015.), reduce viruses in fruits (Brust, 2000BRUST, G. E. Reflective and black mulch increase yield in pumpkins under virus disease pressure. Journal of Economic Entomology, 93(3):828-833, 2000.; Olinik et al., 2011OLINIK, J. et al. Produtividade de híbridos de abobrinha italiana cultivados sob diferentes coberturas de solo. Horticultura Brasileira, 29(1):130-134, 2011.), accelerate leaf area growth (Fan et al., 2017FAN, Y. et al. Plastic mulch decreases available energy and evapotranspiration and improves yield and water use efficiency in an irrigated maize cropland. Agricultural Water Management , 179:122-131, 2017.; Qin et al., 2016QIN, S. et al. Can the drip irrigation under film mulch reduce crop evapotranspiration and save water under the sufficient irrigation condition? Agricultural Water Management , 177:128-137, 2016.) and increase yield (El-Samnoudi et al., 2019EL-SAMNOUDI, I. M. et al. Combined effect of poultry manure and soil mulching on soil properties, physiological responses, yields and water-use efficiencies of sorghum plants under water stress. Communications in Soil Science and Plant Analysis, 50(20):2626-2639, 2019.; Hou et al., 2019HOU, F. et al. Mulching with plastic film improved the root quality of summer-sown sweet potato (Ipomoea batatas (L). Lam.) in northern China. Journal of Integrative Agriculture, 18(5):982-991, 2019.).

Polyethylene, a plastic film traditionally used as mulch, is not properly removed from soil (Liu; He; Yan, 2014LIU, E. K.; HE, W. Q.; YAN, C. R. ‘White revolution’ to ‘white pollution’ - Agricultural plastic film mulch in China. Environmental Research Letters, 9:99-101, 2014.), not efficiently recycled and is often stockpiled on-farm, burned, or deposited in landfills (Ahokas et al., 2014AHOKAS, J. et al. Paper based mulches as an alternative to polyethylene mulch in vegetable production. Makinaları Bilimi Dergisi, 10(1):73-78, 2014.). Additionally, its residues in soil can affect seed germination, root growth, and soil moisture homogeneity (Liu; He; Yan, 2014LIU, E. K.; HE, W. Q.; YAN, C. R. ‘White revolution’ to ‘white pollution’ - Agricultural plastic film mulch in China. Environmental Research Letters, 9:99-101, 2014.) and lead to the formation of environmentally harmful chemical products, such as phthalate esters, di-(2-ethylhexyl) phthalate, aldehydes and ketones (Chen et al., 2013CHEN, Y. et al. Empirical estimation of pollution load and contamination levels of phthalate esters in agricultural soils from plastic film mulching in China. Environmental Earth Sciences, 70(1):239-247, 2013.). Therefore, biodegradable mulches are suitable alternatives for replacing polyethylene. Biodegradable mulches include paper (cellulosic fiber), polylactic acid, polyester and corn, sugar cane, or potato starch (Gross; Kalra, 2002GROSS, R. A.; KALRA, B. Biodegradable polymers for the environment. Science, 297:803-807, 2002.). Additionally, biodegradable mulches can be broken down by photodegradation or biodegradation (Kasirajan; Ngouajio, 2012KASIRAJAN, S.; NGOUAJIO, M. Polyethylene and biodegradable mulches for agricultural applications: A review. Agronomy for Sustainable Development , 32(2):501-529, 2012.), thus reducing the cost of removal and disposal. Reports indicate that yield and weed control are comparable to those obtained with polyethylene mulch in many crops (Brault; Stewart; Jenni, 2002BRAULT, D.; STEWART, K. A.; JENNI, S. Growth, development, and yield of head lettuce cultivated on paper and polyethylene Mulch. HortScience, 37(1):92-94, 2002.; Cirujeda et al., 2012CIRUJEDA, A. et al. Biodegradable mulch instead of polyethylene for weed control of processing tomato production. Agronomy for Sustainable Development, 32(4):889-897, 2012.; Miles et al., 2012MILES, C. et al. Deterioration of potentially biodegradable alternatives to black plastic mulch in three tomato production regions. Hort Science, 47(9):1270-1277, 2012.; Saraiva et al., 2012SARAIVA, A. et al. The use of biodegradable mulch films in muskmelon crop production. Journal of Agricultural Science and Review, 1(4):88-95, 2012.; Wortman; Kadoma; Crandall, 2016WORTMAN, S. E.; KADOMA, I.; CRANDALL, M. D. Biodegradable plastic and fabric mulch performance in field and high tunnel cucumber production. HortTechnology, 26(2):148-155, 2016.). However, to be suitable, biodegradable mulches need to be efficient in conserving soil moisture and controlling weeds, mainly in tropical climates.

The use of mulch in association with drip irrigation has been shown to be suitable for the worldwide production of zucchini in both open-field and protected cultivation (Carpes et al., 2008CARPES, R. H. et al. Ausência de frutos colhidos e suas interferências na variabilidade da fitomassa de frutos de abobrinha italiana cultivada em diferentes sistemas de irrigação. Ceres, 55(6):590-595, 2008. ; Coleman et al., 2015COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.), potato (Zhang et al., 2017ZHANG, Y. L. et al. Influence of different plastic film mulches and wetted soil percentages on potato grown under drip irrigation. Agricultural Water Management , 180:160-171, 2017.) and tomato (Biswas et al., 2015BISWAS, S. K. et al. Effect of drip irrigation and mulching on yield, water-use efficiency and economics of tomato. Plant, Soil and Environment, 61(3):97-102, 2015.). In drip irrigation, a small volume of water is constantly delivered in the root zone, increasing irrigation and fertigation efficiency (Vicente et al., 2017VICENTE, M. R. et al. Spacial distribution of fertigated coffee root system. Ciência e Agrotecnologia, 41(1):72-80, 2017.). Mulch types and characteristics of drip irrigation systems can influence the soil water distribution, mainly in the top 0-20 cm soil layer (Chen et al., 2013CHEN, Y. et al. Empirical estimation of pollution load and contamination levels of phthalate esters in agricultural soils from plastic film mulching in China. Environmental Earth Sciences, 70(1):239-247, 2013.), which has the highest concentrations of zucchini roots (Al-Omran et al., 2005AL-OMRAN, A. M. et al. Effect of drip irrigation on squash (Cucurbita pepo) yield and water-use efficiency in sandy calcareous soils amended with clay deposits. Agricultural Water Management, 73(1):43-55, 2005.; Contreras et al., 2017CONTRERAS, J. I. et al. Irrigation management of greenhouse zucchini with different soil matric potential level. Agronomic and environmental effects. Agricultural Water Management , 183:26-34, 2017.). Spatiotemporal changes in soil water content can affect evapotranspiration (Zhang et al., 2017ZHANG, Y. L. et al. Influence of different plastic film mulches and wetted soil percentages on potato grown under drip irrigation. Agricultural Water Management , 180:160-171, 2017.). Therefore, the impact of different mulch types and drip irrigation on zucchini water consumption, water saving and yield must be studied.

