Response of okra (Abelmoschus esculentus) to foliar application of micronutrients

SUMATI NARAYAN; INSHA JAVEED; KHURSHEED HUSSAIN; FAROOQ AHMAD KHAN; SHAKEEL AHMAD MIR; SHABIR AHMED BANGROO; AJAZ AHMAD MALIK

doi:10.56093/ijas.v91i5.113095

Authors

SUMATI NARAYAN Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India
INSHA JAVEED Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India
KHURSHEED HUSSAIN Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India
FAROOQ AHMAD KHAN Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India
SHAKEEL AHMAD MIR Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India
SHABIR AHMED BANGROO Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India
AJAZ AHMAD MALIK Sher-e-Kashmir University of Agricultural Sciences and Technology of Kashmir, Jammu and Kashmir 190 025, India

https://doi.org/10.56093/ijas.v91i5.113095

Keywords:

Chlorophyll, Fruit yield, Micronutrients, Okra

Abstract

The experiment was conducted at SKUAST-Kashmir, Shalimar during 2018 to evaluate the effects of foliar sprays of different micronutrients, viz. B, Zn Cu, Mo, Fe and Mn, on plant growth, physiological and yield attributes of okra. Treatments were prepared as 100 ppm aqueous solution of each boric acid, zinc sulphate, copper sulphate, ferrous sulphate and magnesium sulphate, except ammonium molybdate (taken as 50ppm). Each treatment was applied individually as well as in different combinations at 30, 45 and 60 DAS, thus making total of 14 treatments with three replications. Results indicated that different treatments markedly increased the plant growth, chlorophyll and yield of okra. The maximum plant height (156.40 cm), leaf area (5938.55 cm2), leaf area (5938.55/plant), LAI (4.39), SLW (10.1) mg/cm2) as well as leaf chlorophyll content (0.80 mg/g) were recorded when all the micronutrients were applied in combination (T7). The same treatment also recorded earliest fruit harvest (45.43 DAS) with highest number of fruits per plant (23.20), maximum fruit size (1.37 cm × 11.25 cm) and thus, fruit yield (241.74 g/plant) against the minimum plant height (116.45 cm), LAI (1.90), SLW (6.12 mg/cm2), chlorophyll content (0.50 mg/g), number of fruits (20.29/plant), fruit size (1.11 cm × 9.56 cm) and yield (183.01 g/plant) with maximum time taken (71.8 DAS) to first harvest. Finally, it can be stated that combined application of micronutrients (B, Zn Cu, Mo, Fe and Mn) as foliar sprays at 30, 45 and 60 DAS is most effective in improving plant growth, yield and yield attributes of okra.

Downloads

Download data is not yet available.

References

Ali S, Javed H U, Rehman U R N, Sabir I A, Naeem M S, Siddiqui M Z, Saeed D A and Nawaz M A. 2013. Foliar application of some macro and micronutrients improves tomato growth, flowering and yield. International Journal of Biosciences 3(10): 280-87.

Fageria N K, Filhoa M P B, Moreirab A and Guimaresa C M. 2009. Foliar fertilization of crop plants. Journal of Plant Nutrition 32(6): 1044-64.

Gemede H F, Ratta N, Haki G D, Woldegiorgis A Z and Beyene F. 2015. Nutritional quality and health benefits of okra (Abelmoschus esculentus): A review. International Journal of Nutrition and Food Sciences 4(2): 208-15.

Jayaraman J. 1981. Laboratory Manual in Biochemistry. Willey Eastern Pvt Ltd, New Delhi.

Jiang C, Jokhan M, Hohjo M, Tsukagoshi S, Ebihara M, Akio Nakaminami A and Maruo T. 2017. Photosynthesis, plant growth, and fruit production of single-truss tomato improves with supplemental lighting provided from underneath or within the inner canopy. Scientia Horticulturae 222: 221-29.

Kandoliya R U, Sakarvadiya H L and Kunjadia B B. 2018. Effect of zinc and iron application on leaf chlorophyll, carotenoid, grain yield and quality of wheat in calcareous soil of Saurashtra region. International Journal of Chemical Studies 6(4): 2092- 96.

Khan F A, Banday F A, Narayan S, Khan F U and Bhat S A. 2016. Use of models as non-destructive method for leaf area estimation in horticultural crops. IRA-International Journal of Applied Sciences 4(1): 162-80.

Mehraj H, Taufique T, Mandal M S H, Sikdar R K and Jamal Uddin A F M. 2015. Foliar feeding of micronutrient mixture on growth and yield of okra (Abelmoschus esculantus). American-Eurasian Journal of Agriculture & Environment Science 15(11): 2124-29.

Mohammadi G, Khah E M, Petropoulos S A and Chachalis D B. 2016. Effect of foliar application of micronutrients on plant growth and seed germination of four okra cultivars. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 44(1): 257-63.

Naz R M M, Muhammad S, Hamid A and Bibi F. 2012. Effect of boron on the flowering and fruiting of tomato. Sarhad Journal of Agriculture 28(1): 37-40.

Radford P T 1967. Growth analysis formulae, their use and abuse. Crop Science 7(3): 171-75.

Roosta H R, Estaji A and Niknam F. 2018. Effect of iron, zinc and manganese shortage-induced change on photosynthetic pigments, some osmoregulators and chlorophyll fluorescence parameters in lettuce. Photosynthetica 56(2): 606–15.

Sestak Z 1971. Plant photosynthetic production. Manual of Methods, N.V. Publication, pp. 343-381. Catsky J and Jarris P G (Eds).

Surendra P, Nawalagatti C M, Chetti M B and Hiremath S M. 2006. Effect of plant growth regulators and micronutrients on morphoPhysiological and biochemical traits and yield in okra. Karnataka Journal of Agricultural Sciences 19(3): 694-97