Effect of Pesticide Addition Sequence on the Preparation of Phytosanitary Spray Solutions

RAMOS, M.F.T.; SANTOS, R.T.S.; ALMEIDA, D.P.; VECHIA, J.F.D.; FERREIRA, M.C.

doi:10.1590/S0100-83582019370100075

ABSTRACT:

The addition of adjuvants to herbicide solutions is aimed at preserving or enhancing the biological effect of treatment. However, it is commonly performed without knowledge of the physicochemical interactions between products. This study aimed to assess the effects of different addition sequences of the herbicide aminopyralid + fluroxypyr and adjuvants in the preparation of phytosanitary spray solutions on the surface tension and contact angle. Two experiments were carried out with herbicide doses of 1 and 2 L ha-1 associated with the adjuvants mineral oil (MO), silicone-polyether copolymer (SIL), and a mixture of phosphatidylcholine (lectin) and propionic acid (LEC), all at a proportion of 0.3% v v-1. The application rate was 150 L ha-1. Surface tension was measured by the pendant droplet method. Contact angle was measured on the adaxial and abaxial surfaces of leaves of the pasture weed Senna obtusifolia and parafilm. Preparation sequence did not change the contact angle on any of the analyzed surfaces at a dose of 1 L ha-1 of herbicide. For the dose of 2 L ha-1, the adjuvants SIL and LEC showed a higher spreading when previously added to the herbicide. MO resulted in a higher spreading when added after the herbicide, with higher surface coverage. Therefore, the preparation sequence influences the dispersion of phytosanitary spray solutions on targets.

Keywords:
adjuvants; preparation sequence; Senna obtusifolia

RESUMO:

A adição de adjuvantes às caldas herbicidas visa preservar ou aumentar o efeito biológico do tratamento, porém é comumente realizada sem conhecimento das interações físico-químicas entre os produtos. Assim, objetivou-se neste trabalho avaliar os efeitos sobre a tensão superficial e o ângulo de contato decorrentes de diferentes sequências de adição do herbicida aminopiralide + fluroxipir e adjuvantes no preparo de caldas fitossanitárias. Foram realizados dois experimentos, com a dosagem de 1 e 2 L ha-1 do herbicida, associados aos adjuvantes óleo mineral (OM), copolímero de poliéter e silicone (SIL), mistura de fosfatidicolina e ácido propiônico (LEC), todos na proporção de 0,3% v v-1. A taxa de aplicação considerada foi de 150 L ha-1. Mediu-se a tensão superficial pelo método da gota pendente. O ângulo de contato foi medido nas superfícies adaxial e abaxial de folhas da planta daninha de pastagens Senna obtusifolia e em parafilme. Verificou-se que a ordem de preparo não alterou o ângulo de contato em nenhuma das superfícies analisadas na dosagem de 1 L ha-1 do herbicida. Para a dosagem de 2 L ha-1, os adjuvantes SIL e LEC apresentaram maior espalhamento quando adicionados previamente ao herbicida. O OM resultou em maior espalhamento quando adicionado após o herbicida, com maior cobertura da superfície. Portanto, a sequência de preparo das caldas fitossanitárias influencia no espalhamento destas sobre os alvos.

Palavras-chave:
adjuvantes; ordem de preparo; Senna obtusifolia

INTRODUCTION

Product addition sequence to the sprayer tank during the preparation of spray solution with herbicides and adjuvants is important to avoid possible problems with phytointoxication, treatment ineffectiveness or damages to the sprayer equipment due to potential incompatibilities (Cessa et al., 2013Cessa RMA, Honaiser AC, Melo EP, Lima Junior IS. Dessecação de Brachiaria decumbens: ordem de preparo e constituintes da calda de pulverização. Rev Cienc Exatas Terra - UNIGRAN. 2013;2(1):33-40.).

Agricultural adjuvants are compounds added to formulations or spray solutions directly into the sprayer tank to modify their physicochemical properties. These compounds may contribute to the compatibility of products in the sprayer tank and improve the performance of agricultural applications, influencing the viscosity, surface tension, contact angle, pH, electrical conductivity, and retention and droplet deposition (Prado et al., 2016Prado EP, Raetano C, Ferreira MH. Effects of agricultural spray adjuvants in surface tension reduction and spray retention on Eucalyptus leaves. Afr J Agric Res. 2016;11(40):3959-65.; Cunha et al., 2017Cunha JPAR, Alves GS, Marques RS. Tensão superficial, potencial hidrogeniônico e condutividade elétrica de caldas de produtos fitossanitários e adjuvantes. Rev Cienc Agron. 2017;48(2):261-70.). Each adjuvant has specific properties aimed at acting in increased permeability and absorption of molecules, retention of spray solution, surface coverage, reduction of foam, adequacy of droplets for the dispersion of spray solution on targets, among others (Oliveira et al., 2013Oliveira RB, Antuniassi UR, Mota AAB, Chechetto RG. Potential of adjuvants to reduce drift in agricultural spraying. Eng Agric. 2013;33(5)986-92.; Decaro Junior et al., 2015Decaro Junior ST, Ferreira MC, Lasmar O. Physical characteristics of oily spraying liquids and droplets formed on coffee leaves and glass surfaces. Eng Agríc. 2015;35:588-600.; Decaro et al., 2016Decaro RA, Decaro Junior ST, Ferreira MC. Deposit of pesticides without and with adjuvants on citrus seedlings following different intervals of artificial rain. Cienc Rural. 2016;46(1)13-9.).

