Strawberry (Fragaria X ananassa Duch.) yiel das affected by the soil pH

Milosevic, Tomo M.; Milosevic, Nebojsa T.; Glisic, Ivan P.

doi:10.1590/S0001-37652009000200012

Abstracts

Two-year trials (20062007) suggested that the use of calcium oxide (CaO) on acid soils increased soil pH and yields in strawberry cultivars Marmolada, Selena and Senga Sengana, under the environmental conditions of Cacak (Western Serbia). The highest yield was obtained when CaO was applied at 750 kg ha-1 rate. Further increase in rate up to 1,500 kg ha-1 did not show corresponding increase in yield; the result was a slight yield drop compared to the peak yield shown at 750 kg ha¹ rate. Overall, yields at rates above 750 kg ha¹ were still higher than control and in the treatment employing lowest CaO application rate of 250 kg ha-1.

acid soils; CaO; pH; strawberry; yield

Dois anos de ensaios (2006-2007) sugeriram que o uso deóxido cálcio (CaO) em solos ácidos aumentou o pH do soloe o rendimento das cultivares de morango, Marmolada, Selena e Senga Sengana, sob as condições ambientais de Cacak (oeste da Sérvia). O rendimento mais elevado foi obtido quando CaO foi aplicado na quantidade de 750 kg ha-1. O aumento da quantidade para nível até 1500 kg ha-1 não mostrouaumento correspondente do rendimento; o resultado foi umaligeira queda em comparação com o rendimento máximo obtidoa 750 kg ha¹. Globalmente, os resultados a taxas superiores a 750 kg ha¹ foram ainda mais elevados do que no controle e no tratamento empregando quantidade mais baixa de 250 kg ha-1 de CaO.

solos ácidos; CaO; pH; morango; produtividade

AGRARIAN SCIENCES

Strawberry (Fragaria X ananassa Duch.) yiel das affected by the soil pH

Tomo M. Milosevic^I; Nebojsa T. Milosevic^II; Ivan P. Glisic^I

^IFaculty of Agronomy, Department of Horticulture, 32000 Cacak, Cara Dusana 34, Serbia

^IIFruit Research Institute, Department of Fruit Growing, 32000 Cacak, Kralja Petra I/9, Serbia

^{Correspondence to} Correspondence to: Tomo M. Milosevic E-mail: tomom@tfc.kg.ac.rs

ABSTRACT

Two-year trials (20062007) suggested that the use of calcium oxide (CaO) on acid soils increased soil pH and yields in strawberry cultivars Marmolada, Selena and Senga Sengana, under the environmental conditions of Cacak (Western Serbia). The highest yield was obtained when CaO was applied at 750 kg ha^-1rate. Further increase in rate up to 1,500 kg ha^-1did not show corresponding increase in yield; the result was a slight yield drop compared to the peak yield shown at 750 kg ha¹rate. Overall, yields at rates above 750 kg ha¹were still higher than control and in the treatment employing lowest CaO application rate of 250 kg ha^-1.

Key words: acid soils, CaO, pH, strawberry, yield.

RESUMO

Dois anos de ensaios (2006-2007) sugeriram que o uso deóxido cálcio (CaO) em solos ácidos aumentou o pH do soloe o rendimento das cultivares de morango, Marmolada, Selena e Senga Sengana, sob as condições ambientais de Cacak (oeste da Sérvia). O rendimento mais elevado foi obtido quando CaO foi aplicado na quantidade de 750 kg ha^-1. O aumento da quantidade para nível até 1500 kg ha^-1não mostrouaumento correspondente do rendimento; o resultado foi umaligeira queda em comparação com o rendimento máximo obtidoa 750 kg ha¹. Globalmente, os resultados a taxas superiores a 750 kg ha¹foram ainda mais elevados do que no controle e no tratamento empregando quantidade mais baixa de 250 kg ha^-1de CaO.

Palavras-chave: solos ácidos, CaO, pH, morango, produtividade.

