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http://dx.doi.org/10.5423/PPJ.2009.25.3.270

Reducing Fungicidal Spray Frequency for Major Apple Diseases by Increasing the Spray Interval from 15 to 25 days  

Lee, Dong-Hyuck (Apple Experiment Station, National Horticultural Research Institute)
Shin, Ho-Cheol (Central Research Institute, Kyung Nong Co. Ltd)
Cho, Rae-Hong (Crop Protection Research Team, AgroLife Research Institute)
Uhm, Jae-Youl (School of Applied Biology and Chemistry, Kyungpook National University)
Publication Information
The Plant Pathology Journal / v.25, no.3, 2009 , pp. 270-279 More about this Journal
Abstract
During the course of a study to develop a spraying program at 15-day spray intervals, two important findings were identified allowing for further reduction of spray frequency by increasing the spray interval. In evaluating the contribution of fungicides from a 15-day spray interval program, control of white rot, which is of prime importance in Korea, was not affected, in spite of the extended spray interval caused by omitting the fungicides during the season. In another experiment assessing the duration of the protective activities of several key fungicides used in the 15-day spray interval program, infection control was maintained for almost 30 days for some fungicide. Based on these two findings, a basic spraying program with a 25-day spray interval was developed. This program was modified for four successive years to improve the control efficacy against bitter rot and Marssonina blotch, which sometimes causes as much damage as white rot.
Keywords
bitter rot; apple white rot; fungicidal spraying program; spray frequency; Marssonina blotch;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
Times Cited By Web Of Science : 0  (Related Records In Web of Science)
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1 Kim, K. W., Park, E. W., Kim, Y. H., Ahn, K. K., Kim, P. G. and Kim, K. S. 2001. Latency-and defense-related ultrastructural characteristics of apple fruit tissues infected with Botryosphaeria dothidea. Phytopathology 91:165-172   DOI   ScienceOn
2 Kohn, F. C. Jr. and Hendrix, F. F. 1983. Influence of sugar content and pH on development of white rot on apples. Plant Dis. 67:410-412   DOI
3 Korea Crop Protection Association. 2005. Pesticide guidebook
4 Harada, Y., Sawamura, K. and Kono, K. 1974. Diplocarpon mali sp. Nov., the perfect state of apple blotch ftmgus Marssonina coronaria. Ann. Phytopathol. Soc. Jpn. 40:412-418   DOI
5 Lee. D. H., Choi, K. H., Lee, S. W. and Kim, D. A. 2008. Recent status of apple diseases in the major apple producing areas in Korea. In: Report of Horticultural Research in 2008, p. 827-828. Apple Experiment Institute, RDA, Korea
6 Lee, D. H., Kim, D. H., Woo, H. and Uhm, J. Y. 2007. After-infection activities of protective ftmgicides against apple white rot. Plant Pathol. J. 23:166-173   DOI   ScienceOn
7 Hayashi, S. 1984. Epidemiology and control of apple ring rot. Plant Protection 38:553-556 (in Japanese)
8 Kim, D. H. and Uhm, J. Y. 2002. Effect of application timing of ergosterol biosynthesis-inhibiting ftmgicides on the suppression of disease and latent infection of apple white rot caused by Botryosphaeria dothidea. J. Gen. Plant Pathol. 68:237-245   DOI   ScienceOn
9 Lee, D. H., Lee, S. W., Choi, K. H., Kim, D. A. and Uhm, J. Y. 2006. Survey on the occurrence of apple diseases in Korea from 1992 to 2000. Plant Pathol. J. 22:375-380
10 Uhm, J. Y. 1998. Current practice of chemical control against apple diseases and its improvement in Korea. In: Proceedings of the International Symposium on Recent Technology of Chemical Control of Plant Diseases, pp. 19-49. Korean Society of Plant Pathology, Daegu, Korea
11 Ogata, T. 1997. Environmental and cultural factors affecting the occurrence cycle of Botryosphaeria fruit rot of apple, and its control measures. Plant Prot. 51:11-14 (in Japanese)