Thus, surface tension is the force on fluid surfaces, and its reduction in the spray solution provides a higher spreading capacity of droplets (Silva et al., 2006Silva FML, Velini ED, Corrêa TM. Influência dos íons Mg, Ca, Fe, Cu e Zn sobre a tensão superficial estática de soluções contendo surfatante. Planta Daninha. 2006;24(3):589-95.). Thus, this property interferes with the amount of herbicide retained on the leaf surface and, together with leaf chemical composition, how this interaction occurs (Prado et al., 2016Prado EP, Raetano C, Ferreira MH. Effects of agricultural spray adjuvants in surface tension reduction and spray retention on Eucalyptus leaves. Afr J Agric Res. 2016;11(40):3959-65.). Adjuvants differ significantly from each other in reducing the surface tension and contact angle, factors relevant to droplet formation and target coverage, which should be carefully considered for an appropriate selection (Li et al., 2016Li J, Chen W, Xu Y, Wu X. Comparative effects of different types of tankmixed adjuvants on the efficacy, absorption and translocation of cyhalofop-butyl in barnyardgrass (Echinochloa crus-galli [L.] Beauv.). Weed Biol Manage. 2016;16(2):80-9.).

Considering the lack of information on the technology of pesticide application in pastures, this study aims at contributing to the decision-making of farmers regarding the most appropriate combination between adjuvants and herbicide, as well as the correct product addition sequence to the phytosanitary spray solution since it is possible that adjuvant addition alternation interferes with the surface tension and, consequently, droplet spreading on leaf surfaces.

Thus, this study aimed to assess the effects of different addition sequences of the herbicide aminopyralid + fluroxypyr and adjuvants in the preparation of phytosanitary spray solutions and their influence on the surface tension and contact angle.

MATERIAL AND METHODS

The study of effects of the addition sequence of herbicides and adjuvants on the preparation of spray solution was carried out in 2016 in a completely randomized design with four replications, arranged in a 2 × 3 + 1 factorial scheme. Interaction factors consisted of two treatments related to the preparation sequence of the spray solution (herbicide + adjuvant and adjuvant + herbicide) and three adjuvants, with water as the control (Table 1).

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Table 1
Treatments for the assessments of surface tension and contact angle of both experiments, with the respective preparation sequences

The herbicide used in the experiment was aminopyralid + fluroxypyr (Dominum® 40.0 g a.e. L-1 + 80 g a.e. L-1, SL, Dow AgroSciences), belonging to the groups pyridinecarboxylic and pyridinyloxyalkanoic acids, respectively, with registration for Senna obtusifolia in pastures. This herbicide was associated with three adjuvants: 1 - aliphatic hydrocarbons (mineral oil: Nimbus®, 428.0 g a.i. L-1, EC, Syngenta); 2 - organosiliconate (silicone-polyether copolymer: Silwet®, 1,000 g a.i. L-1); and 3 - mixture of phosphatidylcholine (lectin) and propionic acid (LI-700®, 712.88 g a.i. L-1, CE, De SANGOSSE Agroquímica). Each adjuvant was added to the spray solution at a proportion of 0.3% v v-1, alternately to the herbicide (Table 1), as recommended in the herbicide leaflet. A concentration equivalent to the application rate of 150 L ha-1 was used as a basis.

Two experiments were performed: one at a dose of 1 L ha-1 of commercial herbicide (experiment I) and the other at a dose of 2 L ha-1 of herbicide (experiment II), considering the control of S. obtusifolia and other broadleaf weed species present in the pasture (Table 1).

Experiments were also performed to determine the physicochemical characteristics of the phytosanitary spray solutions, in which the surface tension and contact angle were assessed. The equipment used was the Contact Angle System OCA 15-Plus (Dataphysics®) equipped with a high speed and definition digital camera and the software SCA20® for automation and processing of the obtained images.