INTRODUCTION

In Republic of Serbia, strawberries are being cultivated on soils with pH ranging between 4 and 8. Milosevic (1997) shows that acid soils with pH 4.0 are less suitable for strawberry production than alkaline soils with pH 8.0. In these extreme soil pH values strawberry production, yield potential and fruit quality are seriously compromised. According to Milosevic (1997) optimum soil pH for strawberry cultivation ranges from 4.6-6.5. A highly marked increase in substitutional acidity is being exhibited in 22% of soils in Serbia, and 56% of soils have pH values consistent with acid reaction. As reported by Cakmak (2002), 60% of world soils exert limiting effects on food production due to their degradation, micronutrient deficiencies and toxicity traits.

The subject matter of this study is strawberry cultivation on acid soils subjected to treatments aimed at acidity reduction i.e. increasing pH values by CaO applications to the soil. A great number of authors (Gray et al. 1999, Burelle 2003) have studied the effect of soil as a primary substrate on vegetative growth, reproductive cycle, strawberry yield, accumulation of certain elements, particularly heavy metals (Cd), in the roots, leaves and fruits.

The objective of the study was to determine the most favourable CaO rate that would bring soil pH to the level that would insure highest possible yields per unit area.

Several authors (Makus and Morris 1989, Cheour et al. 1990, 1991, Na Phun et al. 1995, 1997, Wojcik and Lewandowski 2003, Lanauskas et al. 2006) have reported seeing positive effects of soil and/or foliar-applied calcium-containing compounds on yield and fruit quality in strawberries as well as on soil pH increase (Takeda 1999, Lacertosa et al. 1999, Niskanen and Dris 2002). Cieslinski et al. (2004) showed that increased soil pH has positive effect on growth and yield in certain strawberry cultivars.

MATERIALS AND METHODS

Trials were conducted in 2006 and 2007 in a strawberry planting at Prislonica situated 15 km northeast of Cacak (43º53^'N; 20º21^'E), Western Serbia at an altitude of 530 m. The research material included most commonly grown strawberry cultivars Marmolada, Selena and Senga Sengana. The cultivars were grown as "frigo" seedlings planted at the beginning of August in 2005 and in 2006 in simple rows at 80 X 25 cm spacing (50,000 seedlings per hectare). The flowers were cut back in autumn.

The trial was set up as a randomised block design in four replications for a single treatment, with each replication including a control. The experimental plot was 10 m². Adjoining plots were separated with 1 mwide insulating tape.

In October of 2005 and 2006 CaO was broadcasted by hand immediately incorporated into the soil. CaO treatments were as follows:

A ₁ = 0 (control), A ₂ = 250, A ₃ = 500, A ₄ = 750, A ₅ = 1, 000, A ₆ = 1, 250 and A ₇ = 1, 500 kg ha¹.

In March of 2006 and 2007, 500 kg of NPK (10:12:26), and 150 kg lime ammonium nitrate (27%) per hectare were incorporated into the soil. Provided plant care was in accordance with the modern strawberry production technology. Soil analysis was done prior to strawberry planting and after the harvest. A Pye glass electrode pH-meter-potentiometer (W.G. Pye, Cambridge) was used to measure the pH value in 0.01 M KCl.

Experimental data were subjected to analysis of variance. For mean separation a Dunett's test at P < 0.05 and P < 0.01 was used. the data were analyzed by the anova statistical program, origin, version 7.5. Correlation and regression analysis and analysis of the variance of regression at P < 0.05 and P < 0.01 were employed to determine correlation and interaction between the cao application rate and soil ph change (mead et al. 1996).

WEATHER AND SOIL CHARACTERISTICS

Climate conditions during the examination were not significantly different from the longterm averages. In 2006, the average annual temperature was 9.1ºC, and the average temperature for the growing season was 15.3ºC. The total annual and total growing season precipitations were 561.9 mm m^-2and 343.9 mm m^-2, respectively. In 2007, the average annual temperature was 11.6º and the average temperature for the growing season was 18.0ºC. The total annual and growingseason rainfalls were 505.4 mm m^-2and 205.0 mm m², respectively.

