Biochar Grafted on CMC-Terpolymer by Green Microwave Route for Sustainable Agriculture

The deficiency of water sources and the environmental disposal of large amounts of biomass waste (orange peels) produces economic and environmental problems, though its conversion into biochar by a pyrolysis procedure might be used to improve soil productivity. In the current study, we investigated...

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Published inAgriculture (Basel) Vol. 11; no. 4; p. 350
Main Authors Elsaeed, Shimaa M., Zaki, E. G., Ibrahim, Tarek M., Ibrahim Talha, Nasser, Saad, Hosam A., Gobouri, Adil A., Elkelish, Amr, Mohamed el-kousy, Salah
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.04.2021
Subjects
Agricultural economics
Agriculture
Arid lands
Arid zones
Aridity
biochar
Biodegradability
Biodegradation
Biomass
Cellulose
Charcoal
Degradability
Enhanced oil recovery
Equilibrium
Ethanol
Grafting
Hydrogels
Irrigation water
Moisture content
Plant growth
Polymerization
Polymers
Pyrolysis
Reaction time
Retention
Retention capacity
Soil degradation
Soil improvement
Soil investigations
Soil water
superabsorbent
Sustainable agriculture
swelling ratio and water retention
Terpolymers
Water consumption
water holding capacity
Egypt
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Summary:The deficiency of water sources and the environmental disposal of large amounts of biomass waste (orange peels) produces economic and environmental problems, though its conversion into biochar by a pyrolysis procedure might be used to improve soil productivity. In the current study, we investigated the performance of superabsorbent biochar composite grafted on CMC as a low-cost, alternative, and biodegradable terpolymer composite (IPNCB) for soil water retention capacity. The IPNCB composite was synthesized by both microwave and conventional routes. The optimal reaction parameters proved that the microwave route has a high grafting percentage (%G) and short reaction time compared to the conventional route. The superabsorbent composite was characterized using different methods: FTIR, TGA, and SEM. The results show that the equilibrium water swelling (EW) of the IPNCB composite was improved at a 2% biochar concentration. The incorporation of biochar (BC) into the polymer network improved the water holding capacity (WHC) to 57.6% and water retention (WR) to 9.1% after 30 days. The degradation test indicates the IPNCB composite has a good degradability rate. Mixing soil with the prepared IPNCB composite can improve plant growth and reduce water consumption through the irrigation of arid lands. The IPNCB composite is a candidate in sustainable agriculture applications.
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture11040350