Surface tension was determined by the pendant droplet method, in which the image of the formed droplet at the tip of a syringe is captured by high speed and resolution CCD camera (30 frames per second) and sent for processing in equipment that analyzes the droplet format by axis asymmetry. The calculation of surface tension is based on the Yang-Laplace equation, considering the deformation of the droplets emitted at each sampling (Ferreira et al., 2013Ferreira MC, Lasmar O, Decaro Junior ST, Neves SS, Azevedo LH. Qualidade da aplicação de inseticida em amendoim (Arachis hypogaea L.), com e sem adjuvantes na calda, sob chuva simulada. Biosci J. 2013;29:1431-40.). The measurement of surface tension was performed for 60 s after droplet formation, considering moments 5, 15, and 30 s for assessment.

Contact angle was assessed on three different surfaces: two natural (adaxial and abaxial surface of S. obtusifolia leaves) and an artificial surface (parafilm: a resistant mixture of plastic paraffin with paper, waterproof, marketed as Parafilm M®). Plants of S. obtusifolia were cultivated in pots containing substrate composed of soil, sand, and animal manure (3:3:1) in a greenhouse for 60 days for leaf collection. Fully developed leaves were collected, and longitudinal rectangles of approximately 5 × 1 cm were sectioned. These sections were arranged horizontally on stretchers to reduce undulations that hamper contact angle readings. Images were assessed every second for one minute after the deposition of each droplet on the surfaces. The angle was assessed considering 5, 15, and 30 seconds after the droplet was deposited on the surface.

The results were submitted to analysis of variance by the F-test and treatment means were compared by the Tukey’s test (p>0.05) using the software Asistat 7.7 Beta® (Silva and Azevedo, 2016Silva FAS, Azevedo CAV. The Assistat software version 7.7 and its use in the analysis of experimental data. Afr J Agric Res. 2016;11(11):3733-40.).

RESULTS AND DISCUSSION

The study of characteristics of surface tension and contact angle as a function of the preparation sequence of the addition of herbicide and adjuvant to the spray solutions showed no differences for the variable surface tension. However, the contact angle showed significant differences, denoting the interference of preparation sequence on the spray solution characteristics and its interaction with the surfaces on which the droplets are deposited.

For surface tension, even in the absence of differences for the factor preparation sequence, differences were observed between treatments (herbicides and adjuvants) and between treatments and control (water) (Table 2). Despite the difference between adjuvants, the addition sequence of these products in the sprayer tank did not interfere with the surface tension when the used dose was 1 L ha-1 of herbicide.

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Table 2
Means of surface tension (mN m-1) of treatments at 5, 15, and 30 seconds after droplet formation, F-values, and coefficients of variation (CV%) for experiments I and II

The adjuvant composed of the mixture of phosphatidylcholine (lectin) and propionic acid (LEC) and that of mineral oil (MO) led to higher surface tension values (Table 2). The addition of MO resulted in a higher tension value at all times assessed in experiment I (1 L ha-1 of herbicide) and did not differ for LEC in experiment II (2 L ha-1 of aminopyralid + fluroxypyr). It was possibly due to the bi-fold dose of herbicide in the second experiment, which implied a higher amount of adjuvants in the spray solution since they already compose the herbicide formulation itself. Thus, MO addition in herbicide spray solutions may have reached the critical micelle concentration, not leading to a decrease in the contact angle since the increasing concentration of OM in phytosanitary spray solutions presents a limit of surface tension decrease (Decaro Júnior et al., 2015).

Regarding the organosiliconate adjuvant (SIL), lower surface tension values were verified at the three analyzed moments, as well as in both experiments (Table 2). Surface tension values for SIL lower than those of other adjuvants have been observed in other studies, corroborating the results found here (Iost and Raetano, 2010Iost CAR, Raetano CG. Tensão superficial dinâmica e ângulo de contato de soluções aquosas com surfactante em superfícies artificiais e naturais. Eng Agríc. 2010;30:670-80.). This lower value is due to the organosiliconate formulation, which, due to its high surfactant power, rapidly reduces the surface tension of aqueous solutions, overcoming the effects generated by hydrocarbon adjuvants (Prado et al., 2016Prado EP, Raetano C, Ferreira MH. Effects of agricultural spray adjuvants in surface tension reduction and spray retention on Eucalyptus leaves. Afr J Agric Res. 2016;11(40):3959-65.).

Water, a predominant component in the spray solution, has a high surface tension, which implies low spreading of droplets when deposited on the plant. It interferes with product efficacy since the area covered by droplets and the amount of liquid present directly affect the evaporation and absorption rates of the deposited spray solutions (Yu et al., 2009Yu Y, Zhu H, Ozkan HE. Evaporation of pesticide droplets on surfaces under various relative humidity conditions. J ASTM Int. 2009;6:1-8.; Decaro Junior et al., 2014Decaro Junior ST, Ferreira MC, Lasmar O, Campos HBN. Relationship among variables of sprays applied at reduced volumes in a coffee plantation. Asp Appl Biol. 2014;122:415-22.).