An essential parameter in drip irrigation system design is wetted soil percentage, which is the area wetted as a percent of the total irrigated area (Keller; Karmeli, 1974KELLER, J.; KARMELI, D. Trickle irrigation design parameters. Transactions of the ASAE, 17(4):678-684, 1974.). Wetted soil percentages that are too low may cause poor root growth and distribution, resulting in water stress, while wetted soil percentages that are too high may cause poor soil aeration, deep drainage, and high soil evaporation, resulting in low water- and fertilizer-use efficiency and groundwater contamination. Changes in wetted soil percentages require different irrigation frequencies, impacting the soil water regime, which can influence root distribution, solute transport, water uptake by roots and yield (Al-Omran et al., 2005AL-OMRAN, A. M. et al. Effect of drip irrigation on squash (Cucurbita pepo) yield and water-use efficiency in sandy calcareous soils amended with clay deposits. Agricultural Water Management, 73(1):43-55, 2005.; Feddes et al.,1976FEDDES, R. A. et al. Simulation of field water uptake by plants using a soil water dependent root extraction function. Journal of Hydrology, 31(1):13-26, 1976.; Grecco et al., 2019GRECCO, K. L. et al. HYDRUS-2D simulations of water and potassium movement in drip irrigated tropical soil container cultivated with sugarcane. Agricultural Water Management , 221:334-347, 2019.; Kuslu et al., 2014KUSLU, Y. et al. Fruit yield and quality, and irrigation water use efficiency of summer squash drip-irrigated with different irrigation quantities in a semi-arid agricultural area. Journal of Integrative Agriculture , 13(11):2518-2526, 2014.). Determining a suitable wetted soil percentage could increase yield while conserving water.

Therefore, field experiments during two consecutive cropping seasons in Southeast Brazil were carried out to investigate the effect of different soil mulching materials and wetted soil percentages on water consumption, net photosynthesis, leaf area index, fruit yield and water-use efficiency in zucchini and the ability of the mulches to control weeds.

MATERIAL AND METHODS

Zucchini (Cucurbita pepo L.) was cultivated in a field experiment at the experimental field of the Department of Plant Science (20°45’S, 42°52’W, 650 m a.s.l.), Viçosa, Minas Gerais, Southeast Brazil, in two consecutive cycles in 2017 and 2018. The municipality of Viçosa, belonging to the Zona da Mata mesoregion in Minas Gerais, has an average annual temperature of 21.8 °C, annual precipitation of 1361 mm and Cwa climate (according to Köppen’s classification), which is characterized by humid, subtropical conditions, with dry and cold winters and hot and rainy summers (Alvares et al., 2013ALVARES, C. A. et al. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22(6):711-728, 2013.).

The experimental area was 432 m². The groundwater remained at a depth of ∼20 m. The local soil was an Argissolo Vermelho (Ultisol), with 390 g kg^-1 sand, 200 g kg^-1 silt, and 410 g kg^-1 clay (clay texture). The soil physical-hydraulic and chemical properties at the surface (0-20 cm depth) are described in Table 1. These characteristics were determined before the implementation of the experiments. The composite sample used for all the soil analyses was made of a mixture of several samples from the experimental area (Teixeira et al., 2017TEIXEIRA, P. C. et al. Manual de Métodos de Análise de Solo. Brasília: Embrapa, 2017. 574p.).

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Table 1:
Some selected soil chemical and physical-hydraulic properties.

Two different wetted soil percentages (WSPs; 50 and 70%), the ratio between actual wetted soil volume and total soil volume within a specified soil layer (Schwartzman; Zur, 1986SCHWARTZMAN, M.; ZUR, B. Emitter spacing and geometry of wetted soil volume. Journal of Irrigation and Drainage Engineering, 112(3):242-253, 1986.), were evaluated using drip irrigation. Four different soil mulching treatments were studied with the two wetted soil percentages: white and black polyethylene mulches (Electro Plastic, São Paulo, BRA), biodegradable mulch of recycled paper (Ponte Nova Papéis, Ponte Nova, BRA) and a nonmulched control. For the mulched treatments, approximately 70% of the soil surface was covered with mulch, and the edges were buried. Both polyethylene mulches were 22 µm thick, and the biodegradable mulch was 187 µm thick. A completely randomized block design with six replications was adopted.

Each plot (3.0 m x 3.0 m) contained 3 rows, 1.0 m apart. Zucchini seeds (cv. PX 7051, Seminis, São Paulo, BRA) were hand-sown every 50 cm at a depth of 3 cm. For the mulched treatments, holes with a 7 cm diameter were punched through the film to sow the seeds.

Disk plows, disk harrows and rotary hoes were used for tilling operations 15 days before sowing in both experiments. In the 2017 cropping season (winter/spring), the zucchini seeds were sown in the field on August 19, and harvest was carried out for 26 days, from October 05 to October 31. After sowing, 90 kg ha^-1 N, 100 kg ha^-1 P₂O₅, 100 kg ha^-1 K₂O, 10 kg ha^-1 Ca, 70 kg ha^-1 Mg and 20 kg ha^-1 S were applied through the drip irrigation system (fertigation) on five dates (20% on September 01, 30% on September 15, 30% on September 30, and 20% on October 15).

In the 2018 cropping season (summer/autumn), the zucchini seeds were sown in the field on February 02, and harvest was carried out for 21 days, from March 27 to April 16. After sowing, 90 kg ha^-1 N, 80 kg ha^-1 P₂O₅, 80 kg ha^-1 K₂O, 10 kg ha^-1 Ca, 70 kg ha^-1 Mg and 40 kg ha^-1 S were applied by fertigation on five dates (20% on February 15, 30% on March 01, 30% on March 15, and 20% on April 01). These nutrients were provided by a combination of calcium nitrate, potassium nitrate, monoammonium phosphate, ammonium sulfate, magnesium sulfate and potassium chloride fertilizers. In both experiments, chlorantraniliprole (Premio-20%) and azoxystrobin/difenoconazole (Amistar Top-20%/12.5%) were used for pest (Diaphania spp.) and disease (Pseudoperonospora cubensis) control, respectively.

