| Title | Functionalized biochar from waste as a slow-release nutrient source: Application on tomato plants |
|---|---|
| ID_Doc | 26776 |
| Authors | Rosa, D; Petruccelli, V; Iacobbi, MC; Brasili, E; Badiali, C; Pasqua, G; Di Palma, L |
| Title | Functionalized biochar from waste as a slow-release nutrient source: Application on tomato plants |
| Year | 2024 |
| Published | Heliyon, 10, 8 |
| Abstract | Licorice processing waste was pyrolyzed at different temperatures (500 and 700 degrees C) to obtain biochar (BC500 and BC700) for use as a slow -release fertilizer on Solanum lycopersicum . The materials were characterized through BET analysis, SEM, elemental analysis, pH zc , and pyrolysis temperature effect was evaluated. The biochars were functionalized by the impregnation method to enrich them with nitrogen, phosphorus, and potassium (NPK), and desorption tests were performed in aqueous solution at different pHs (5 and 7). The pseudo -second -order model described well the release of all 3 macronutrients tested, BC500 was found to have slower release kinetics due to smaller pore size, reaching adsorption/desorption equilibrium after 14 days, compared with 10 for BC700, K des were lower in all 3 cases and NPK content was higher, initial pH did not change the release kinetics. BC500 was selected as an agricultural soil conditioner by testing at both different dosages of BC (0 - 25 %) and different NPK ratios (3:1:4 and 4:1:3). The treatment significance was evaluated. The best treatment resulted in BC dosage of 25 % nutrient ratio 4:1:3 which increased, compared to the control, total chlorophyll content (+38 %) and carotenoids (+15 %). |
| https://doi.org/10.1016/j.heliyon.2024.e29455 |
Similar Articles
| ID | Score | Article |
|---|---|---|
23746
|
Villada, E; Velasquez, M; Gómez, AM; Correa, JD; Saldarriaga, JF; López, JE; Tamayo, A Combining anaerobic digestion slurry and different biochars to develop a biochar-based slow-release NPK fertilizer(2024) | |
| 20225
|
Marcinczyk, M; Ok, YS; Oleszczuk, P From waste to fertilizer: Nutrient recovery from wastewater by pristine and engineered biochars(2022) | |
| 16231
|
Stylianou, M; Lai, TRT; Bennici, S; Dutournie, P; Limousy, L; Agapiou, A; Papamichael, I; Khiari, B; Jeguirim, M; Zorpas, AA Tomato waste biochar in the framework of circular economy(2023) | |
| 8368
|
Skrzypczak, D; Szopa, D; Mikula, K; Izydorczyk, G; Basladynska, S; Hoppe, V; Pstrowska, K; Wzorek, Z; Kominko, H; Kulazynski, M; Moustakas, K; Chojnacka, K; Witek-Krowiak, A Tannery waste-derived biochar as a carrier of micronutrients essential to plants(2022) | |
| 9794
|
Samoraj, M; Mironiuk, M; Witek-Krowiak, A; Izydorczyk, G; Skrzypczak, D; Mikula, K; Basladynska, S; Moustakas, K; Chojnacka, K Biochar in environmental friendly fertilizers-Prospects of development products and technologies(2022) | |
| 19965
|
Enaime, G; Lübken, M Agricultural Waste-Based Biochar for Agronomic Applications(2021)Applied Sciences-Basel, 11.0, 19 | |
| 22057
|
Sharma, A; Swami, S; Pawaiya, A; Mishra, A; Chaudhary, M; Bhatt, N; Khan, AA; Mutiyar, PK; Suthar, S Developing slow-release fertilizer based on pyrolysis of domestic biogas digestate cake: A circular economy approach for rural farmers(2023) | |
| 9489
|
López-Cano, I; Cayuela, ML; Sánchez-García, M; Sánchez-Monedero, MA Suitability of Different Agricultural and Urban Organic Wastes as Feedstocks for the Production of BiocharPart 2: Agronomical Evaluation as Soil Amendment(2018)Sustainability, 10.0, 6 | |
| 13435
|
Fdez-Sanromán, A; Pazos, M; Rosales, E; Sanromán, MA Unravelling the Environmental Application of Biochar as Low-Cost Biosorbent: A Review(2020)Applied Sciences-Basel, 10, 21 | |
| 13021
|
Lustosa, JF; da Silva, APF; Costa, ST; Gomes, HT; de Figueiredo, T; Hernández, Z Biochars Derived from Olive Mill Byproducts: Typology, Characterization, and Eco-Efficient Application in Agriculture-A Systematic Review(2024)Sustainability, 16.0, 12 |