The presence of additives is frequent in formulations of agricultural pesticides, including surfactants with a high frequency and importance to reduce surface tension (Iost and Raetano, 2010Iost CAR, Raetano CG. Tensão superficial dinâmica e ângulo de contato de soluções aquosas com surfactante em superfícies artificiais e naturais. Eng Agríc. 2010;30:670-80.). Formulations influence development costs, manufacturing process, contents of commercial products, and application given their influence on leaf surface wetting, product retention on the treated surface, liquid absorption by leaf surface, and product activation to maintain the expected biological effect (Cunha and Alves, 2009Cunha JP, Alves GS. Características físico-químicas de soluções aquosas com adjuvantes de uso agrícola. Interciência. 2009;34(9)655-9.; Maciel et al., 2010Maciel CDG, Guerra N, Oliveira Neto AM, Poletine JP, Bastos SLW, Dias NMS. Tensão superficial estática de misturas em tanque de glyphosate + chlorimuron-ethyl isoladas ou associadas com adjuvantes. Planta Daninha. 2010;28(3):673-85.; Decaro Junior et al., 2015Decaro Junior ST, Ferreira MC, Lasmar O. Physical characteristics of oily spraying liquids and droplets formed on coffee leaves and glass surfaces. Eng Agríc. 2015;35:588-600.; Calore et al., 2015Calore RA, Ferreira MC, Galli JC. Efeitos de adjuvantes no controle de Enneothrips flavens Moulton,1941 (Thysanoptera: trypidae) na cultura do amendoim. Rev Bras Cienc Agr. 2015;10(1)74-81.). The better understanding of the effects of surface tension brings possibilities of a better use of adjuvants for pesticide formulation, prepared spray solutions, and applications directly in the field.

Regarding the contact angle (θo), the values found for the analyzed factors were lower than those of control in both experiments (I and II) on all surfaces (Table 3), which means that droplets formed from water spread less than those arising from phytosanitary spray solutions composed by adjuvants (Decaro Junior et al., 2015Decaro Junior ST, Ferreira MC, Lasmar O. Physical characteristics of oily spraying liquids and droplets formed on coffee leaves and glass surfaces. Eng Agríc. 2015;35:588-600.). The use of adjuvants in spray solutions increases the wetted area by the droplet on both sides of soybean leaves due to the effect of adjuvants on the interaction between the droplet and leaf surfaces (Gimenes et al., 2013Gimenes MJ, Zhu H, Raetano CG, Oliveira RB. Dispersion and evaporation of droplets amended with adjuvants on soybeans. Crop Prot. 2013;44:84-90.).

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Table 3
F-values and coefficients of variation (CV) applied to means of contact angle (θo) of treatments at 5, 15, and 30 seconds after droplet formation for the experiments I and II

The adjuvant SIL presented lower values of contact angle on all surfaces and in both doses. The organosiliconate adjuvant (SIL) is classified as a spreader-sticker, which, when associated with phytosanitary spray solutions, provides a higher contact of the droplet with the surface due to its surfactant action.

Surfactants added to the spray solution are often able to reduce surface tension as well as decrease the contact angle of droplets on hydrophobic surfaces (Decaro Júnior et al., 2014). The used organosiliconate adjuvant has a significant spreading effect, losing the droplet shape, with a complete, flat, and parallel spread with the surface (θo = 0), practically immediately after the droplets have been deposited on the leaf surface. In general, the decrease in surface tension of the spray liquid results in a reduction in droplet contact angles (Decaro Júnior et al., 2015).

Although a decrease in contact angle is desirable, droplets become more prone to evaporation before absorption occurs through the epicuticular leaf layer, resulting in possible loss of biological effect. Phytosanitary spray solutions characterized by lower surface tensions led to a larger wet area and increase in the evaporation rate (Cunha et al., 2016Cunha JPAR, Lasmar O, Ramos AMP, Alves GS. Evaporation time of droplets containing thiamethoxam and adjuvants sprayed on sugarcane leaves. Pesq Agropec Trop. 2016;46(1):1-8.).

In experiment I, an interaction was observed between the preparation sequence and adjuvants only for the abaxial surface of S. obtusifolia (Table 3). When analyzing the effect of adjuvants on preparation sequence (Table 4), the adjuvant LEC led to lower contact angle values when added after the herbicide at all analyzed times. The adjuvant LEC reduces the surface tension less when compared to the other assessed adjuvants.