Drip tapes (Petroisa, Avaré, BRA) (500 µm thick and 16 mm inner diameter) were placed on the surface of the center of each row before mulching. Each drip tape was connected to a 32 mm diameter polyethylene (PE) pipe. Hand valves controlled the opening and closing of the drip tapes in each plot. The operating pressure was maintained at 100 kPa, controlled with a pressure gauge (Petroisa, Avaré, BRA). Each treatment had a soil moisture sensor (model HFM 1000; Falker, Porto Alegre, Brazil) in only one plot. The sensor, previously calibrated for the soil of the area, was installed directly under the drip tape and between two plants at a depth of 20 cm. The soil in the 0-20 cm layer contains the majority of the roots (Al-Omran et al., 2005; Contreras et al., 2017CONTRERAS, J. I. et al. Irrigation management of greenhouse zucchini with different soil matric potential level. Agronomic and environmental effects. Agricultural Water Management , 183:26-34, 2017.). The daily reading was taken at 8:00. The amount of water delivered in each irrigation event was determined using Equation 1 (Zhang et al., 2017ZHANG, Y. L. et al. Influence of different plastic film mulches and wetted soil percentages on potato grown under drip irrigation. Agricultural Water Management , 180:160-171, 2017.).

I D = Z (θ_{F C} - θ_{a}) P / η

(1)

where ID is the irrigation depth (mm), Z is the soil layer depth (200 mm), θ_FC is the soil moisture at field capacity (m³ m^-3), θ_a is the actual soil moisture before irrigation (m³ m^-3), P is the percentage of the wetted zone (0.50 or 0.70), and η is the coefficient of the efficiency of the drip irrigation system.

The field capacity (θ_FC) was 0.531 m³ m^-3 in 2017 and 0.495 m³ m^-3 in 2018 at a depth of 20 cm. The coefficient of efficiency of the drip irrigation system determined in a field test ranged from 0.91 to 0.95. Irrigation was initiated when the soil moisture (θ_a) was approximately 0.40 m³ m^-3. The maximum soil water depletion was equal to 30% of the soil available storage.

In relation to wetted soil percentages (WSPs), two different drip irrigation systems were used to generate two different wetted soil profiles. Then, different emitter discharges and emitter spacings were used (Schwartzman; Zur, 1986SCHWARTZMAN, M.; ZUR, B. Emitter spacing and geometry of wetted soil volume. Journal of Irrigation and Drainage Engineering, 112(3):242-253, 1986.). For 50% WSP, the drip tape had an emitter discharge of 2.3 L h^-1 and emitter spacing of 50 cm. For 70% WSP, the drip tape had an emitter discharge of 4.3 L h^-1 and emitter spacing of 20 cm. After previous irrigations, the WSP was observed through pits in the field and set as 50% and 70% for the specific soil layer (0-20 cm).

Zucchini water consumption was estimated using soil water balance (Equation 2).

W C = I + P - D - R \pm Δ S

(2)

where WC is the zucchini water consumption (mm), I is the irrigation depth (mm), P is precipitation (mm), D is the drainage flux below the crop root zone (mm), R is the surface runoff (mm), and ΔS is the change in soil water storage (mm).

In this study, P was assumed to be effective for the mulched treatments and nonmulched treatments. The drainage (D) below the root zone (Z) was assumed to be negligible because the irrigation amounts applied were small. R was assumed to be null because the area was flat. ΔS was determined by gravimetric measurements, which were taken by sampling the soil moisture before sowing and at harvest in each treatment.

Meteorological data were obtained from a weather station (Irriplus, model E500, Viçosa, BRA) installed close to the experimental area, with data collected every hour. A digital waterproof thermometer (Dallas Semiconductor, model Ds18b20, Dallas, USA) was installed at a depth of 5 cm in the soil of each treatment in the three plots. Soil temperature (°C) was recorded during the first three weeks after sowing, when the leaf area index was lowest and there was low soil cover from the plant canopy; this was the period of maximum fluctuation in the soil temperature. Measurements were taken every hour using an Arduino Uno microcontroller.

Net photosynthesis (μmol of CO₂ m^-2 s^-1) was recorded in the harvest period on October 25, 2017 and April 02, 2018, corresponding to 69 and 43 days after sowing, respectively. The fourth expanded and healthy leaves of three plants in each experimental unit were selected using the central leaf lobe, and net photosynthesis was measured using a portable infrared gas analyzer (LI-COR Biosciences, model LICor 6400, Nebraska, USA). The constant CO₂ concentration was 400 ppm, and the light intensity was 1200 μmol m^-2 s^-1. This light intensity was chosen based upon a light response curve by choosing the highest net photosynthesis before light saturation (Figure 1).

Figure 1:
Light curve for a zucchini leaf.

Leaf area was measured by digital photograph analysis using R software, following the procedures described by Katabuchi (2015KATABUCHI, M. Leaf area: An R package for rapid digital image analysis of leaf area. Ecological Research, 30(6):1073-1077, 2015.). All the leaves of one plant (0.5 m²) in each plot were collected and photographed. Then, the leaf area index was calculated in m² m^-2.

To quantify weed control in the mulched and nonmulched treatments, the biomass of weeds was measured by collecting and separating the weeds by species. Weeds growing in the hole or piercing the mulch within one 1.0 m x 1.0 m square in each plot between the 2nd and 3rd zucchini plants in the central row were collected and subsequently dried at 70 °C for 72 hours. Weed measurements were carried out on two dates in 2017 (September 13 and 28) and in 2018 (March 12 and 22).

Commercial fruit yield (t ha^-1) was based on fruit production in the central row in each plot. Fruits approximately 18 cm long were harvested daily (Carpes et al., 2008CARPES, R. H. et al. Ausência de frutos colhidos e suas interferências na variabilidade da fitomassa de frutos de abobrinha italiana cultivada em diferentes sistemas de irrigação. Ceres, 55(6):590-595, 2008. ). Water-use efficiency (kg m^-3) was the ratio between the commercial fruit yield (kg m^-2) and amount of water consumed (m³ m^-2).

For the soil temperature and net water requirement, a descriptive analysis was adopted. The other variables were analyzed with an F test (analysis of variance), and when there was a significant difference, the means were compared by Tukey’s test (P ≤ 0.050). The normality, independence and homoscedasticity of the data were verified. The analysis was performed using R software (packages “LeafArea” and “ExpDes.pt”).

