Evaluation of Variable Rates of Zinc Sulfate Fertilization on Soil Chemical Characteristics, Fertility Status, and Growth Components of Wheat (Triticum aestivum): A Case Study on the Hilly Region of Uthal, Balochistan

Khalid Hameed  Mengal; Shahmir Ali Kalhoro; Muneer Ahmed  Rodeni; Kashif Ali  Kubar; Punhoon Khan  Korai; Siraj  Ahmed; Shabir Ahmed; Bilal Ahmed  Ababaki; Sami   Ullah; Sher   Jan; Abdullah  Raisani; Zain ul Abidin  Kasi; Javed Ahmed  Mengal

doi:10.55627/agrivet.03.02.0774

Authors

Khalid Hameed Mengal Department of Soil Science, Faculty of Agriculture, LUAWMS
Shahmir Ali Kalhoro Department of Soil Science, Faculty of Agriculture, LUAWMS
Muneer Ahmed Rodeni Department of Soil Science, Faculty of Agriculture, LUAWMS
Kashif Ali Kubar Department of Soil Science, Faculty of Agriculture, LUAWMS
Punhoon Khan Korai Department of Soil Science, Faculty of Agriculture, LUAWMS
Siraj Ahmed Department of forest and wildlife, Quetta
Shabir Ahmed Department of Agriculture Extension, Quetta
Bilal Ahmed Ababaki Agriculture Research Institute, Quetta
Sami Ullah Agriculture Research Institute Quetta
Sher Jan Department of Soil Science, Faculty of Agriculture, LUAWMS
Abdullah Raisani Agriculture Research Institute Quetta
Zain ul Abidin Kasi Department of forest and wildlife, Quetta
Javed Ahmed Mengal 5Department of Soil Science, Faculty of Crop Production, SAU, Tando Jam

DOI:

https://doi.org/10.55627/agrivet.03.02.0774

Keywords:

Zinc, Nitrogen, Wheat, Fertile Tillers, Grain Yield, Nutrient Interaction

Abstract

Fertilization of field crops with zinc (Zn) has recently been a significant consideration worldwide due to deficiency and malnutrition. This research study aimed to evaluate the impact of different levels of zinc sulfate, combined with nitrogen and phosphorous fertilizers on soil properties, morphological characteristics of plants, plant growth, yield attributes, and their interaction with soil properties. The research experiment was conducted in a randomized complete block design with Six variable rates of ZnSO-4 (0, 4.5, 9.5, 14.5, 19.5, and 24.5 kgha-1) arranged in a triplicate. The analysis results showed a 15-20% significant effect of increased rate of Zn fertilization on plant growth (plant height, leaf length, spike length, and fertile tiller formation), biological and grain yield of wheat compared to control. The mean maximum of biological (18018.33±820.63 and 17219.66±1261.41 kgha-1) and grain yield (4233.33±121.027 and 4000±58.13 kgha-1) were observed in T5 and T4 (ZnSO-4 rate 24.5 and 19.5 kgha-1) compared to control (8675.66±228.92 and 2863.33±46.99 kgha-1). Additionally; the results of the co-relation matrix showed a positive significant (p<0.05) effect among the various soil and plant parameters, while; the negative significant (p<0.05) was observed in soil pH, and non-significant (p<0.05) was observed in soil EC (dsm-1). Conclusively; this study's findings suggested that ZnSO-4 at the rate of 24.5 kgha-1 could improve the interaction among the soil and plant nutrition that enhanced the morphological characteristic of wheat and ultimately influenced biological and grain yield kgha-1 of wheat in the hilly areas of Balochistan.

References

Adeel, M.A., Hussain, S., Basit, A., Hussain, M.B., Aon, M., 2024. Biofortification of wheat in salt-affected soil through seed priming and soil application of zinc. Journal of Trace Elements and Minerals 8, 100159.

Ahmed, S., Kalhoro, S.A., Ahmed, B., Sarfaraz, Q., Rodeni, M.A., Hameed, K., Ullah, S., 2024. Impact of Humic Acid on the Morphological Components and Growth Parameters of Wheat (Triticum Aestivum L.) Under Dry Climate of Uthal. Journal of Applied Research in Plant Sciences 5, 226-236.

Azeem, A., Ul-Allah, S., Azeem, F., Naeem, M., Sattar, A., Ijaz, M., Sher, A., 2023. Effect of foliar applied zinc sulphate on phenotypic variability, association and heritability of yield and zinc biofortification related traits of wheat genotypes. Heliyon 9.

Corpas, F.J., Palma, J.M., 2020. H2S signaling in plants and applications in agriculture. Journal of Advanced Research 24, 131-137.