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Table 4
Slicing of the significant interaction of contact angle (θo) of the abaxial surface of leaves of Senna obtusifolia for the factors preparation sequence and adjuvants at 5, 15, and 30 seconds after droplet formation with spray solutions at a dose of 1 L ha-1 of aminopyralid + fluroxypyr (experiment I)

The adjuvant MO presented lower contact angle values after 15 seconds of droplet deposit on the abaxial leaf surface when it was previously added to the herbicide. It means that the products tend to stabilize the spreading angle, with a more intense effect in the first seconds when the droplets are deposited, just as with surface tension. The addition of SIL led to a contact angle equal to zero degrees, which has also been observed in other studies (Iost and Raetano, 2010Iost CAR, Raetano CG. Tensão superficial dinâmica e ângulo de contato de soluções aquosas com surfactante em superfícies artificiais e naturais. Eng Agríc. 2010;30:670-80.). Therefore, the application of high volume pesticides associated with adjuvants that drastically reduce surface tension and hence contact angle should be carefully analyzed as it may cause an increase in production costs, draining losses, and environmental contamination (Prado et al., 2016Prado EP, Raetano C, Ferreira MH. Effects of agricultural spray adjuvants in surface tension reduction and spray retention on Eucalyptus leaves. Afr J Agric Res. 2016;11(40):3959-65.).

The adjuvants SIL and LEC provided a lower contact angle for the adaxial surface when the herbicide was added after the adjuvants (Table 5). It occurs because the siliconized adjuvant forms a lower contact angle at the highest concentration, while in the absence of this surfactant the angles are small in both surfaces (Tang et al., 2008Tang X, Dong J, Li X. A comparison of spreading behaviors of Silwet L-77 on dry and wet lotus leaves. J Colloid Inter Sci. 2008;325;223-7.). Droplet spreading on the artificial surface (parafilm) was similar to that observed on the adaxial leaf surface of S. obtusifolia (Table 6) since parafilm has a lipophilic characteristic (θo > 90o) that resembles the adaxial surface of the species used in the experiment (Kissmann, 1998Kismann KG. Adjuvantes para caldas de produtos fitossanitários. In: Guedes JVC, Dornelles SB. Tecnologia e segurança na aplicação de agrotóxicos: novas tecnologias. Santa Maria: Sociedade de Agronomia de Santa Maria; 1998. p.39-51. ; Iost and Raetano, 2010Iost CAR, Raetano CG. Tensão superficial dinâmica e ângulo de contato de soluções aquosas com surfactante em superfícies artificiais e naturais. Eng Agríc. 2010;30:670-80.).

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Table 5
Slicing of the significant interaction of contact angle (θo) of the adaxial surface of leaves of Senna obtusifolia for the factors preparation sequence and adjuvants at 5, 15, and 30 seconds after droplet formation with spray solutions at a dose of 2 L ha-1 of aminopyralid + fluroxypyr (experiment II)

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Table 6
Slicing of the significant interaction of contact angle (θo) of parafilm for the factors preparation sequence and adjuvants at 5, 15, and 30 seconds after droplet formation with spray solutions at a dose of 1 L ha-1 of aminopyralid + fluroxypyr (experiment I)

The surface of leaves of S. obtusifolia is composed of 93% of polar components on the epicuticular surface and a pH of 6.8, and the presence of non-polar compounds in spray solutions affects surface wetting (Kissmann, 1998Kismann KG. Adjuvantes para caldas de produtos fitossanitários. In: Guedes JVC, Dornelles SB. Tecnologia e segurança na aplicação de agrotóxicos: novas tecnologias. Santa Maria: Sociedade de Agronomia de Santa Maria; 1998. p.39-51. ). Droplets on hydrophilic surfaces have a larger coverage area and a shorter evaporation time than on hydrophobic surfaces (Yu et al., 2009Yu Y, Zhu H, Ozkan HE. Evaporation of pesticide droplets on surfaces under various relative humidity conditions. J ASTM Int. 2009;6:1-8.).

Mineral oil resulted in a higher spreading when added after the herbicide, with higher coverage for all analyzed surfaces (Table 7). However, mineral oil added to spray solutions reduces the evaporation rate on hydrophilic and hydrophobic artificial surfaces but increases it on lipophilic surfaces (Lasmar and Cunha, 2016Lasmar O, Cunha JPAR. Evaporation time of droplets containing thiamethoxam and adjuvants on hydrophilic, hydrophobic and lipophilic surfaces under different air relative humidities. Biosci J. 2016;32:108-14.).

