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RESEARCH ARTICLE
Contents Vol 46(1)

Quality of fresh and dried fruit of apricot (cv. Moorpark) in response to soil-applied nitrogen

M. A. Rettke A D , T. R. Pitt B , N. A. Maier A and J. A. Jones C
+ Author Affiliations
- Author Affiliations

A South Australian Research and Development Institute, Plant Research Centre, GPO Box 397, Adelaide, SA 5001, Australia.

B South Australian Research and Development Institute, Loxton Centre, Box 411, Loxton, SA 5333, Australia.

C BiometricsSA, South Australian Research and Development Institute, The University of Adelaide, GPO Box 397, Adelaide, SA 5001, Australia.

D Corresponding author. Email: rettke.michael@saugov.sa.gov.au

Australian Journal of Experimental Agriculture 46(1) 123-129 https://doi.org/10.1071/EA04211
Submitted: 13 October 2004  Accepted: 19 July 2005   Published: 9 February 2006

Abstract

The effects of soil applications of nitrogen on the quality of fresh and dried fruit from 12-year-old apricot Prunus armeniaca cultivar Moorpark trees growing on an orthic Tenosol in the Riverland region of South Australia were studied over 3 years. The experiment was set up in a randomised complete block design with 6 annual rates of nitrogen (0, 250, 500, 750, 1000 and 1250 g/tree.year) applied in the form of ammonium nitrate. Application was split into 30% at budburst, 30% six weeks after budburst and 40% after harvest. Firmness of fruit was significantly reduced as the rate of applied nitrogen increased. The flesh of individual fruits ripened more evenly when 0 or 250 g nitrogen/tree.year was applied, compared with rates in the range 500–1250 g nitrogen/tree.year. Application of nitrogen significantly increased the pH of fruit. The total soluble solids level of fruit from trees that received 0 or 250 g nitrogen/tree.year, was significantly lower than from trees that received 750 or 1250, but not 1000 g nitrogen/tree.year. Application of nitrogen did not significantly affect the concentration of sulfur dioxide in fresh fruit measured after sulfuring, but the concentration of sulfur dioxide in fruit at the completion of drying was significantly increased. The application of nitrogen did not affect the drying ratio of fruit. Nitrogen application increased the rate of darkening of dried apricots in storage in each of the three years. Relationships were found between time taken for dried apricots to darken to an unacceptable level and nitrogen concentration in harvested fruit. It is suggested that to assist in the management of darkening of dried apricots in storage, annual nitrogen application rates on an orthic Tenosol need to be below 500 g/tree.year and ideally below 250 g/tree.year.


Acknowledgments

We thank the Dried Fruits Research and Development Council for financial assistance that enabled this work. Thanks goes to Maria Nechvoglod and Sue Haywood for assistance in carrying out the experiment. Appreciation is expressed to Angas Park Fruit Co. Pty Ltd for provision of the experimental site and particularly Mr Bill Berends for his cooperation in accommodating our experimental requirements and for providing the day-to-day management of the orchard.


References


Bulow G (1980) Apricot varieties. Queensland Agricultural Journal 106, 29–30. open url image1

Bussi C, Amiot MJ (1998) Effects of nitrogen and potassium fertilization on the growth, yield and pitburn of apricot (cv. Bergeron). The Journal of Horticultural Science & Biotechnology 73, 387–392. open url image1

Dahlenburg AP, Glenn T, Hill JFW (1986) Sulfur dioxide measurement techniques for dried fruits. Department of Agriculture, Report No. E/4/86, Adelaide.

Dimitrovski T, Cevetkovic D (1981) The effect of NPK on the growth, yield and quality of the apricot fruit. Acta Horticulturae 85, 481–489. open url image1

El-Sayed AS, Luh BS (1967) Amino acids and quality of canned apricots as affected by nitrogen fertilisation. Food Technology 21, 416–420. open url image1

Isbell RF (1996) ‘The Australian soil classification.’ (CSIRO Publishing: Melbourne)

Kotze WAG, de Villiers J (1991) Uptake of 15N labelled ammonium and nitrate by apple, apricot and nectarine trees. Journal of the Southern African Society for Horticultural Science 1, 89–91. open url image1

Rettke MA (1993) Predicting the storage life of dried apricots. Australian Dried Fruit News 21, 5. open url image1

Rettke MA, Maier NA, Dahlenburg AP, Partington DL (2001) Relationships between darkening of dried apricots and nutrient concentrations in fresh fruit and mid-shoot leaves. Australian Journal of Experimental Agriculture 41, 573–577.
Crossref | GoogleScholarGoogle Scholar | open url image1

Rettke MA, Pitt TR , Maier NA, Jones JA (2006) Growth and yield responses of apricot (cv. Moorpark) to soil applied nitrogen. Australian Journal of Experimental Agriculture 46, 115–122. open url image1

Rossello C, Mulet A, Simal S, Torres A, Canellas J (1994) Quality of dried apricots; effect of storage temperature, light and SO2 content. Journal of the Science of Food and Agriculture 65, 121–124. open url image1

Stadtman ER, Barker HA, Mrak EM, Mackinney G (1946) Storage of dried fruit; influence of moisture and sulfur dioxide on deterioration of apricots. Industrial and Engineering Chemistry 38, 99–104.
Crossref | GoogleScholarGoogle Scholar | open url image1

Stafford AE, Bolin HR, Mackey BE (1972) Absorbtion of aqueous bisulfite by apricots. Journal of Food Science 37, 941–943. open url image1

Wetherilt H, Pala M, Basoglu N (1993) Relationship between sulfur dioxide level and inhibition of browning in apricots dried to different moisture levels. In ‘Developments in food science’. (Ed. G Charalambous) pp. 381–388. (Elsevier: Amsterdam)