RESULTS AND DISCUSSION

The two consecutive cycles had different climatic conditions (Figure 2). During 2017 (August to October), the total amount of precipitation was 63 mm, the average daily air temperature was 20.9 °C, and the average daily reference evapotranspiration was 3.70 mm d^-1. During 2018 (February to April), the total amount of precipitation was 335 mm, the average daily air temperature was 24.5 °C, and the average daily reference evapotranspiration was 3.51 mm d^-1.

Figure 2:
Daily air temperature, reference evapotranspiration (ETo) as determined by the Penman-Monteith equation (indicated by the curves), and daily precipitation (indicated by the bars) during the cropping seasons of 2017 (August 19 to October 31) and 2018 (February 02 to April 16) of zucchini cultivation.

In the 2018 cycle, the number of rain events was almost three times (28) that observed in the 2017 cycle (10) (Table 2). The average amount of water per precipitation event was 6.3 mm in 2017 and 12.0 mm in 2018. This increased the contribution of water from precipitation to the zucchini water consumption in 2018 compared to that in 2017 (including in the mulched treatments) from (average) 7% to 60% (Figure 3). Furthermore, the amount of water was substantially lower in 2018 than in 2017. For the mulched treatments, the zucchini water consumption was equal to 175 mm and 138 mm under the white polyethylene mulch (WP), 164 mm and 145 mm under the black polyethylene mulch (BP) and 165 mm and 145 mm under the biodegradable mulch for the 2017 and 2018 cycles, respectively. In the nonmulched treatment (NM), zucchini water consumption was equal to 239 mm and 190 mm in the 2017 and 2018 cycles, respectively. In general, the average water savings in the mulched treatments were 30 and 25% in the 2017 and 2018 cycles, respectively, compared to the water used in the NM treatment. In relation to the wetted soil percentage (WSP), the zucchini water consumption in the mulched treatments was 7% (2017) and 5% (2018) higher under 70% WSP than under 50% WSP. However, in the NM treatment, the zucchini water consumption was 20% (2017) and 17% (2018) higher in the 70% WSP treatment than in the 50% WSP treatment.

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Table 2:
Rain and irrigation during the zucchini cropping seasons in each soil mulching treatment (SMT) and wetted soil percentage (WSP) treatment.

Figure 3:
Zucchini water consumption for the different soil mulching treatments: white polyethylene mulch (WP), black polyethylene mulch (BP), recycled paper mulch (RP), nonmulched (NM) and wetted soil percentages: 50% (P50) and 70% (P70) for the cropping seasons of 2017 and 2018.

The water consumption and agronomic characteristics of zucchini were greatly influenced by the cropping seasons. Different climatic conditions were observed in each season. Precipitation and air temperature were both lower in 2017 and higher in 2018. In general, the cropping season of 2017 was cold and dry, and the cropping season of 2018 was hot and rainy. Most likely, the climatic conditions (high air temperature) accelerated the zucchini cycle, reducing it from 75 days in 2017 to 57 days in 2018. Due to the duration of the zucchini cycle associated with the climatic condition, the water consumption was lower in 2018 than in 2017.

In the mulched treatments, the biodegradable mulch reduced water consumption more than the polyethylene mulch. Polyethylene mulch can save water by reducing soil evaporation (Liu et al., 2013LIU, M. X. et al. Numerical simulation of soil water dynamics in a drip irrigated cotton field under plastic mulch. Pedosphere, 23(5):620-635, 2013.). Mulch affects soil water contents mainly in the top 0-20 cm layer (Chen et al., 2019CHEN, B. et al. Two-dimensional monitoring of soil water content in fields with plastic mulching using electrical resistivity tomography. Computers and Electronics in Agriculture, 159:84-91, 2019.). Water saving under biodegradable mulch depends on its rate of degradation during the cropping season (Chen et al., 2019CHEN, B. et al. Two-dimensional monitoring of soil water content in fields with plastic mulching using electrical resistivity tomography. Computers and Electronics in Agriculture, 159:84-91, 2019.; Saglam et al., 2017SAGLAM, M. et al. Modeling the effect of biodegradable paper and plastic mulch on soil moisture dynamics. Agricultural Water Management , 193:240-250, 2017.). In this study, the biodegradable mulching material (recycled paper), basically composed of cellulose, was quite resistant to degradation, performing similarly to polyethylene in terms of soil moisture conservation. The resistance to degradation by the recycled paper mulch can be explained by its relatively low water absorption (33.46 g of H₂O m^-2) and specific volume (1.42 cm³ g^-1), which indicate a more compact chemical bond between the fibers compared to that in other biodegradable mulches. Slight degradation was observed only along the buried edges, probably caused by soil microorganisms that degrade cellulose.

The soil temperatures under the different soil mulching treatments were affected by the composition of the mulching material employed in both cropping seasons (Figure 4). The soil temperature under the BP was higher in all daylengths during both cropping seasons. The greatest daily thermal amplitude occurred in NM treatment (9.2 °C in 2017 and 7.3 °C in 2018). On the other hand, the lowest daily thermal amplitude occurred in the RP treatment (6.0 °C in 2017 and 3.6 °C in 2018). The cooling effect of the RP reduced the soil temperature during the hottest hours of the day (~15 hours).

Figure 4:
Soil temperature at 5 cm beneath the soil mulching treatment in the cropping seasons of 2017 (A) and 2018 (B). WP, white polyethylene; BP, black polyethylene; RP, recycled paper and NM, nonmulched. The data shown represent the average of the first three weeks.

The climatic conditions created by high air temperature associated with solar radiation contributed to increasing the soil temperature. In the cropping season of 2018, the soil temperature reached 32.3 °C at 15:00 hours in the BP treatment. Reports have shown that soil temperatures above 30 °C can interfere negatively with transpiration, photosynthesis and water flow in plants (Amorin; Valle, 1992AMORIN, S. M. C. de; VALLE, R. R. Radicular temperature effects in water movement resistence in cacao tree (Theobroma cacao L.). Acta Botanica Brasilica, 6(1):55-64, 1992.) and reduce fruit yield (Namaghi et al., 2018NAMAGHI, M. N. et al. Effects of mulching on soil temperature and moisture variations, leaf nutrient status, growth and yield of pistachio trees (Pistacia vera .L). Scientia Horticulturae, 241:115-123, 2018.). A suitable alternative to reducing soil heat flux is light-colored mulch (such as the RP and WP mulches), especially in tropical climates, such as those found in southeastern Brazil. Light-colored mulch can increase the reflection of solar radiation and reduce soil heat flux and, consequently, soil temperature (Decoteau; Kasperbauer; Hunt, 1990DECOTEAU, D. R.; KASPERBAUER, M. J.; HUNT, P. G. Bell pepper plant development over mulches of diverse colors. HortScience , 25(4):460-462, 1990.; Ham; Kluitenberg; Lamont, 1993HAM, J. M.; KLUITENBERG, G. J.; LAMONT, W. J. Optical properties of plastic mulches affect the field temperature regime. Journal of the American Society for Horticultural Science , 118(2):188-193, 1993.).