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Table 7
Slicing of the significant interaction of contact angle (θo) of the abaxial surface of leaves of Senna obtusifolia for the factors preparation sequence and adjuvants at 5 and 15 seconds after droplet formation with spray solutions at a dose of 2 L ha-1 of aminopyralid + fluroxypyr (experiment II)

Most of the sprayed droplets come into contact with the adaxial leaf surface, where product absorption rate is higher. The reduced contact angle of droplets with the surface where they are deposited due to adjuvant addition leads to a higher spray solution spreading, providing a larger covered area and increasing the possibility of contact with the desired target or the possibility of product absorption by leaf surface (Cunha et al., 2016Cunha JPAR, Lasmar O, Ramos AMP, Alves GS. Evaporation time of droplets containing thiamethoxam and adjuvants sprayed on sugarcane leaves. Pesq Agropec Trop. 2016;46(1):1-8.).

Regarding the contact angle of experiment I, preparation sequence was different only on the abaxial leaf surface of S. obtusifolia, where fewer spray droplets are deposited in conventional applications. Moreover, an alteration was observed for experiment II, in which the adjuvants SIL and ECL showed a higher spreading when added before the herbicide. MO resulted in a higher spreading when added after the herbicide, with a larger surface coverage. The adaxial surface and parafilm had similar contact angle results.

Thus, spray solution preparation sequence did not interfere with the surface tension and contact angle for a dose of 1 L ha-1 of herbicide but interfered with for 2 L ha-1. Thus, adjuvant addition - SIL and LEC before the herbicide and MO after the herbicide - provides a higher spreading of spray solutions.

REFERENCES

Calore RA, Ferreira MC, Galli JC. Efeitos de adjuvantes no controle de Enneothrips flavens Moulton,1941 (Thysanoptera: trypidae) na cultura do amendoim. Rev Bras Cienc Agr. 2015;10(1)74-81.
Cessa RMA, Honaiser AC, Melo EP, Lima Junior IS. Dessecação de Brachiaria decumbens: ordem de preparo e constituintes da calda de pulverização. Rev Cienc Exatas Terra - UNIGRAN. 2013;2(1):33-40.
Cunha JP, Alves GS. Características físico-químicas de soluções aquosas com adjuvantes de uso agrícola. Interciência. 2009;34(9)655-9.
Cunha JPAR, Lasmar O, Ramos AMP, Alves GS. Evaporation time of droplets containing thiamethoxam and adjuvants sprayed on sugarcane leaves. Pesq Agropec Trop. 2016;46(1):1-8.
Cunha JPAR, Alves GS, Marques RS. Tensão superficial, potencial hidrogeniônico e condutividade elétrica de caldas de produtos fitossanitários e adjuvantes. Rev Cienc Agron. 2017;48(2):261-70.
Decaro Junior ST, Ferreira MC, Lasmar O, Campos HBN. Relationship among variables of sprays applied at reduced volumes in a coffee plantation. Asp Appl Biol. 2014;122:415-22.
Decaro Junior ST, Ferreira MC, Lasmar O. Physical characteristics of oily spraying liquids and droplets formed on coffee leaves and glass surfaces. Eng Agríc. 2015;35:588-600.
Decaro RA, Decaro Junior ST, Ferreira MC. Deposit of pesticides without and with adjuvants on citrus seedlings following different intervals of artificial rain. Cienc Rural. 2016;46(1)13-9.
Ferreira MC, Lasmar O, Decaro Junior ST, Neves SS, Azevedo LH. Qualidade da aplicação de inseticida em amendoim (Arachis hypogaea L.), com e sem adjuvantes na calda, sob chuva simulada. Biosci J. 2013;29:1431-40.
Gimenes MJ, Zhu H, Raetano CG, Oliveira RB. Dispersion and evaporation of droplets amended with adjuvants on soybeans. Crop Prot. 2013;44:84-90.
Iost CAR, Raetano CG. Tensão superficial dinâmica e ângulo de contato de soluções aquosas com surfactante em superfícies artificiais e naturais. Eng Agríc. 2010;30:670-80.
Kismann KG. Adjuvantes para caldas de produtos fitossanitários. In: Guedes JVC, Dornelles SB. Tecnologia e segurança na aplicação de agrotóxicos: novas tecnologias. Santa Maria: Sociedade de Agronomia de Santa Maria; 1998. p.39-51.
Lasmar O, Cunha JPAR. Evaporation time of droplets containing thiamethoxam and adjuvants on hydrophilic, hydrophobic and lipophilic surfaces under different air relative humidities. Biosci J. 2016;32:108-14.
Li J, Chen W, Xu Y, Wu X. Comparative effects of different types of tankmixed adjuvants on the efficacy, absorption and translocation of cyhalofop-butyl in barnyardgrass (Echinochloa crus-galli [L.] Beauv). Weed Biol Manage. 2016;16(2):80-9.
Maciel CDG, Guerra N, Oliveira Neto AM, Poletine JP, Bastos SLW, Dias NMS. Tensão superficial estática de misturas em tanque de glyphosate + chlorimuron-ethyl isoladas ou associadas com adjuvantes. Planta Daninha. 2010;28(3):673-85.
Oliveira RB, Antuniassi UR, Mota AAB, Chechetto RG. Potential of adjuvants to reduce drift in agricultural spraying. Eng Agric. 2013;33(5)986-92.
Prado EP, Raetano C, Ferreira MH. Effects of agricultural spray adjuvants in surface tension reduction and spray retention on Eucalyptus leaves. Afr J Agric Res. 2016;11(40):3959-65.
Silva FAS, Azevedo CAV. The Assistat software version 7.7 and its use in the analysis of experimental data. Afr J Agric Res. 2016;11(11):3733-40.
Silva FML, Velini ED, Corrêa TM. Influência dos íons Mg, Ca, Fe, Cu e Zn sobre a tensão superficial estática de soluções contendo surfatante. Planta Daninha. 2006;24(3):589-95.
Tang X, Dong J, Li X. A comparison of spreading behaviors of Silwet L-77 on dry and wet lotus leaves. J Colloid Inter Sci. 2008;325;223-7.
Yu Y, Zhu H, Ozkan HE. Evaporation of pesticide droplets on surfaces under various relative humidity conditions. J ASTM Int. 2009;6:1-8.