Dawar, K., Khan, N., Fahad, S., Alam, S.S., Khan, S., Mian, I.A., Akbar, W.A., 2021. Effect of sulfur and zinc nutrition on yield and uptake by wheat. Journal of Plant Growth Regulation, 1-9.

Dhaliwal, S.S., Sharma, V., Shukla, A.K., Verma, V., Kaur, M., Shivay, Y.S., Nisar, S., Gaber, A., Brestic, M., Barek, V., 2022. Biofortification—A frontier novel approach to enrich micronutrients in field crops to encounter the nutritional security. Molecules 27, 1340.

Estefan, G., 2013. Methods of soil, plant, and water analysis: a manual for the West Asia and North Africa region. International Center for Agricultural Research in the Dry Areas (ICARDA).

Faizan, M., Bhat, J.A., Chen, C., Alyemeni, M.N., Wijaya, L., Ahmad, P., Yu, F., 2021. Zinc oxide nanoparticles (ZnO-NPs) induce salt tolerance by improving the antioxidant system and photosynthetic machinery in tomato. Plant Physiology and Biochemistry 161, 122-130.

Ferrari, M., Dal Cortivo, C., Panozzo, A., Barion, G., Visioli, G., Giannelli, G., Vamerali, T., 2021. Comparing soil vs. foliar nitrogen supply of the whole fertilizer dose in common wheat. Agronomy 11, 2138.

Gatto, A., Loewenstein, W., Sadik-Zada, E.R., 2021. An extensive data set on energy, economy, environmental pollution and institutional quality in the petroleum-reliant developing and transition economies. Data in Brief 35, 106766.

Guerrini, L., Napoli, M., Mancini, M., Masella, P., Cappelli, A., Parenti, A., Orlandini, S., 2020. Wheat grain composition, dough rheology and bread quality as affected by nitrogen and sulfur fertilization and seeding density. Agronomy 10, 233.

Gupta, N., Ram, H., Kumar, B., 2016. Mechanism of zinc absorption in plants: uptake, transport, translocation and accumulation. Reviews in Environmental Science and Bio/Technology 15, 89-109.

Hafeez, M.B., Ramzan, Y., Khan, S., Ibrar, D., Bashir, S., Zahra, N., Rashid, N., Nadeem, M., Rahman, S.u., Shair, H., 2021. Application of zinc and iron-based fertilizers improves the growth attributes, productivity, and grain quality of two wheat (Triticum aestivum) cultivars. Frontiers in Nutrition 8, 779595.

Haider, S.A., Naqvi, S.R., Akram, T., Umar, G.A., Shahzad, A., Sial, M.R., Khaliq, S., Kamran, M., 2019. LSTM neural network based forecasting model for wheat production in Pakistan. Agronomy 9, 72.

Hassan, M.U., Chattha, M.U., Ullah, A., Khan, I., Qadeer, A., Aamer, M., Khan, A.U., Nadeem, F., Khan, T.A., 2019. Agronomic biofortification to improve productivity and grain Zn concentration of bread wheat.

Hera, M.H.R., Hossain, M., Paul, A.K., 2018. Effect of foliar zinc spray on growth and yield of heat tolerant wheat under water stress. Journal of Biological and Environmental Engineering 1, 10-16.

Jackson, M.L., 2005. Soil chemical analysis: advanced course: a manual of methods useful for instruction and research in soil chemistry, physical chemistry of soils, soil fertility, and soil genesis. UW-Madison Libraries parallel press.

Jalal, A., Galindo, F.S., Freitas, L.A., da Silva Oliveira, C.E., de Lima, B.H., Pereira, Í.T., Ferraz, G.F., de Souza, J.S., da Costa, K.N., Nogueira, T.A.R., 2022. Yield, zinc efficiencies and biofortification of wheat with zinc sulfate application in soil and foliar nanozinc fertilisation. Crop and Pasture Science.

Joy, E.J., Ahmad, W., Zia, M.H., Kumssa, D.B., Young, S.D., Ander, E.L., Watts, M.J., Stein, A.J., Broadley, M.R., 2017. Valuing increased zinc (Zn) fertiliser-use in Pakistan. Plant and Soil 411, 139-150.

Nguemezi, C., Tematio, P., Yemefack, M., Tsozue, D., Silatsa, T., 2020. Soil quality and soil fertility status in major soil groups at the Tombel area, South-West Cameroon. Heliyon 6.

Qadir, M., Wang, X., Baloch, A.H., Baloch, I.A., Azeem, M., Imran, M., Saleem, M., 2018. The impact of drought on phenotypic characters of five advance bread wheat genotypes. Pure and Applied Biology 7, 635-642.

