18.4 Factors Affecting Biohydrogen
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18.4.4
Substrates
Like other biofuels, biohydrogen generated by the biological route is also highly
influenced by the type of substrate, availability, and cost of substrate. Among all
fermentation routes, dark fermentation has received enormous popularity due to
its ability to utilize a wide range of feedstock. Hydrogen-producing microbes can
metabolize both simple carbons like reducing sugars (glucose/xylose) obtained by
pretreatment and saccharification of lignocellulosic biomass and complex substrates
like starch, sucrose, and wastewater through dark fermentation. Hydrogen is clean
energy, and its production from waste further makes this process an economically
attractive concept for large-scale production. Table 18.2 lists various substrates
(simple and complex) used by different microbes for hydrogen production. Several
studies have demonstrated that it is essential to determine the optimum range of
a substrate for fermentative H2 production, as increasing substrate concentration
beyond the optimum range may inhibit the growth of H2-producing bacteria, which
would eventually result in a decrease in H2 yield. This is because the active sites
of enzymes catalyzing H2 production are saturated with a particular concentration
of substrate, beyond which may result in enzyme inhibition or substrate inhibition
kinetics.
18.4.5
Type of Reactor
The yield and production rate of H2 by biological routes highly depend on the vessel
used for fermentation. In order to attain the required rate of production, it is essential
to operate under controlled ambient conditions, which can be achieved by using an
automated bioreactor. Apart from this, reactor configuration and mode of operation
also play an essential role in maximizing the production rates. Biohydrogen reactors
can be operated under the following modes of operations, viz. batch, fed-batch, and
continuous.
18.4.5.1
Batch Mode
The batch process is the most widely used mode of operation for biohydrogen
production from various feedstocks operated under a wide range of operating condi-
tions. In the batch process, strain cultivation is carried out in closed vessels, which
offers many advantages such as simple configuration, ease in monitoring substrate
utilization, and effect of physical factors on H2 production. Several studies have been
reported on batch fermentation for H2 production by different species of Escherichia,
Clostridium, Enterobacter, Archaea, Rhodopseudomonas, and Rhodobacter. Under
batch operation, E. cloacae DM 11 and Caldicellulosiruptor owensensis have reported
the highest hydrogen yield (YH2∕S) of 3.9 and 4.0 mol-H2/mol-substrate, respectively.
Clostridium is the most studied organism for biohydrogen production via dark
fermentation, showing a hydrogen evolution rate of 27 mmol/l/h [32, 33]. Batch
fermentation with other species of Clostridium reported a maximum H2 yield of 3.35
and 2.3 mol-H2/mol-glucose [34]. Under a similar mode of operation, a maximum
hydrogen yield of 6.63 mol-H2/mol-sucrose was achieved by using Rhodobacter