Add to ORKGA reaction engineering model is presented for the bioproduction of chemicals associated with the growth of immobilized biomass in or around carriers. The model describes multiple-substrate diffusion limitations and first-order growth inhibition by one of the products. Analytical solutions are presented for intra-biofilm substrate and product concentrations, active biofilm thickness, biocatalyst effectiveness factor and degree of catalyst utilization. Simple criteria for optimal catalyst design are derived. Where applicable, the presented explicit analytical solutions for the biocatalyst effectiveness factor are much more convenient to incorporate into a macro-reactor model than the numerical alternatives
Microbial conversions are generally inhibited by their products. This product inhibition is particul...
Microbial conversions are generally inhibited by their products. This product inhibition is particul...
Analytical expressions of the effectiveness factor of a biocatalytic membrane reactor, and its asymp...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
A reaction engineering model for the degradation of an inhibitory substrate by a steady-state biofil...
A reaction engineering model for the degradation of an inhibitory substrate by a steady-state biofil...
Microbial conversions are generally inhibited by their products. This product inhibition is particul...
Microbial conversions are generally inhibited by their products. This product inhibition is particul...
Analytical expressions of the effectiveness factor of a biocatalytic membrane reactor, and its asymp...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
A reaction engineering model is presented for the bioproduction of chemicals associated with the gro...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
An analytical reaction engineering model, recently presented by van Ede et al. (1992), which describ...
A reaction engineering model for the degradation of an inhibitory substrate by a steady-state biofil...
A reaction engineering model for the degradation of an inhibitory substrate by a steady-state biofil...
Microbial conversions are generally inhibited by their products. This product inhibition is particul...
Microbial conversions are generally inhibited by their products. This product inhibition is particul...
Analytical expressions of the effectiveness factor of a biocatalytic membrane reactor, and its asymp...