In general, the zucchini characteristics were higher in the cropping season of 2017 than in that of 2018 (Table 3). The net photosynthesis (An) was higher in 2017 (20 µmol CO₂ m^-2 s^-1) than in 2018 (19 µmol CO₂ m^-2 s^-1). Furthermore, the leaf area index (LAI) was much higher (27%) in 2017 (2.98 m² m^-2) than in 2018 (2.34 m² m^-2). The zucchini plants yielded 96.3 ton ha^-1 in 2017 and 36.9 ton ha^-1 in 2018. The water-use efficiency (WUE) was higher in 2017 (53.9 kg m^-3) than in 2018 (35.1 kg m^-3). The weeds growing in the area, measured by weed dry mass (WDM), were similar in both cropping seasons. However, the amount of weeds growing in the NM treatment (32.9 g m^-2) was substantially higher than that in the mulched treatments (i.e., WP, BP and RP) (1.5 g m^-2, on average). Furthermore, weed control in the RP treatment (2.1 g m^-2) was comparable to that in the polyethylene mulch treatments (WP, 1.2 g m^-2; BP, 1.4 g m^-2). The LAI was much higher (150%) in the mulched treatments than in the NM treatment. The soil mulching treatments greatly influenced fruit production, with yields of 78.1 ton ha^-1 in the WP treatment, 69.1 ton ha^-1 in the BP treatment, 66.6 ton ha^-1 in the RP treatment and 52.4 ton ha^-1 in the NM treatment. The WUE was higher in the mulched treatments than in the NM treatment. The wetted soil percentages influenced only the WUE, which was higher in the 50% treatment (41.6 kg m^-3) than in the 70% treatment (37.4 kg m^-3).

Thumbnail

Table 3:
Tukey test for the effects of the cropping seasons (S), soil mulching materials (M) and wetted soil percentages (P) on the net photosynthesis (An), leaf area index (LAI), fruit yield (Yield), water-use efficiency (WUE) of zucchini and weed dry mass (WDM).

The rate of photosynthesis is affected by thermal and water stresses (Amorin; Valle, 1992AMORIN, S. M. C. de; VALLE, R. R. Radicular temperature effects in water movement resistence in cacao tree (Theobroma cacao L.). Acta Botanica Brasilica, 6(1):55-64, 1992.; El-Mageed; Semida; El-Wahed, 2016EL-MAGEED, T. A. A.; SEMIDA, W. M.; EL-WAHED, M. H. A. Effect of mulching on plant water status, soil salinity and yield of squash under summer-fall deficit irrigation in salt affected soil. Agricultural Water Management , 173:1-12, 2016.; Mu; Fang, 2017MU, L.; FANG, L. Effects of different mulching practices on the photosynthetic characteristics of hot pepper (Capsicum annuum L.) in a greenhouse in Northwest China. Acta Agriculturae Scandinavica, Section B - Soil & Plant Science , 65(8):735-746, 2017.). Most likely, the higher soil temperature in 2018 negatively affected the net photosynthesis compared to that in 2017. Moreover, in 2017, the yield was 2.6 times higher than that in 2018. This result can be explained by the larger leaf area in 2017 associated with higher daily solar radiation and longer cycle duration compared to those in 2018. The average daily solar radiation was 239 W m^-2 in 2017 and 205 m^-2 in 2018. The duration of the zucchini cycle was 75 days in 2017 and 57 days in 2018. Plant growth and fruit yield are closely linked to the amount of photosynthetically active radiation (PAR; 400-700 nm) intercepted by leaves, and LAI is frequently used for quantifying the intercepted PAR (Ewert, 2004EWERT, F. Modelling plant responses to elevated CO2: How important is leaf area index? Annals of Botany, 93(6):619-627, 2004.). Furthermore, compared with the recommended range (18 to 24 °C), the fluctuations in air temperature were more suitable for zucchini in 2017 than in 2018 (Fontes, 2005FONTES, P. C. R. Olericultura teoria e prática. Viçosa: Editora UFV, 2005. 486p.). The combination of these factors may have resulted in more carbohydrate production and consequently more fruit production.

Mulching is an appropriate agricultural technique for water saving. Reports have shown an increase in water-use efficiency (WUE) in many crops, such as pumpkin (Brust, 2000BRUST, G. E. Reflective and black mulch increase yield in pumpkins under virus disease pressure. Journal of Economic Entomology, 93(3):828-833, 2000.), squash (El-Mageed; Semida; El-Wahed, 2016EL-MAGEED, T. A. A.; SEMIDA, W. M.; EL-WAHED, M. H. A. Effect of mulching on plant water status, soil salinity and yield of squash under summer-fall deficit irrigation in salt affected soil. Agricultural Water Management , 173:1-12, 2016.), potato (Zhang et al., 2017ZHANG, Y. L. et al. Influence of different plastic film mulches and wetted soil percentages on potato grown under drip irrigation. Agricultural Water Management , 180:160-171, 2017.), sorghum (El-Mageed et al., 2018EL-MAGEED, T. A. A. et al. Compost and mulching modulates morphological, physiological responses and water use efficiency in sorghum (bicolor L. Moench) under low moisture regime. Agricultural Water Management , 208:431-439, 2018.) and cucumber (Yaghi; Arslan; Naoum, 2013YAGHI, T.; ARSLAN, A.; NAOUM, F. Cucumber (Cucumis sativus, L.) water use efficiency (WUE) under plastic mulch and drip irrigation. Agricultural Water Management , 128:149-157, 2013. ). Mulches conserve soil moisture and reduce soil evaporation, improving plant water status (El-Mageed et al., 2018EL-MAGEED, T. A. A. et al. Compost and mulching modulates morphological, physiological responses and water use efficiency in sorghum (bicolor L. Moench) under low moisture regime. Agricultural Water Management , 208:431-439, 2018.). Soil water evaporation is generally not useful for increasing crop yield (Xie; Wang; Li, 2005XIE, Z.; WANG, Y.; LI, F. Effect of plastic mulching on soil water use and spring wheat yield in arid region of northwest China. Agricultural Water Management , 75:71-83, 2005.). In this study, a low wetted soil percentage (50%) increased the WUE, which is consistent with results in potato crops (Zhang et al., 2017ZHANG, Y. L. et al. Influence of different plastic film mulches and wetted soil percentages on potato grown under drip irrigation. Agricultural Water Management , 180:160-171, 2017.).

