Biomethane is a renewable product that can directly substitute its fossil counterpart, although its synthesis from residual biomasses has some hurdles. Because of the complex nature of both biomasses and the microbial consortia involved, innovative approaches such as mathematical modeling can be deployed to support possible improvements. The goal of this study is two-fold, as we aimed to modify a part of the Anaerobic Digestion Model No. 1 (ADM1), describing biomethane production from activated sludge, matching with its actual microbial nature, and to use the model for identifying relevant parameters to improve biomethane production. Firstly, thermodynamic analysis was performed, highlighting the direct route from glucose to biomethane as the most favorable. Then, by using MATLAB® and Simulink Toolbox, we discovered that the model fails to predict the microbiological behavior of the system. The structure of the ADM1 model was then modified by adding substrate consumption yields in equations describing microbial growth, to better reflect the consortium behavior. The updated model was tested by modifying several parameters: the coefficient of decomposition was identified to increase biomethane production. Approaching mathematical models from a microbiological point of view can lead to further improvement of the models themselves. Furthermore, this work represents additional evidence of the importance of informatics tools, such as bioprocess simulations to foster biomethane role in bioeconomy.

Bertacchi, S., Ruusunen, M., Sorsa, A., Sirviö, A., Branduardi, P. (2021). Mathematical Analysis and Update of ADM1 Model for Biomethane Production by Anaerobic Digestion. FERMENTATION, 7(4) [10.3390/fermentation7040237].

Mathematical Analysis and Update of ADM1 Model for Biomethane Production by Anaerobic Digestion

Bertacchi, Stefano
Primo
;
Branduardi, Paola
2021

Abstract

Biomethane is a renewable product that can directly substitute its fossil counterpart, although its synthesis from residual biomasses has some hurdles. Because of the complex nature of both biomasses and the microbial consortia involved, innovative approaches such as mathematical modeling can be deployed to support possible improvements. The goal of this study is two-fold, as we aimed to modify a part of the Anaerobic Digestion Model No. 1 (ADM1), describing biomethane production from activated sludge, matching with its actual microbial nature, and to use the model for identifying relevant parameters to improve biomethane production. Firstly, thermodynamic analysis was performed, highlighting the direct route from glucose to biomethane as the most favorable. Then, by using MATLAB® and Simulink Toolbox, we discovered that the model fails to predict the microbiological behavior of the system. The structure of the ADM1 model was then modified by adding substrate consumption yields in equations describing microbial growth, to better reflect the consortium behavior. The updated model was tested by modifying several parameters: the coefficient of decomposition was identified to increase biomethane production. Approaching mathematical models from a microbiological point of view can lead to further improvement of the models themselves. Furthermore, this work represents additional evidence of the importance of informatics tools, such as bioprocess simulations to foster biomethane role in bioeconomy.
Articolo in rivista - Articolo scientifico
Anaerobic digestion; Bioeconomy; Biomethane; Biorefinery; Differential equa-tions; Mathematical modeling;
English
21-ott-2021
2021
7
4
237
open
Bertacchi, S., Ruusunen, M., Sorsa, A., Sirviö, A., Branduardi, P. (2021). Mathematical Analysis and Update of ADM1 Model for Biomethane Production by Anaerobic Digestion. FERMENTATION, 7(4) [10.3390/fermentation7040237].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/331683
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