Publication Dates

Publication in this collection
09 Sept 2019
Date of issue
2019

History

Received
19 Sept 2017
Accepted
08 Mar 2018

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

[1] Calore RA, Ferreira MC, Galli JC. Efeitos de adjuvantes no controle de Enneothrips flavens Moulton,1941 (Thysanoptera: trypidae) na cultura do amendoim. Rev Bras Cienc Agr. 2015;10(1)74-81.

[2] Cessa RMA, Honaiser AC, Melo EP, Lima Junior IS. Dessecação de Brachiaria decumbens: ordem de preparo e constituintes da calda de pulverização. Rev Cienc Exatas Terra - UNIGRAN. 2013;2(1):33-40.

[3] Cunha JP, Alves GS. Características físico-químicas de soluções aquosas com adjuvantes de uso agrícola. Interciência. 2009;34(9)655-9.

[4] Cunha JPAR, Lasmar O, Ramos AMP, Alves GS. Evaporation time of droplets containing thiamethoxam and adjuvants sprayed on sugarcane leaves. Pesq Agropec Trop. 2016;46(1):1-8.

[5] Cunha JPAR, Alves GS, Marques RS. Tensão superficial, potencial hidrogeniônico e condutividade elétrica de caldas de produtos fitossanitários e adjuvantes. Rev Cienc Agron. 2017;48(2):261-70.

[6] Decaro Junior ST, Ferreira MC, Lasmar O, Campos HBN. Relationship among variables of sprays applied at reduced volumes in a coffee plantation. Asp Appl Biol. 2014;122:415-22.

[7] Decaro Junior ST, Ferreira MC, Lasmar O. Physical characteristics of oily spraying liquids and droplets formed on coffee leaves and glass surfaces. Eng Agríc. 2015;35:588-600.

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Treatment	Experiment I⁽¹⁾	Experiment II⁽²⁾
Treatment	Preparation sequence	Preparation sequence
1	Control	Control
2	HERB⁽³⁾ + MO⁽³⁾	HERB + MO
3	HERB + ³SIL	HERB + SIL
4	HERB + ³LEC	HERB + LEC
5	MO + HERB	MO + HERB
6	SIL + HERB	SIL + HERB
7	LEC + HERB	LEC + HERB

Factor	Variable	Surface tension (mN m^-1)
		Experiment I⁽¹⁾			Experiment II⁽²⁾
		5 s	15 s	30 s	5 s	15 s	30 s
Preparation sequence	Herb.⁽³⁾ + Adj.	30.95 a	30.57 a	30.27 a	29.55 a	28.63 a	28.19 a
Preparation sequence	Adj.⁽³⁾ + Herb.	30.18 a	29.85 a	29.60 a	29.45 a	28.99 a	28.85 a
LSD		1.59	1.52	1.52	0.80	0.96	1.08
Adjuvants	MO⁽³⁾	35.75 a	34.94 a	34.26 a	32.54 a	31.18 a	30.61 a
	SIL⁽³⁾	24.97 c	25.19 c	25.22 c	24.08 b	23.87 b	24.01 b
	LEC⁽³⁾	30.98 b	30.50 b	30.34 b	31.89 a	31.39 a	30.94 a
LSD		2.36	2.25	2.26	1.19	1.42	1.61
ANOVA
		Calculated F-values (Experiment I)			Calculated F-values (Experiment II)
Preparation sequence		1.02^ns	0.95^ns	0.84^ns	0.06^ns	0.61^ns	1.57^ns
Adjuvants		66.29**	59.35**	51.00**	197.03**	114.69**	74.55**
Preparation sequence vs. adjuvants		2.10^ns	1.88^ns	1.15^ns	2.24^ns	0.34^ns	0.25^ns
Treatments vs. control		1988.9**	2213.1**	2056.3**	8153.4**	5893.9**	4305.5**
CV (%)		5.07	4.88	4.96	2.63	3.19	3.66

