Microalgae biofilm in soil: Greenhouse gas emissions, ammonia volatilization and plant growth

Castro, Jackeline de Siqueira; Calijuri, Maria Lúcia; Assemany, Paula Peixoto; Cecon, Paulo Roberto; Assis, Igor Rodrigues de; Ribeiro, Vinícius José

doi:10.1016/j.scitotenv.2016.08.205

Cited by 65 publications

(31 citation statements)

References 26 publications

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“…Indeed biomass production of 153 g and 547 g were respectively noticed for the fertilization at the time of transplant and 22 days prior the time of transplant [25]. According to many authors [26,46,47], even growing plants with microalgae biomass wasn't better than those grown with synthetic fertilizers or digestate, the use of microalgal biomass for fertilizing purposes presents some important advantages. Microalgal biomass can be considered as a slow-released fertilizer since the application of dried biomass to soils would not result in emissions Table 4.…”

Section: Agronomic Trials By Plant Growth and Lixiviation Testsmentioning

confidence: 99%

Production of Microalgal Slow-Release Fertilizer by Valorizing Liquid Agricultural Digestate: Growth Experiments with Tomatoes

Jimenez¹,

Μάρκου²,

Tayibi

et al. 2020

Applied Sciences

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Anaerobic Digestion (AD) is a process that is well-known and fast-developing in Europe. AD generates large amounts of digestate, especially in livestock-intensive areas. Digestate has potential environmental issues due to nutrients (such as nitrogen) lixiviation or volatilization. Using liquid digestate as a nutrient source for microalgae growth is considered beneficial because digestate could be valorized and upgraded by the production of an added value product. In this work, microalgal biomass produced using liquid digestate from an agricultural biogas plant was investigated as a slow-release fertilizer in tomatoes. Monoraphidium sp. was first cultivated at different dilutions (1:20, 1:30, 1:50), in indoor laboratory-scale trials. The optimum dilution factor was determined to be 1:50, with a specific growth rate of 0.13 d−1 and a complete nitrogen removal capacity in 25 days of culture. Then, outdoor experiments were conducted in a 110 dm3 vertical, closed photobioreactors (PBRs) in batch and semi-continuous mode with 1:50 diluted liquid digestate. During the batch mode, the microalgae were able to remove almost all NH4+ and 65 (±13) % of PO43−, while the microalgal growth rate reached 0.25 d−1. After the batch mode, the cultures were switched to operate under semi-continuously conditions. The cell densities were maintained at 1.3 × 107 cells mL−1 and a biomass productivity around 38.3 mg TSS L−1 d−1 during three weeks was achieved, where after that it started to decline due to unfavorable weather conditions. Microalgae biomass was further tested as a fertilizer for tomatoes growth, enhancing by 32% plant growth in terms of dry biomass compared with the control trials (without fertilization). Similar performances were achieved in tomato growth using synthetic fertilizer or digestate. Finally, the leaching effect in soils columns without plant was tested and after 25 days, only 7% of N was leached when microalgae were used, against 50% in the case of synthetic fertilizer.

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Section: Agronomic Trials By Plant Growth and Lixiviation Testsmentioning

confidence: 99%

Production of Microalgal Slow-Release Fertilizer by Valorizing Liquid Agricultural Digestate: Growth Experiments with Tomatoes

Jimenez¹,

Μάρκου²,

Tayibi

et al. 2020

Applied Sciences

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“…The study also alluded to the necessity in understanding and using the interactions between mass and radiative transfer, physiology of the microorganisms, and their radiation and substrate kinetics and dynamics. In addition to these components, we have also identified that biofilm formation is important, whether it is a structure to be avoided or fostered as a design feature [66].…”

Section: Comparison Of Eulerian and Lagrangian Methodologiesmentioning

confidence: 99%

“…There is a net increment of biomass production yield compared to typical activated sludge processes. This could have an impact in energy recovery (through biogas) but also in sludge waste disposal expenses, which can be partially counteracted by downstream production of high value-added bioresources as proteins, prebiotics and probiotics[31] or bioplastics, as well as energetic resources as third generation liquid biofuels[66].…”

