Chemostat Biomass Calculation

Saccharomyces cerevisiae in continuous fermentation reaches steady state when the specific growth rate equals the dilution rate. Given parameters allow direct computation of steady-state biomass concentration using Monod kinetics and yield coefficient.

Key Equations

At steady state in a chemostat with sterile feed and negligible maintenance:

• Specific growth rate μ = dilution rate D = 0.5 h^-1
• Monod equation: μ = μm × S / (K_s + S), where μm = 0.7 h^-1, K_s = 0.3 g·L^-1
• Biomass balance: X = Y_x/s × (S_in – S), where Y_x/s = 0.4 g biomass/g substrate, S_in = 10 g·L^-1

Step-by-Step Solution

Solve for steady-state substrate concentration S first.

Substitute into Monod:

0.5 = 0.7 × S / (0.3 + S)

Rearrange:

0.5(0.3 + S) = 0.7S

0.15 + 0.5S = 0.7S

0.15 = 0.2S

S = 0.75 g·L^-1

Now compute biomass X:

X = 0.4 × (10 – 0.75) = 0.4 × 9.25 = 3.7 g·L^-1

Verification Assumptions

Sterile feed eliminates inflow biomass, simplifying to X = Y_x/s (S_in – S). Negligible maintenance ignores non-growth substrate use. Yield Y_x/s defined per substrate consumed aligns with standard chemostat models for Saccharomyces cerevisiae under glucose limitation.

SEO Content

Saccharomyces cerevisiae chemostat biomass concentration determines continuous fermentation efficiency in biotechnological processes like ethanol production. This Saccharomyces cerevisiae chemostat calculation uses Monod kinetics for precise steady-state prediction.

Monod Kinetics Application

In continuous fermentation, Saccharomyces cerevisiae growth balances dilution. At D = 0.5 h^-1, solve μ = D to find S = 0.75 g·L^-1, then X = 3.7 g·L^-1 using yield coefficient.

Practical Implications

Optimizes bioreactor design for microbial biotechnology, matching user expertise in fermentation kinetics and biochemical engineering.

GATE-Style Problem Insight

Identical to 2016 GATE Biotechnology question, confirming 3.7 as correct fill-in value.