Adaxial surface	Experiment I⁽¹⁾			Experiment II⁽²⁾
Adaxial surface	5 s	15 s	30 s	5 s	15 s	30 s
Preparation sequence	2.03^ns	0.67^ns	0.02^ns	16.41**	5.80*	7.38*
Adjuvants	499.82**	440.39**	298.04**	199.05**	175.99**	94.96**
Preparation sequence vs. adjuvants	2.32^ns	2.59^ns	3.23^ns	15.44**	10.33**	11.59**
Treatments vs. control	967.24**	1287.51**	1026.48**	81.06**	654.36**	448.18**
CV (%)	8.72	8.92	10.72	11.33	12.35	17.03
Abaxial surface
Preparation sequence	0.91^ns	0.02^ns	0.09^ns	0.62^ns	2.25^ns	2.17^ns
Adjuvants	235.01**	83.12**	149.71**	316.09**	319.78**	289.01**
Preparation sequence vs. adjuvants	8.17**	5.14*	5.90**	10.74**	4.44*	1.65^ns
Treatments vs. control	401.94**	241.77**	529.17**	638.29**	869.33**	1043.46**
CV (%)	12.82	20.37	14.9	10.20	10.48	10.64
Parafilm
Preparation sequence	0.00^ns	0.02^ns	0.07^ns	2.74^ns	14.46**	15.80**
Adjuvants	332.02**	239.67**	277.68**	41.15**	39.85**	48.41**
Preparation sequence vs. adjuvants	3.45^ns	2.02^ns	0.94^ns	10.80**	9.90**	12.47**
Treatments vs. control	1283.26**	1318.90**	1582.51**	799.85**	1208.72**	1324.64**
CV (%)	5.83	6.47	6.24	5.92	5.34	5.39

Preparation sequence	5 seconds			15 seconds			30 seconds
Preparation sequence	MO⁽¹⁾	SIL	LEC	MO	SIL	LEC	MO	SIL	LEC
Herb.⁽¹⁾ + adj.	83.49 aA	0.00 aC	63.16 bB	76.19 aA	0.00 aC	51.92 bB	70.11 aA	0.00 aC	45.99 bB
Adj.⁽¹⁾ + herb.	72.13 aA	0.00 aB	83.98 aA	56.80 bA	0.00 aB	69.11 aA	57.97 bA	0.00 aB	61.08 aA
LSD columns	11.97			16.78			11.67
LSD rows	14.39			20.34			14.15

Preparation sequence	5 seconds			15 seconds			30 seconds
Preparation sequence	MO⁽¹⁾	SIL	LEC	MO	SIL	LEC	MO	SIL	LEC
Herb.⁽¹⁾ + adj.	57.66 aB	16.39 aC	81.86 aA	53.13 bB	9.76 aC	72.27 aA	50.72 aA	4.60 aB	65.40 aA
Adj.⁽¹⁾ + herb.	67.26 aA	0.00 bB	55.56 bA	63.22 aA	0.00 aB	51.84 bA	58.85 aA	0.00 aC	33.92 bB
LSD columns	9.81			10.01			12.35
LSD rows	11.89			12.14			14.97

Brasil

Brasil

Effect of Pesticide Addition Sequence on the Preparation of Phytosanitary Spray Solutions

Efeito da Sequência de Adição de Agrotóxicos no Preparo de Caldas Fitossanitárias

ABSTRACT:

RESUMO:

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

REFERENCES

Publication Dates

History

Preparation sequence	5 seconds			15 seconds			30 seconds
Preparation sequence	MO⁽¹⁾	SIL	LEC	MO	SIL	LEC	MO	SIL	LEC
Herb.⁽¹⁾ + adj.	56.50 bB	50.89 aB	65.21 aA	54.82 aA	48.22 aB	58.28 aA	52.05 aA	45.29 aB	55.28 aA
Adj.⁽¹⁾ + herb.	64.02 aA	41.69 bB	59.13 bA	57.96 aA	38.04 bC	50.41 bB	55.69 aA	34.24 bC	47.74 bB
LSD columns	5.62			4.7			4.51
LSD rows	6.81			5.7			5.47