The planting was established on brown forest soil developed from schist. Prior to establishing the trial planting and calciumoxide treatments, soil was showing a highly acid reaction (pH 4.12). Soil analysis reviled following nutrient levels: 2.14% humus, 0.14% total nitrogen, 50 mg kg^-1P₂O₅ and 110 mg kg^-1K₂O at a depth of 0-40 cm.

RESULTS

Our results indicate that the soil acidity (pH) is affected by the CaO application rate as shown in Table I.

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The data analysis showed that high CaO application rates resulted in decreasing soil acidity showing higher pH values as expressed in absolute and relative amounts. The maximum CaO application rate of 1,500 kg ha^-1 raised pH readings for 2.10-unit or 33.76% compared to the control. This is also confirmed by the linear regression curve (Fig. 1) with a shape Y = 3.85+0.37x and a very high correlation (r= 0.959) coefficient. The regression variance analysis detected statistically significant differences between the soil pH obtained by increasing CaO rates and the control (P < 0.05).

The trial results presented in Table II and Figure 2 show that the use of CaO for raising the soil pH had positive effect on strawberry yields. The yields obtained in all the treatments were higher than those in the control. The highest yield in all cultivars examined was obtained in the trial plot where 750 kg ha^-1CaO (A4) was applied. At this rate there was an increase in pH from 4.12 (the control) to 5.75, as well as the increase in yield of 124.63%. Data in Table III show strawberry yields obtained in the control (A₁), being 10.60 t ha¹ in Marmolada, 9.65 t ha^-1in Selena and 8.50 t ha^-1in Senga Sengana cultivars. With the highes-tyielding A₄treatment, the yield varied from 19.70 t ha¹(Senga Sengana), 21.75 t ha¹(Selena), and 23.12 t ha¹(Marmolada). Compared to control the highest yield increasewas recorded in Senga Sengana (131.76%), followed by Selena (125.36% and Marmolada (118.11%).

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The analysis of variance and the Dunett's test showed statistically significant (P < 0.01) increase in maximum yields compared to control with the CaO application rate of 750 kg ha^-1.

DISCUSSION

This study supports data cited in literature (Milosevic 1997, Niskanen and Dris 2002) that the most favourable pH for t strawberry production is between 4.6 and 6.5. Similar data were reported by Cieslinski et al. (2004) who determined that pH 5.1 and pH 6.8 had different effects on plant development and strawberry yield - better tiller development and higher yield at higher soil pH in strawberry cultivars (Rainier, Totem and Selva) grown under greenhouse conditions in Parkhill sandy loam soil.

Further CaO application rate increase exceeding 750 kg ha^-1 resulted in a gradual yield decrease. The observation can serve as an important indicator in strawberry production on acid soils. Importantly, the yield evidently decreased with respect to the 750 kg ha^-1 CaO application rate (A₄) but increased as compared to the control (A₁) and the lowest rate treatment (250 kg ha^-1 CaO). Lanauskas et al. (2006) determined that 150 kg ha-1 Ca(NO₃)₂ applied to the soil were not sufficient to justifiably increase the yield and fruit weight of the Honeoye strawberry cultivar as compared to the control (without fertilisation) on the soil with the pH of 7.1. According to Brocic (1997) 4,000 kg ha-1 CaO are required to decrease acidity by 0.7 pH units on pseudogley, being eight times the rates applied in this study which caused similar changes in pH. The differences are likely to be due to soil types, as the soil in our study is brown forest soil developed from schist, that is far more fertile and richer in organic and mineral matter than pseudogley soil. The climatic conditions in the research years were nearly identical thus they could not have markedly affected studied parameters.

Strawberry cultivars in all treatments received identical nutritional regime involving the applications of NPK(10:12:26) at the rate of 500 kg ha^-1, and 150 kg ha^-1 lime ammonium nitrate therefore nutrient management was not responsible for the yield increases. The yield increase as induced by the use of different CaO rates on acid soils may be attributed to the effect of soil pH and Ca²⁺ ions on the mobilisation and uptake of certain ions from the soil by the strawberry root system.