The abundance of five predominant species of weeds was different for the soil mulching treatments and cropping seasons (Figure 5). In general, the weeds Cyperus rotundus (35%) and Oxalis latifolia (39%) were more abundant in the mulched treatments (RP, WP and BP), while C. rotundus (37%) and Amaranthus viridis (33%) were more abundant in the NM treatment. The percentage of C. rotundus increased from 2017 (27%) to 2018 (46%) in all the treatments. On the other hand, the percentage of the weeds Emilia sonchifolia, A. viridis and Sorghum halepense decreased substantially from 2017 to 2018 in the mulched treatments.

Figure 5:
Pie chart of the relative abundances of the weeds (dry mass (g m^-2)) in the zucchini plots grown with different soil mulching treatments: white polyethylene mulch (WP), black polyethylene mulch (BP), biodegradable mulch of recycled paper (RP), and nonmulched (NM) for the cropping seasons of 2017 and 2018.

The yield was much higher in the mulched treatments than in the NM. Mulch can increase surface reflectance (Decoteau; Kasperbauer; Hunt, 1990DECOTEAU, D. R.; KASPERBAUER, M. J.; HUNT, P. G. Bell pepper plant development over mulches of diverse colors. HortScience , 25(4):460-462, 1990.; Ham; Kluitenberg; Lamont, 1993HAM, J. M.; KLUITENBERG, G. J.; LAMONT, W. J. Optical properties of plastic mulches affect the field temperature regime. Journal of the American Society for Horticultural Science , 118(2):188-193, 1993.), contributing to the efficiency of light absorption by chlorophyll and consequently increasing fruit yield (Brust, 2000BRUST, G. E. Reflective and black mulch increase yield in pumpkins under virus disease pressure. Journal of Economic Entomology, 93(3):828-833, 2000.; Olinik et al., 2011OLINIK, J. et al. Produtividade de híbridos de abobrinha italiana cultivados sob diferentes coberturas de solo. Horticultura Brasileira, 29(1):130-134, 2011.). Mulch is important for weed control (Coleman et al., 2015COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.). Weeds compete for water, nutrients, light and space, which can lead to a loss of productivity. In this study, the predominant weed was Cyperus rotundus, a perennial, aggressive and difficult-to-control weed (Kumar, 2016KUMAR, V. Importance of Motha (Cyperus rotundus Linn.) and its control management. Van Sangyan, 3(5):37-43, 2016.), considered the most problematic in cucurbit crops (Coleman et al., 2015COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.). In general, the biodegradable mulch (RP) was comparable to the polyethylene mulch in terms of weed control; therefore, it is a suitable alternative that could replace polyethylene mulch. These results represent useful information for farmers and technicians regarding the use of mulches. Furthermore, curiously, C. rotundus and Oxalis latifolia were the predominant weeds in the mulched treatments. These weeds have in common a reserve structure that provides energy for the growth/development of the plant, allowing it to find sunlight through the mulch hole.

CONCLUSIONS

In this study, the cropping season, soil mulching treatment and wetted soil percentage significantly influenced the zucchini water consumption and agronomic characteristics. The biodegradable mulch was comparable to the polyethylene mulch in terms of water savings. The cropping season of 2017 was more favorable for zucchini than the 2018 season, resulting in higher leaf area growth, net photosynthesis, fruit yield and water-use efficiency. On average, the mulch reduced water consumption by 30% in 2017 and 25% in 2018. The zucchini water consumption was equal to 175 mm and 138 mm under the white polyethylene mulch, 164 mm and 145 mm under the black polyethylene mulch, 165 mm and 145 mm under the biodegradable mulch and 239 mm and 190 mm in the nonmulched treatment in the cropping seasons of 2017 and 2018, respectively. Soil temperature and its amplitude were reduced under the biodegradable and white polyethylene mulches, so both are suitable alternatives to traditional mulches in tropical climates. Compared to the nonmulched treatment, the mulch treatments were efficient in saving water, reducing weed infestations (95%), increasing yield (36%) and enhancing water-use efficiency (94%). Compared to the 70% (37.4 kg m^-3) wetted soil percentage, the 50% (41.6 kg m^-3) treatment increased the water-use efficiency. Compared to the polyethylene mulch, C. rotundus and other weeds were better controlled by the biodegradable mulch. In general, these results represent useful information that extends the options for technicians and farmers.

ACKNOWLEDGEMENTS

The authors are grateful to the Brazilian National Council for Scientific and Technological Development (CNPq), scholarship grant 434484/2018-0, to the Coordination for the Improvement of Higher Education Personnel (Capes), Finance code 001, and especially to Professor Silvio Bueno Pereira (in memory) (DEA-UFV) for his scientific support.

