Manfred Lübken scite author profile

Biochar as a stable carbon-rich material shows incredible potential to handle water/wastewater contaminants. Its application is gaining increasing interest due to the availability of feedstock, the simplicity of the preparation methods, and their enhanced physico-chemical properties. The efficacy of biochar to remove organic and inorganic pollutants depends on its surface area, pore size distribution, surface functional groups, and the size of the molecules to be removed, while the physical architecture and surface properties of biochar depend on the nature of feedstock and the preparation method/conditions. For instance, pyrolysis at high temperatures generally produces hydrophobic biochars with higher surface area and micropore volume, allowing it to be more suitable for organic contaminants sorption, whereas biochars produced at low temperatures own smaller pore size, lower surface area, and higher oxygen-containing functional groups and are more suitable to remove inorganic contaminants. In the field of water/wastewater treatment, biochar can have extensive application prospects. Biochar have been widely used as an additive/support media during anaerobic digestion and as filter media for the removal of suspended matter, heavy metals and pathogens. Biochar was also tested for its efficiency as a support-based catalyst for the degradation of dyes and recalcitrant contaminants. The current review discusses on the different methods for biochar production and provides an overview of current applications of biochar in wastewater treatment.

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Modelling the energy balance of an anaerobic digester fed with cattle manure and renewable energy crops

Lübken

et al. 2007

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Biogas from grass silage – Measurements and modeling with ADM1

Koch

Lübken

Gehring

et al. 2010

Bioresource Technology

161

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An integrated 45 L pilot microbial fuel cell system at a full-scale wastewater treatment plant

Hiegemann

Herzer

Nettmann

et al. 2016

Bioresource Technology

168

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Microbiological fermentation of lignocellulosic biomass: current state and prospects of mathematical modeling

Lübken¹,

Gehring²,

Wichern³

2009

Appl Microbiol Biotechnol

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The anaerobic fermentation process has achieved growing importance in practice in recent years. Anaerobic fermentation is especially valuable because its end product is methane, a renewable energy source. While the use of renewable energy sources has accelerated substantially in recent years, their potential has not yet been sufficiently exploited. This is especially true for biogas technology. Biogas is created in a multistage process in which different microorganisms use the energy stored in carbohydrates, fats, and proteins for their metabolism. In order to produce biogas, any organic substrate that is microbiologically accessible can be used. The microbiological process in itself is extremely complex and still requires substantial research in order to be fully understood. Technical facilities for the production of biogas are thus generally scaled in a purely empirical manner. The efficiency of the process, therefore, corresponds to the optimum only in the rarest cases. An optimal production of biogas, as well as a stable plant operation requires detailed knowledge of the biochemical processes in the fermenter. The use of mathematical models can help to achieve the necessary deeper understanding of the process. This paper reviews both the history of model development and current state of the art in modeling anaerobic digestion processes.

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Manfred Lübken

Biochar for Wastewater Treatment—Conversion Technologies and Applications

Modelling the energy balance of an anaerobic digester fed with cattle manure and renewable energy crops

Biogas from grass silage – Measurements and modeling with ADM1

An integrated 45 L pilot microbial fuel cell system at a full-scale wastewater treatment plant

Microbiological fermentation of lignocellulosic biomass: current state and prospects of mathematical modeling

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