Rehman, A., Farooq, M., Naveed, M., Ozturk, L., Nawaz, A., 2018. Pseudomonas-aided zinc application improves the productivity and biofortification of bread wheat. Crop and Pasture Science 69, 659-672.

Sattar, A., Wang, X., Ul-Allah, S., Sher, A., Ijaz, M., Irfan, M., Abbas, T., Hussain, S., Nawaz, F., Al-Hashimi, A., 2022. Foliar application of zinc improves morpho-physiological and antioxidant defense mechanisms, and agronomic grain biofortification of wheat (Triticum aestivum L.) under water stress. Saudi Journal of Biological Sciences 29, 1699-1706.

Sehgal, A., Sita, K., Kumar, J., Kumar, S., Singh, S., Siddique, K.H., Nayyar, H., 2017. Effects of drought, heat and their interaction on the growth, yield and photosynthetic function of lentil (Lens culinaris Medikus) genotypes varying in heat and drought sensitivity. Frontiers in Plant Science 8, 1776.

Shehzadi, N., Mahmood, A., Kaleem, M., Chishti, M.S., Bashir, H., Hashem, A., Abd-Allah, E.F., Shahid, H., Ishtiaq, A., 2024. Zinc and nitrogen mediate the regulation of growth, leading to the upregulation of antioxidant aptitude, physio-biochemical traits, and yield in wheat plants. Scientific Reports 14, 12897.

Shoja, T., Majidian, M., Rabiee, M., 2018. Effects of zinc, boron and sulfur on grain yield, activity of some antioxidant enzymes and fatty acid composition of rapeseed (Brassica napus L.). Acta Agriculturae Slovenica 111, 73-84.

Singh, B.R., Timsina, Y.N., Lind, O.C., Cagno, S., Janssens, K., 2018. Zinc and iron concentration as affected by nitrogen fertilization and their localization in wheat grain. Frontiers in Plant Science 9, 307.

Singh, S., Kaur, J., Ram, H., Singh, J., Kaur, S., 2023. Agronomic bio-fortification of wheat (Triticum aestivum L.) to alleviate zinc deficiency in human being. Reviews in Environmental Science and Bio/Technology 22, 505-526.

Suganya, A., Saravanan, A., Manivannan, N., 2020. Role of zinc nutrition for increasing zinc availability, uptake, yield, and quality of maize (Zea mays L.) grains: An overview. Communications in Soil Science and Plant Analysis 51, 2001-2021.

Sultana, S., Naser, H.á., Shil, N., Akhter, S., Begum, R., 2016. Effect of foliar application of zinc on yield of wheat grown by avoiding irrigation at different growth stages.

Thapa, D.B., Subedi, M., Yadav, R.P., Joshi, B.P., Adhikari, B.N., Shrestha, K.P., Magar, P.B., Pant, K.R., Gurung, S.B., Ghimire, S., 2022. Variation in grain zinc and iron concentrations, grain yield and associated traits of biofortified bread wheat genotypes in Nepal. Frontiers in Plant Science 13, 881965.

Usmani, M.M., Nawaz, F., Majeed, S., Shehzad, M.A., Ahmad, K.S., Akhtar, G., Aqib, M., Shabbir, R.N., 2020. Sulfate-mediated drought tolerance in maize involves regulation at physiological and biochemical levels. Scientific Reports 10, 1147.

Wahid, M.A., Irshad, M., Irshad, S., Khan, S., Hasnain, Z., Ibrar, D., Khan, A.R., Saleem, M.F., Bashir, S., Alotaibi, S.S., 2022. Nitrogenous fertilizer coated with zinc improves the productivity and grain quality of rice grown under anaerobic conditions. Frontiers in Plant Science 13, 914653.

Walkley, A., Black, I.A., 1934. An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil Science 37, 29-38.

Wang, X., Li, Q., Pei, Z., Wang, S., 2018. Effects of zinc oxide nanoparticles on the growth, photosynthetic traits, and antioxidative enzymes in tomato plants. Biologia Plantarum 62, 801-808.

Wilson, T.L., Guttieri, M.J., Nelson, N.O., Fritz, A., Tilley, M., 2020. Nitrogen and sulfur effects on hard winter wheat quality and asparagine concentration. Journal of Cereal Science 93, 102969.

Zhu, D.-B., Hu, K.-D., Guo, X.-K., Liu, Y., Hu, L.-Y., Li, Y.-H., Wang, S.-H., Zhang, H., 2015. Sulfur dioxide enhances endogenous hydrogen sulfide accumulation and alleviates oxidative stress induced by aluminum stress in germinating wheat seeds. Oxidative Medicine and Cellular Longevity 2015, 612363.