| Title |
Bioashes and their potential for reuse to sustain ecosystem services and underpin circular economy |
| ID_Doc |
20968 |
| Authors |
Ondrasek, G; Kovacic, MB; Carevic, I; Stirmer, N; Stipicevic, S; Udikovic-Kolic, N; Filipovic, V; Romic, D; Rengel, Z |
| Title |
Bioashes and their potential for reuse to sustain ecosystem services and underpin circular economy |
| Year |
2021 |
| Published |
|
| DOI |
10.1016/j.rser.2021.111540 |
| Abstract |
Global promotion of decarbonisation by using sustainable bio-renewables is associated with generation of ash residues whose amounts have increased exponentially in the last decades. Bioashes are physicochemically complex, ultra-alkaline, and potentially hazardous solids, but with a huge potential to become (co)products with environmental/economic value. Their diverse nature lends itself to a wide range of uses in land remediation, wastewater treatment, civil and bio-tech engineering, end even medicine. However, there are issues hindering the usage of bioashes as valuable resources: i) large variation among specific fractions and types, ii) strong and long-lasting reactivity and potential toxicity, and iii) an incoherent, often non-existent, legislative and regulatory framework for management of specific bio-wastes. Overcoming these obstacles and uncertainties regarding the ecological and economic benefits vs. negative side-effects is a significant challenge. The research and imple-mentation work is urgently needed to i) elucidate dosage-dependent biological outcomes of bioash amendments, especially those related to soil and aquatic microbiomes as the primary living barriers/biofilters for most sub-stances released from bioashes, and ii) transform finely powdered matrices to easy-to-apply forms (from nano/ micro-to mm-sized agglomerates) to reduce human health implications. The continued progress in material sciences and nanotechnology offers a fascinating array of solutions for re-purposing bioashes; however, given the stringent quality-demanding criteria, the separation and concentration of targeted submatrices (e.g. alumino-silicates) from the bulk bioashes are yet to be achieved on the lab to industrial scales. Meanwhile, a significant reuse potential of bioashes will remain under-exploited and compounded by the adverse environmental issues arising from landfill disposal. |
| Author Keywords |
Bio-renewable; Pozzolanic material; Solid co-products; Acid soils; Metal contamination; Wastewater treatment |
| Index Keywords |
Index Keywords |
| Document Type |
Other |
| Open Access |
Open Access |
| Source |
Science Citation Index Expanded (SCI-EXPANDED) |
| EID |
WOS:000708455700001 |
| WoS Category |
Green & Sustainable Science & Technology; Energy & Fuels |
| Research Area |
Science & Technology - Other Topics; Energy & Fuels |
| PDF |
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