CONCLUSION

The obtained results from the study on the effects of increasing CaO rates on soil pH change and strawberry yield may suggest the following conclusions: the use of CaO on acid soil increased soil pH and yieldincreases in Marmolada, Selena and Senga Sengana strawberry cultivars in all treatments applied. The highest yield was recorded with the 750 kg ha¹CaO application rate, with pH of 5.75. The increase in CaO rates above 750 kg ha¹did not bring corresponding increase in strawberry yield while showing slight decreasing tendency with respect to the rate mentioned. Overall atCaO rates above 750 kg ha¹yield was higher than in the control (0 kg ha¹) and the treatment employing thelo west application rate (250 kg ha¹).

Manuscript received on June 5, 2008; accepted for publication on September 16, 2008;presented by ELIBIO L. RECH

BROCIC Z. 1997. Effect of lime, organic and mineral fertilizers on pseudogley chemical changes on maize yield in Dragacevo. In: 50 years Institute for Maize, Proceedings, Zemun Polje, Serbia, p. 157-166 (in Serbian).
BURELLE NK. 2003. Effects of transplant type and soil fumigant on growth and yield of strawberry in Florida. Plant Soil J 256: 273-280.
CAKMAK I. 2002. Plant nutrition research: Priorities to meet human needs for food in sustainable ways. Plant and Soil 247: 3-24.
CHEOUR F, WILLEMOT C, ARUL J, MAKHLOUF J, CHAREST M AND GOSSELIN A. 1990. Foliar application of calcium chloride delays postharvest ripening of strawberry. J Amer Soc Hort Sci 115: 789-792.
CHEOUR F, WILLEMOT C, ARUL J, MAKHLOUF J AND DESJARDINS Y. 1991. Postharvest rasponse of two strawberry cultivars to foliar application CaCl2. Hort Sci 26: 1186-1188.
CIESLINSKI G, NEILSEN GH AND HOGUE EJ. 2004. Effect of soil cadmium application and pH on growth and cadmium accumulation in roots, leaves and fruit of strawberry plants (Fragaria X ananassa Duch.). Plant and Soil 180: 267-276.
GRAY CW, MCLAREN RG, ROBERTS, AHC AND CONDRON LM. 1999. Effect of soil pH on cadmium phytoavailability in some New Zealand soils. N Zealand J Crop Hort Sci 27: 169-179.
LACERTOSA G, LATEANA V, MONTENURRO D, PALAZZO D AND VANADIA S. 1999. Soil fertility and plant nutritional status of strawbery in the Basilicata Region, Southern Italy. In: Improved Crop Quality by Nutrient Management. 86: 159-162.
LANAUSKAS J, USELIS N, VALIUSKAITE A AND VISKELIS P. 2006. Effect of foliar and soil applied fertilizers on strawberry healthiness, yield and berry quality. Agr Res 4 (Special issue), p. 247-250.
MAKUS J AND MORRIS R. 1989. Influence of soil and foliarapplied calcium on strawberry fruit nutrient and postharwest quality. Acta Hort 265: 443-446.
MEAD R, CORNOW RN AND HASTED AM. 1996. Statistical methods in agriculture and experimental biology. Chapman & Hall, London.
MILOSEVIC T. 1997. Special Topics in Fruit Growing. Faculty of Agronomy & Community for Fruits and Vegetables, CacakBelgrade, p. 353-384 (in Serbian).
NA PHUN W, KAWADA K AND KUSUNOKI M. 1995. Effect of postharvest calcium application on postharvest quality of Nyoho strawberries. J Japan Soc Hort Sci 2: 638-639.
NA PHUN W, KAWADA K AND KUSUNOKI M. 1997. Effect of spray timing, spray part and calcium formula on the effectiveness of calcium spray on Nyoho strawberries. J Japan Soc Hort Sci 2: 70-71.
NISKANEN R AND DRIS R. 2002. Nutritional status of strawberry fields. Acta Hort 2: 439-442.
TAKEDA F. 1999. Strawberry production in soil less culture system. Acta Hort 481: 289-296.
WOJCIK P AND LEWANDOWSKI M. 2003. Effect of calcium and boron sprays on yield and quality of Elsanta strawberry. J Plant Nutr 3: 671-682.

