Canan Nilay DURAN
(Akdeniz Üniversitesi, Fen Bilimleri Enstitüsü, Bahçe Bitkileri Bölümü, 07070 Konyaaltı / Antalya, Türkiye)
(Akdeniz Üniversites, Fen Bilimleri Enstitüsü, Bahçe Bitkileri Bölümü, 07070 Konyaaltı / Antalya, Türkiye)
Sevinç ŞENER
(Akdeniz Üniversitesi, Ziraat Fakültesi, Bahçe Bitkileri Bölümü, 07070 Konyaaltı / Antalya, Türkiye)
Yıl: 2020Cilt: 8Sayı: 2ISSN: 2148-127X / 2148-127XSayfa Aralığı: 421 - 425Türkçe

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Effects of Various Bioactivator Applications on Sapling Development of Passionflower and Guava Plantles
Passionflower is a member of Passifloraceae family, it can be used as medicinal and ornamental plants in addition to its consumption as fruit in the world. Guava (Psidium guajava L.) fruits, which has a rich nutrient content, are consumed both fresh and processed. Passionfruit and guava plants, which can only be cultivated in temperate southern coasts in our country, have gained commercial importance because of the fruits' export potential, high medical importance and nutrient. This study was carried out to determine the effects of some bioactivator applications on the criteria of sapling growth and development of passionflower and guava plants. The experiment was conducted between 2018-2019 under greenhouse conditions. Saplings obtained from seed germination in Akdeniz University Faculty of Agriculture Research and Experiment Area were used as plant material. 3 different commercial preparations called Messenger, Crop-set and ISR-2000 were used as bioactivators. Plant height (cm), stem diameter (mm) and number of leaves (number / plant) were measured weekly, in order to determine the effect of the applications on the growth and development of saplings. At the end of the study, it was determined that the highest average plant height (10.17 cm), stem diameter (13.53 mm) were obtained in ISR-2000 application. The highest average plant height (11.93 cm), stem diameter (16.44 mm) and number of leaves (9.07 units / plant) were obtained from Messenger application in guava plant. When the results obtained are evaluated, it is recommended that ISR-2000 bioactivator can be applied in passionflower sapling cultivation and Messenger bioactivator can be applied for guava sapling cultivation
DergiAraştırma MakalesiErişime Açık
  • Alessandra B, Lorenzo C,·Luca P,·Tullia GT,· Flavia G, Stefania C, Andrea MM, Filippo A, Marisa L. 2006. Phenol conten related to antioxidant and antimicrobial activities of Passiflora spp.extracts. Europ. Food Res. Technol. 223: 102 - 109.
  • de Melo Filho JS, Véras M, Leno M, da Silva TI, de Sousa Alves L, Dias TJ. 2018. Organic fertilizers as mitigating effects of water salinity on Passiflora cincinnata seedlings. Acta Agronómica, 67(4): 501-511.
  • De Wilde WJJO. 1972. The indigenous old world passifloras. Blumea, 20(1): 227-250.
  • Dheir I, Abu-Naser SS. 2019. Knowledge Based System for Diagnosing Guava Problems. International Journal of Academic Information Systems Research (IJAISR), 3(3): 9-15.
  • FAO. 2019. (Erişim Tarihi: 12.10.2019). Gurung N, Swamy GSK, Sarkar SK, Ubale NB. 2014. Effect of chemicals and growth regulators on germination, vigour and growth of passion fruit (Passiflora edulis Sims.). The Bioscan, 9(1): 155-157.
  • Gülgün B, Türkyılmaz B, Yıldırım T, Güney A. 2003. Ekonomik Öneme Sahip Bazı Sarılıcı Süs Bitkilerinden “Passiflora caerulea”, “Plumbago capensis”, “Wisteria chinensis” Çeliklerinin Farklı Dikim Zamanlarının Köklenme Oranlarına Etkileri. Ege Üniversitesi Ziraat Fakültesi Dergisi, 40(1).
  • Killip EP. 1960. Supplemental notes on the American species of Passifloraceae with descriptions of new species. Systematic Plant Studies.
  • Lim TK. 2012. Passiflora edulis. In Edible Medicinal And NonMedicinal Plants (pp. 147-165). Springer, Dordrecht.
  • Miyake RTM, Takata WHS, Guerra WEX, Forli F, Narita N, Creste JE. 2016. Effects of potassium fertilization and commercial substrates on development of passion fruit seedlings under greenhouse condition. African Journal of Agricultural Research, 11(39): 3720-3727.
  • Nobre RG, Gheyi HR, Correia KG, Soares FAL, de Andrade LO. 2010. Crescimento e floração do girassol sob estresse salino e adubação nitrogenada. Revista Ciência Agronômica, 41(3): 358-365.
  • Phamiwon ZAS, John S. 2015. Diabetes and medicinal benefits of Passiflora edulis. World Journal of Pharmaceutical Research, 5(3): 453-65.
  • Qwaider SR, Abu Naser SS. 2017. Expert System for Diagnosing Ankle Diseases. International Journal of Engineering and Information Systems (IJEAIS), 1(4): 89-101.
  • Santos JL, Matsumoto SN, D'arede LO, Luz ISD, Viana AES. 2012. Vegetative propagation of cuttings of Passiflora cincinnata mast. in different commercial substrates and containers. Revista Brasileira de Fruticultura, 34(2): 581-588.
  • Silva EAD, Maruyama WI, Mendonça V, Francisco MGS, Bardiviesso DM, Tosta MDS. 2010. Composition of substrates and volume of recipients in the production and quality of yellow passion fruit seedlings. Ciência e Agrotecnologia, 34(3): 588-595.
  • Soares FD, Pereira T, Marques MOM, Monteiro AR. 2007. Volatile and non-volatile chemical composition of the white guava fruit (Psidium guajava) at different stages of maturity.Food chemistry, 100(1): 15-21.
  • Yang XL, Hu XJ, Long XQ. 2019. Characterization of the complete chloroplast genome of a purple passion flower variety ‘Pingtang No. 1’(Passiflora edulia Sims) in China and phylogenetic relationships. Mitochondrial DNA Part B, 4(2): 2649-2651

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