REFERENCES

AHOKAS, J. et al. Paper based mulches as an alternative to polyethylene mulch in vegetable production. Makinaları Bilimi Dergisi, 10(1):73-78, 2014.
AL-OMRAN, A. M. et al. Effect of drip irrigation on squash (Cucurbita pepo) yield and water-use efficiency in sandy calcareous soils amended with clay deposits. Agricultural Water Management, 73(1):43-55, 2005.
ALVARES, C. A. et al. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22(6):711-728, 2013.
AMORIN, S. M. C. de; VALLE, R. R. Radicular temperature effects in water movement resistence in cacao tree (Theobroma cacao L.). Acta Botanica Brasilica, 6(1):55-64, 1992.
BISWAS, S. K. et al. Effect of drip irrigation and mulching on yield, water-use efficiency and economics of tomato. Plant, Soil and Environment, 61(3):97-102, 2015.
BRAULT, D.; STEWART, K. A.; JENNI, S. Growth, development, and yield of head lettuce cultivated on paper and polyethylene Mulch. HortScience, 37(1):92-94, 2002.
BRUST, G. E. Reflective and black mulch increase yield in pumpkins under virus disease pressure. Journal of Economic Entomology, 93(3):828-833, 2000.
CARPES, R. H. et al. Ausência de frutos colhidos e suas interferências na variabilidade da fitomassa de frutos de abobrinha italiana cultivada em diferentes sistemas de irrigação. Ceres, 55(6):590-595, 2008.
CHEN, B. et al. Two-dimensional monitoring of soil water content in fields with plastic mulching using electrical resistivity tomography. Computers and Electronics in Agriculture, 159:84-91, 2019.
CHEN, Y. et al. Empirical estimation of pollution load and contamination levels of phthalate esters in agricultural soils from plastic film mulching in China. Environmental Earth Sciences, 70(1):239-247, 2013.
CIRUJEDA, A. et al. Biodegradable mulch instead of polyethylene for weed control of processing tomato production. Agronomy for Sustainable Development, 32(4):889-897, 2012.
COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.
CONTRERAS, J. I. et al. Irrigation management of greenhouse zucchini with different soil matric potential level. Agronomic and environmental effects. Agricultural Water Management , 183:26-34, 2017.
DECOTEAU, D. R.; KASPERBAUER, M. J.; HUNT, P. G. Bell pepper plant development over mulches of diverse colors. HortScience , 25(4):460-462, 1990.
EL-MAGEED, T. A. A. et al. Compost and mulching modulates morphological, physiological responses and water use efficiency in sorghum (bicolor L. Moench) under low moisture regime. Agricultural Water Management , 208:431-439, 2018.
EL-MAGEED, T. A. A.; SEMIDA, W. M.; EL-WAHED, M. H. A. Effect of mulching on plant water status, soil salinity and yield of squash under summer-fall deficit irrigation in salt affected soil. Agricultural Water Management , 173:1-12, 2016.
EL-SAMNOUDI, I. M. et al. Combined effect of poultry manure and soil mulching on soil properties, physiological responses, yields and water-use efficiencies of sorghum plants under water stress. Communications in Soil Science and Plant Analysis, 50(20):2626-2639, 2019.
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» http://dw.ceasa.gov.br/
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Publication Dates

Publication in this collection
15 June 2020
Date of issue
2020

History

Received
20 Mar 2020
Accepted
27 May 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AHOKAS, J. et al. Paper based mulches as an alternative to polyethylene mulch in vegetable production. Makinaları Bilimi Dergisi, 10(1):73-78, 2014.

[2] AL-OMRAN, A. M. et al. Effect of drip irrigation on squash (Cucurbita pepo) yield and water-use efficiency in sandy calcareous soils amended with clay deposits. Agricultural Water Management, 73(1):43-55, 2005.

[3] ALVARES, C. A. et al. Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift, 22(6):711-728, 2013.

[4] AMORIN, S. M. C. de; VALLE, R. R. Radicular temperature effects in water movement resistence in cacao tree (Theobroma cacao L.). Acta Botanica Brasilica, 6(1):55-64, 1992.

[5] BISWAS, S. K. et al. Effect of drip irrigation and mulching on yield, water-use efficiency and economics of tomato. Plant, Soil and Environment, 61(3):97-102, 2015.

[6] BRAULT, D.; STEWART, K. A.; JENNI, S. Growth, development, and yield of head lettuce cultivated on paper and polyethylene Mulch. HortScience, 37(1):92-94, 2002.

[7] BRUST, G. E. Reflective and black mulch increase yield in pumpkins under virus disease pressure. Journal of Economic Entomology, 93(3):828-833, 2000.

[8] CARPES, R. H. et al. Ausência de frutos colhidos e suas interferências na variabilidade da fitomassa de frutos de abobrinha italiana cultivada em diferentes sistemas de irrigação. Ceres, 55(6):590-595, 2008.

[9] CHEN, B. et al. Two-dimensional monitoring of soil water content in fields with plastic mulching using electrical resistivity tomography. Computers and Electronics in Agriculture, 159:84-91, 2019.

[10] CHEN, Y. et al. Empirical estimation of pollution load and contamination levels of phthalate esters in agricultural soils from plastic film mulching in China. Environmental Earth Sciences, 70(1):239-247, 2013.

[11] CIRUJEDA, A. et al. Biodegradable mulch instead of polyethylene for weed control of processing tomato production. Agronomy for Sustainable Development, 32(4):889-897, 2012.

[12] COLEMAN, M. J. et al. Survey of weed impact, management, and research priorities in Australian cucurbit production. Plant Protection Quarterly, 30(1):12-20, 2015.

[13] CONTRERAS, J. I. et al. Irrigation management of greenhouse zucchini with different soil matric potential level. Agronomic and environmental effects. Agricultural Water Management , 183:26-34, 2017.

[14] DECOTEAU, D. R.; KASPERBAUER, M. J.; HUNT, P. G. Bell pepper plant development over mulches of diverse colors. HortScience , 25(4):460-462, 1990.

[15] EL-MAGEED, T. A. A. et al. Compost and mulching modulates morphological, physiological responses and water use efficiency in sorghum (bicolor L. Moench) under low moisture regime. Agricultural Water Management , 208:431-439, 2018.

[16] EL-MAGEED, T. A. A.; SEMIDA, W. M.; EL-WAHED, M. H. A. Effect of mulching on plant water status, soil salinity and yield of squash under summer-fall deficit irrigation in salt affected soil. Agricultural Water Management , 173:1-12, 2016.

[17] EL-SAMNOUDI, I. M. et al. Combined effect of poultry manure and soil mulching on soil properties, physiological responses, yields and water-use efficiencies of sorghum plants under water stress. Communications in Soil Science and Plant Analysis, 50(20):2626-2639, 2019.

[18] EWERT, F. Modelling plant responses to elevated CO₂: How important is leaf area index? Annals of Botany, 93(6):619-627, 2004.

[19] FAN, Y. et al. Plastic mulch decreases available energy and evapotranspiration and improves yield and water use efficiency in an irrigated maize cropland. Agricultural Water Management , 179:122-131, 2017.

[20] FEDDES, R. A. et al. Simulation of field water uptake by plants using a soil water dependent root extraction function. Journal of Hydrology, 31(1):13-26, 1976.

[21] FONTES, P. C. R. Olericultura teoria e prática. Viçosa: Editora UFV, 2005. 486p.

[22] GRECCO, K. L. et al. HYDRUS-2D simulations of water and potassium movement in drip irrigated tropical soil container cultivated with sugarcane. Agricultural Water Management , 221:334-347, 2019.

[23] GROSS, R. A.; KALRA, B. Biodegradable polymers for the environment. Science, 297:803-807, 2002.