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confidence: 99%

Distributed parameter modelling of phototrophic bioreactor systems

Barry¹

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Purple phototrophic bacteria (PPB) use infrared light to generate microbial energy, with electron, carbon and nitrogen supplied chemically. They have broad applicability for resource recovery from wastes and wastewater, as they have potential value as microbial product and very high growth yields on substrate. Although PPB processes are gaining relevance in the aforementioned industries, reactor design, particularly effective consideration of light in chemical kinetics and hydraulics is a critical issue. This thesis aims to assess key limitations and define their physical behaviour mathematically. The first limitation was that there was no mixed culture PPB process model describing the behaviour of PPB in the presence of ammonia, organic matter and other nutrients. The mixed population models of the International Water Association (IWA) provide a good framework for process modelling and control. As such, a process model for a mixed-culture PPB system was developed based on five key processes: photoheterotrophic growth, photoautotrophic growth, chemoheterotrophic growth, hydrolysis/fermentation, and decay. This model was developed as a set of ordinary differential equations varying in time and lumped in space (as for the IWA models). The second limitation is that the radiative field has not been considered. This can vary spatially and temporally. The radiative field in a PPB system attenuates sharply, which influences the growth domains. A CFD modelling framework was therefore developed in OpenFOAM to describe the spatial variations and interactions between biomass growth, the flow field and the radiative field. It was found that lumped modelling approaches and distributed parameter approaches differed in results based on different reactor domains and behaviours. The deviation from lumped parameter behaviour was greater for a cylindrical stirred reactor than for a flat plate reactor. Therefore, spatial considerations are necessary in the design phase of a photobioreactor. Finally, biofilms are a critical aspect in PPB growth, and a coupled biofilm radiative transfer model has not been previously considered. The model was thus extended to include biofilm formation of a mixed PPB system in the presence of a spatially varying radiative field. A volume-of-fluid approach was used as a basis for this model, considering three particulate species (phototrophic bacteria, biodegradable particulate matter, and inert particulates). The radiative-solid-liquid coupling overall was found to be critical in operation, with traditional lumped parameter approaches to design and analysis not well suited to the emerging challenges of mixed culture photo-bio systems. These aspects should be further considered through model based analysis and experimental validation for future system design.

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“…Microalgae biomass application in soils is beneficial for crops and yields (Shaaban, 2001), the organic matter, carbon content and biological activity in soils increase with these microorganisms (Castro et al, 2017;Miralles et al, 2012;Xie et al, 2007). Microalgae, specifically when they are obtained from wastewater treatments (De-Bashan and Bashan, 2004), contains several nutrients removed from the treated sewage.…”

Section: Climate-smartmentioning

confidence: 99%

“…Considering that CSA is oriented to reduce GHG emissions and enhance the productivity of agricultural ecosystems, microalgae culture and production can be a decisive factor for future scenarios. Several experiments were conducted to study the benefits of microalgae in agriculture, from the fertility perspective (Mulbry et al, 2005;Raposo and Morais, 2011;Renuka et al, 2016;Shaaban, 2001) to the environmental approach (Castro et al, 2017;Egle et al, 2016;Renuka et al, 2016).…”

Section: Microalgae Culturementioning

confidence: 99%

Applications of artificial neural networks in three agro-environmental systems: microalgae production, nutritional characterization of soils and meteorological variables management

Ortellado¹,

Manuel²

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Microalgae biofilm in soil: Greenhouse gas emissions, ammonia volatilization and plant growth

Cited by 65 publications

References 26 publications

Production of Microalgal Slow-Release Fertilizer by Valorizing Liquid Agricultural Digestate: Growth Experiments with Tomatoes

Production of Microalgal Slow-Release Fertilizer by Valorizing Liquid Agricultural Digestate: Growth Experiments with Tomatoes

Distributed parameter modelling of phototrophic bioreactor systems

Applications of artificial neural networks in three agro-environmental systems: microalgae production, nutritional characterization of soils and meteorological variables management

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