Correspondence to:

Tomo M. Milosevic

E-mail:

tomom@tfc.kg.ac.rs

Publication Dates

Publication in this collection
26 May 2009
Date of issue
June 2009

History

Accepted
16 Sept 2008
Received
05 June 2008

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] BROCIC Z. 1997. Effect of lime, organic and mineral fertilizers on pseudogley chemical changes on maize yield in Dragacevo. In: 50 years Institute for Maize, Proceedings, Zemun Polje, Serbia, p. 157-166 (in Serbian).

[2] BURELLE NK. 2003. Effects of transplant type and soil fumigant on growth and yield of strawberry in Florida. Plant Soil J 256: 273-280.

[3] CAKMAK I. 2002. Plant nutrition research: Priorities to meet human needs for food in sustainable ways. Plant and Soil 247: 3-24.

[4] CHEOUR F, WILLEMOT C, ARUL J, MAKHLOUF J, CHAREST M AND GOSSELIN A. 1990. Foliar application of calcium chloride delays postharvest ripening of strawberry. J Amer Soc Hort Sci 115: 789-792.

[5] CHEOUR F, WILLEMOT C, ARUL J, MAKHLOUF J AND DESJARDINS Y. 1991. Postharvest rasponse of two strawberry cultivars to foliar application CaCl2. Hort Sci 26: 1186-1188.

[6] CIESLINSKI G, NEILSEN GH AND HOGUE EJ. 2004. Effect of soil cadmium application and pH on growth and cadmium accumulation in roots, leaves and fruit of strawberry plants (Fragaria X ananassa Duch.). Plant and Soil 180: 267-276.

[7] GRAY CW, MCLAREN RG, ROBERTS, AHC AND CONDRON LM. 1999. Effect of soil pH on cadmium phytoavailability in some New Zealand soils. N Zealand J Crop Hort Sci 27: 169-179.

[8] LACERTOSA G, LATEANA V, MONTENURRO D, PALAZZO D AND VANADIA S. 1999. Soil fertility and plant nutritional status of strawbery in the Basilicata Region, Southern Italy. In: Improved Crop Quality by Nutrient Management. 86: 159-162.

[9] LANAUSKAS J, USELIS N, VALIUSKAITE A AND VISKELIS P. 2006. Effect of foliar and soil applied fertilizers on strawberry healthiness, yield and berry quality. Agr Res 4 (Special issue), p. 247-250.

[10] MAKUS J AND MORRIS R. 1989. Influence of soil and foliarapplied calcium on strawberry fruit nutrient and postharwest quality. Acta Hort 265: 443-446.

[11] MEAD R, CORNOW RN AND HASTED AM. 1996. Statistical methods in agriculture and experimental biology. Chapman & Hall, London.

[12] MILOSEVIC T. 1997. Special Topics in Fruit Growing. Faculty of Agronomy & Community for Fruits and Vegetables, CacakBelgrade, p. 353-384 (in Serbian).

[13] NA PHUN W, KAWADA K AND KUSUNOKI M. 1995. Effect of postharvest calcium application on postharvest quality of Nyoho strawberries. J Japan Soc Hort Sci 2: 638-639.

[14] NA PHUN W, KAWADA K AND KUSUNOKI M. 1997. Effect of spray timing, spray part and calcium formula on the effectiveness of calcium spray on Nyoho strawberries. J Japan Soc Hort Sci 2: 70-71.

[15] NISKANEN R AND DRIS R. 2002. Nutritional status of strawberry fields. Acta Hort 2: 439-442.

[16] TAKEDA F. 1999. Strawberry production in soil less culture system. Acta Hort 481: 289-296.

[17] WOJCIK P AND LEWANDOWSKI M. 2003. Effect of calcium and boron sprays on yield and quality of Elsanta strawberry. J Plant Nutr 3: 671-682.

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