Investigation of the effect of superabsorbent polymer application on soil moisture and plant growth-Reference-Cited by-同舟云学术

Investigation of the effect of superabsorbent polymer application on soil moisture and plant growth

Published:2024-04-30 Issue:1 Volume:5 Page:24-30
ISSN:2718-062X
Container-title:Frontiers in Life Sciences and Related Technologies
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Author:

Seven Senem¹^ORCID,Menceloğlu Yeşim²^ORCID,Ünlü Kemal³^ORCID,Kahraman Kadriye²^ORCID,Rodop Ogeday²^ORCID,Bilge İpek²^ORCID,Yazıcı Mustafa Atilla²^ORCID,Menceloğlu Yusuf²^ORCID

Affiliation:

1. BAHCESEHIR UNIVERSITY

2. SABANCI UNIVERSITY

3. MARMARA UNIVERSITY

Abstract

As climate change continues to affect the environment, drought management has become more critical in agri-food production. Farmers are now looking for alternative drought management methods that are easy to apply. In this sense, superabsorbent polymers (SAPs) were proposed as an alternative soil conditioning and drought management tool within this study. To test the efficiency of a developed SAP in terms of soil conditioning and plant growth promotion with different soil types and extreme drought conditions, long-term soil and greenhouse experiments were carried out in at least 4 replicates. The plant growth was monitored by 4 different growth indicators using wheat as a model plant. Plant growth indicators demonstrated that shoot dry matter, spike length, and grain yield were enhanced up to 24%, and 11.6% using different amounts of SAP at varying drought conditions. The study set forth and exemplary of superabsorbent polymer use in agriculture and useful in dose adjustment and understanding the drought-dose relationship in these types of polymers.

Funder

Tubitak

Publisher

Frontiers in Life Sciences and Related Technologies

Reference47 articles.

1. Acar, O., Izydorczyk, M. S., McMillan, T., Yazici, M. A., Imamoglu, A., Cakmak, I., & Koksel, H. (2023). A research on milling fractions of biofortified and nonbiofortified hull‐less oats in terms of minerals, arabinoxylans, and other chemical properties. Cereal Chemistry, 100(5), 1192-1202.

2. Ahmed, A. M., Mekonnen, M. L., & Mekonnen, K. N. (2023). Review on nanocomposite materials from cellulose, chitosan, alginate, and lignin for removal and recovery of nutrients from wastewater. Carbohydrate Polymer Technologies and Applications, 100386.

3. Ariturk, G., Bilge, K., Seven, S. A., & Menceloglu, Y. Z. (2024). Morphological adaptation of expanded vermiculite in polylactic acid and polypropylene matrices for superior thermoplastic composites. Polymer Composites, 45(6), 5043-5050.

4. Bachra, Y., Grouli, A., Damiri, F., Bennamara, A., & Berrada, M. (2020). A new approach for assessing the absorption of disposable baby diapers and superabsorbent polymers: A comparative study. Results in Materials, 8, 100156.

5. Bett, B., Said, M. Y., Sang, R., Bukachi, S., Wanyoike, S., Kifugo, S. C., & Grace, D. (2017). Effects of flood irrigation on the risk of selected zoonotic pathogens in an arid and semi-arid area in the Eastern Kenya. PloS One, 12(5), e0172626.