[24] HAM, J. M.; KLUITENBERG, G. J.; LAMONT, W. J. Optical properties of plastic mulches affect the field temperature regime. Journal of the American Society for Horticultural Science , 118(2):188-193, 1993.

[25] HOU, F. et al. Mulching with plastic film improved the root quality of summer-sown sweet potato (Ipomoea batatas (L). Lam.) in northern China. Journal of Integrative Agriculture, 18(5):982-991, 2019.

[26] KASIRAJAN, S.; NGOUAJIO, M. Polyethylene and biodegradable mulches for agricultural applications: A review. Agronomy for Sustainable Development , 32(2):501-529, 2012.

[27] KATABUCHI, M. Leaf area: An R package for rapid digital image analysis of leaf area. Ecological Research, 30(6):1073-1077, 2015.

[28] KELLER, J.; KARMELI, D. Trickle irrigation design parameters. Transactions of the ASAE, 17(4):678-684, 1974.

[29] KUMAR, V. Importance of Motha (Cyperus rotundus Linn.) and its control management. Van Sangyan, 3(5):37-43, 2016.

[30] KUSLU, Y. et al. Fruit yield and quality, and irrigation water use efficiency of summer squash drip-irrigated with different irrigation quantities in a semi-arid agricultural area. Journal of Integrative Agriculture , 13(11):2518-2526, 2014.

[31] LIU, E. K.; HE, W. Q.; YAN, C. R. ‘White revolution’ to ‘white pollution’ - Agricultural plastic film mulch in China. Environmental Research Letters, 9:99-101, 2014.

[32] LIU, M. X. et al. Numerical simulation of soil water dynamics in a drip irrigated cotton field under plastic mulch. Pedosphere, 23(5):620-635, 2013.

[33] MILES, C. et al. Deterioration of potentially biodegradable alternatives to black plastic mulch in three tomato production regions. Hort Science, 47(9):1270-1277, 2012.

[34] MU, L.; FANG, L. Effects of different mulching practices on the photosynthetic characteristics of hot pepper (Capsicum annuum L.) in a greenhouse in Northwest China. Acta Agriculturae Scandinavica, Section B - Soil & Plant Science , 65(8):735-746, 2017.

[35] NAMAGHI, M. N. et al. Effects of mulching on soil temperature and moisture variations, leaf nutrient status, growth and yield of pistachio trees (Pistacia vera .L). Scientia Horticulturae, 241:115-123, 2018.

[36] OLINIK, J. et al. Produtividade de híbridos de abobrinha italiana cultivados sob diferentes coberturas de solo. Horticultura Brasileira, 29(1):130-134, 2011.

[37] PROHORT. Programa Brasileiro de Modernização do Mercado Hortigranjeiro - PROHORT. 2019. Available in: <Available in: http://dw.ceasa.gov.br/ >. Access in: September, 16, 2019.
» http://dw.ceasa.gov.br/

[38] QIN, S. et al. Can the drip irrigation under film mulch reduce crop evapotranspiration and save water under the sufficient irrigation condition? Agricultural Water Management , 177:128-137, 2016.

[39] RIBAS, G. G. et al. Temperatura do solo afetada pela irrigação e por diferentes coberturas. Engenharia Agrícola, 35(5):817-828, 2015.

[40] SAGLAM, M. et al. Modeling the effect of biodegradable paper and plastic mulch on soil moisture dynamics. Agricultural Water Management , 193:240-250, 2017.

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Cycle	pH	P	K	S	Ca	Mg	Organic matter	Bulk density	θ_FC	θ_PWP
Cycle	pH	mg dm^-3			cmol_c dm^-3		g kg^-1	g cm^-3	m³ m^-3
1	5.8	88	152	35.7	4.20	0.9	32.2	1.17	0.531	0.362
2	6.2	118	242	16.8	5.72	1.0	27.1	1.09	0.495	0.337

Treatment		An (µmol CO₂ m^-2 s^-1)	LAI (m² m^-2)	Yield (ton ha^-1)	WUE (kg m^-3)	WDM¹ (g m^-2)
Cropping season (S)	2017	20.0 a	2.98 a	96.3 a	53.9 a	1.38
Cropping season (S)	2018	19.0 b	2.34 b	36.9 b	25.1 b	1.36
Soil mulching material (M)	WP	19.4	3.06 a	78.1 a	49.6 a	0.62 b
	BP	19.7	3.01 a	69.1 ab	44.0 ab	0.64 b
	RP	19.9	2.63 a	66.6 b	41.3 b	0.89 b
	NM	19.1	1.93 b	52.4 c	23.2 c	3.35 a
Wetted soil percentage (P)	P50	19.3	2.63	67.4	41.6 a	1.36
Wetted soil percentage (P)	P70	19.7	2.69	65.9	37.4 b	1.39
p-value
S		0.0211*	<0.0001*	<0.0001*	<0.0001*	0.8628^ns
M		0.5891^ns	<0.0001*	<0.0001*	<0.0001*	<0.0001*
P		0.4288^ns	0.7249^ns	0.6236^ns	0.0173*	0.7768^ns
SxM		0.5257^ns	0.5337^ns	0.5214^ns	0.0978^ns	0.1026^ns
SxP		0.4451^ns	0.6011^ns	0.1521^ns	0.5183^ns	0.5669^ns
MxP		0.7072^ns	0.1697^ns	0.0806^ns	0.1421^ns	0.3887^ns
SxMxP		0.8868^ns	0.4625^ns	0.1856^ns	0.2011^ns	0.7886^ns

Treatments			Rain (mm)	Number of rain events	Number of irrigation events	Cumulative water volume applied as irrigations (mm)
Cropping seasons	WSP	SMT	Rain (mm)	Number of rain events	Number of irrigation events	Cumulative water volume applied as irrigations (mm)
2017	50%	WP	63	10	17	165
		BP	63	10	17	152
		RP	63	10	17	156
		NM	63	10	27	181
	70%	WP	63	10	18	177
		BP	63	10	18	168
		RP	63	10	18	162
		NM	63	10	27	213
2018	50%	WP	335	28	8	40
		BP	335	28	8	47
		RP	335	28	5	45
		NM	335	28	10	88
	70%	WP	335	28	6	28
		BP	335	28	5	44
		RP	335	28	8	50
		NM	335	28	10	53

Brasil

Brasil

Mulching materials and wetted soil percentages on zucchini cultivation

Tratamentos de cobertura do solo e porcentagens de área molhada no cultivo da abobrinha

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSIONS

ACKNOWLEDGEMENTS

REFERENCES

Publication Dates

History