tion Ð particularly at high tempera

tion Ð particularly at high temperatures when the
saturation concentration of dissolved oxygen is
much lower. Several researchers, however, have
concluded that the e€ect of temperature on oxygen
transfer is essentially negligible (Boogerd et al.,
1990; Wynn et al., 1997). The concomitant changes
in physical±chemical parameters of water, such as
viscosity and di€usivity, improve the overall mass
transfer rate to o€set the e€ect of reduced oxygen
solubility. The apparent success of numerous fullscale
ATAD processes indicates that commercially
available aeration equipment is able to supply the
necessary oxygen to sustain treatment, although this
has not been extensively discussed in the technical
literature. Rozich and Colvin (1997) have recommended
utilizing aggressive aeration equipment
and greater tank depth to accommodate the potential
enormous oxygen requirements of thermophilic
treatment processes. The simultaneous requirements
for rapid and high eciency oxygen transfer make
the selection of aeration equipment one of the most
critical process design choices.
High reactor temperatures also reduce the surface
tension of water, perhaps leading to a foaming nuisance.
Coincidentally, excess foam production is
often associated with process instability, which is
the primary reason thermophilic aerobic systems
have a reputation for stability problems (Rozich
and Colvin, 1997). At thermophilic temperatures,
however, foaming does not necessarily indicate a
process upset because of this reduced surface tension.
Foaming in thermophilic aerobic reactors has
also been associated with high cell concentrations
(Rozich and Colvin, 1997; LaPara et al., 1998).
Extreme care should be exercised in selecting a
method to reduce foaming problems to ensure that
gas transfer eciency (and thus process performance)
is not adversely a€ected. The solubility of carbonate
salts (e.g., CaCO3 and MgCO3) is also
reduced at higher reactor temperatures, perhaps
leading to the production of an inorganic byproduct.
Although this precipitation is also partially
controlled by reactor pH, chemical thermodynamics
also dictates that the equilibrium chemistry is
a€ected by temperature such that the speciation of
the inorganic-carbon ions favors carbonate at a
lower pH compared to mesophilic temperatures.
The unique water characteristics at thermophilic
temperatures and their potential e€ects on treatment
processes are summarized in Table 5.
The common trait of thermophilic bacteria to
proliferate as discrete cells instead of forming dense
¯oc particles clearly represents a unique challenge
for biomass separation. Two options are to simply
operate biological reactors without cell recycle or to
design a membrane-coupled biological system.
Operation without sludge recycle limits the overall
eciency of the system, and further treatment is
still required to remove thermophilic cells from the
e‚uent prior to discharge. This process alternative
is potentially useful as a preliminary step prior to
further biological treatment (LaPara et al., 1998).
The membrane-coupled treatment system is attractive
in that very high sludge ages can be maintained,
although economic considerations may limit
its use. The problem of biofouling, which is often
associated with membrane-coupled reactors, however,
may be less of a burden because of the same
physiological characteristics of thermophiles preventing
them from forming ¯oc particles. This
alternative has been previously used to treat a land-
®ll leachate waste (Colvin et al., 1996).
The unique nutritional requirements of thermophilic
bacteria studied in pure culture are likely responsible
for the varying success of previous
researchers treating di€erent wastes at di€erent temperatures.
The researchers reporting good results
generally treated complex wastes likely to contain
sucient micronutrients (e.g., manure, blood, etc.),
or provided supplemental nutrients. For research
purposes, the addition of complex nutrient broths,
such as peptone or yeast extract, is usually sucient
to enable biodegradation of most readily degradable
compounds. Further work is necessary to identify
speci®c nutrient supplements suitable for full-scale
operation.