Modelling hydrolysis: Simultaneous versus sequential biodegradation of the hydrolysable fractions

6533b852fe1ef96bd12aac3d

RESEARCH PRODUCT

Modelling hydrolysis: Simultaneous versus sequential biodegradation of the hydrolysable fractions

Julie Jimenez Damien J. Batstone ÁNgel Robles ÁNgel Robles Aurora Seco Fabrice Béline Cyrille Charnier Peter A. Vanrolleghem Mathieu Spérandio Eberhard Morgenroth Eberhard Morgenroth Eric Latrille Jérôme Harmand Dominique Patureau George Ekama Mokhles Kouas Jean-philippe Steyer Michel Torrijos

subject

[SDV.BIO]Life Sciences [q-bio]/Biotechnology Biosolids SEQUENTIAL EXTRACTION ANAEROBIC DIGESTION BIODEGRADATION 02 engineering and technology 010501 environmental sciences TRITICUM AESTIVUM 01 natural sciences 7. Clean energy NUMERICAL MODEL SLUDGE DIGESTION Bioreactors METHANE BIOLOGICAL MATERIALS ACTIVATED SLUDGE 0202 electrical engineering electronic engineering information engineering Anaerobiosis Sequential model PRIORITY JOURNAL Waste Management and Disposal ComputingMilieux_MISCELLANEOUS CALIBRATION Sewage CONCENTRATION (PARAMETER)Chemistry FRACTIONATION ACID HYDROLYSIS INCUBATION TIME MODELLING HYDROLYSIS CHEMICAL FRACTIONATION SEQUENTIAL DEGRADATION Biodegradation Environmental WASTE TREATMENT ORGANIC MATTER [SDE]Environmental Sciences ANAEROBIC DIGESTION MODEL ADM1 SOLID WASTE 020209 energy MODELS Fractionation CAPACITY Hydrolysis DIGESTION ISOTOPIC FRACTIONATION NONHUMAN CHEMICAL OXYGEN DEMAND ARTICLE MODEL SELECTION 0105 earth and related environmental sciences Chromatography Models Theoretical SUBSTRATES Biodegradation SIMULTANEOUS DEGRADATION HOMOGENEOUS MATERIALS Anaerobic digestion WASTE WATER MANAGEMENT Activated sludge APPLE Degradation (geology)

description

Hydrolysis is considered the limiting step during solid waste anaerobic digestion (including co-digestion of sludge and biosolids). Mechanisms of hydrolysis are mechanistically not well understood with detrimental impact on model predictive capability. The common approach to multiple substrates is to consider simultaneous degradation of the substrates. This may not have the capacity to separate the different kinetics. Sequential degradation of substrates is theoretically supported by microbial capacity and the composite nature of substrates (bioaccessibility concept). However, this has not been experimentally assessed. Sequential chemical fractionation has been successfully used to define inputs for an anaerobic digestion model. In this paper, sequential extractions of organic substrates were evaluated in order to compare both models. By removing each fraction (from the most accessible to the least accessible fraction) from three different substrates, anaerobic incubation tests showed that for physically structured substrates, such as activated sludge and wheat straw, sequential approach could better describe experimental results, while this was less important for homogeneous materials such as pulped fruit. Following this, anaerobic incubation tests were performed on five substrates. Cumulative methane production was modelled by the simultaneous and sequential approaches. Results showed that the sequential model could fit the experimental data for all the substrates whereas simultaneous model did not work for some substrates. © 2019

year	journal	country	edition	language
2018-12-06	Waste Management

https://doi.org/10.1016/j.wasman.2019.10.004