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Organic wastes as alternative sources of phosphorus for plant nutrition in a calcareous soil

TitleOrganic wastes as alternative sources of phosphorus for plant nutrition in a calcareous soil
Publication TypeArticolo su Rivista peer-reviewed
Year of Publication2019
AuthorsGrigatti, M., Boanini E., Bolzonella D., Sciubba Luigi, Mancarella S., Ciavatta C., and Marzadori C.
JournalWaste Management
Volume93
Pagination34-46
ISSN0956053X
Keywords31P-NMR, 31P-NMR spectroscopy, activated sludge, Adsorption, Adsorption capacities, Agricultural, agricultural slurry, alternative energy, Alternative source, Anaerobic sludge, animal, Animalia, Animals, Apparent recovery, article, bicarbonate, Bovinae, bovine, calcareous soil, Cattle, Chemical analysis, concentration (composition), concentration (parameter), controlled study, Crop, Crops, Effluents, energy crop, Extraction, grass, Lolium, Mammals, Nitrogen, nonhuman, Nuclear magnetic resonance spectroscopy, organic fertilizer, organic matter, organic waste, phosphate, Phosphorus, phosphorus nuclear magnetic resonance, Pig, plant nutrition, priority journal, Recycling, Ryegrass, Sequential chemical extraction, sequential extraction, sewage, sludge, Sodium bicarbonate, Soil, Soils, Suidae, Swine, waste water, Wastewater sludge, Water, Wine, winery sludge, X ray diffraction, X-Ray Diffraction
Abstract

Recycled organic wastes (OW) can be a valuable P source; however, their P-fertilising capacity is still poorly known. In this study, we selected three anaerobic digestates [wastewater sludge (D1), winery sludge (D2), and bovine-slurry/energy crops (BD)] and two animal effluents [bovine slurry (BS) and swine slurry (SS)] to test their P-release and P-fertilising capacities via sequential chemical extraction (SCE), X-ray diffraction (XRD), and 31P-nuclear magnetic resonance (31P NMR). Subsequently, the three digestates (30 mg P kg−1 of soil) were compared for the release of Olsen-P during a soil incubation and for plant-P apparent recovery (ARF) in a pot experiment using ryegrass (112 days) in a soil with poorly available-P (Olsen-P < 5 mg kg−1), under a non-limiting N environment. The amount of labile-P (H2O + NaHCO3), as determined from SCE, related well to the Olsen-P following OW addition to the soil. It was shown via 31P NMR spectroscopy that orthophosphate was the leading P-form in highly P-releasing OW. The amount of labile-P, however, was affected by soil adsorption, thereby reducing plant-P uptake. The plant-P ARF (%) showed that the recycled P-sources were clustered in highly (BD and SS: ≈20%), intermediately (D1 and BS: ≈15%), and poorly performing OWs (D2: ≈10%) vs. chemical P-source (P-chem: 20%). Therefore, only BD and SS were effective alternatives to P-chem; however, the other OW can be efficient P-sources in soils with higher Olsen-P. Thus, crop fertilisation can be tailored on a P-basis by SCE as a function of soil adsorption capacity and on an N-basis according to the demand. © 2019

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URLhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85065773299&doi=10.1016%2fj.wasman.2019.05.028&partnerID=40&md5=6a5dc20ffd349aa1ec9e895535f83a23
DOI10.1016/j.wasman.2019.05.028
Citation KeyGrigatti201934