A CHEMOSTAT WITH MAGNETIC FEEDBACK FOR THE GROWTH OF SULFATE-REDUCINGBACTERIA AND ITS APPLICATION TO THE REMOVAL AND RECOVERY OF HEAVY-METALS FROM SOLUTION
Jhp. Watson et al., A CHEMOSTAT WITH MAGNETIC FEEDBACK FOR THE GROWTH OF SULFATE-REDUCINGBACTERIA AND ITS APPLICATION TO THE REMOVAL AND RECOVERY OF HEAVY-METALS FROM SOLUTION, Minerals engineering, 9(9), 1996, pp. 973-983
Citations number
17
Categorie Soggetti
Engineering, Chemical","Mining & Mineral Processing",Mineralogy
This paper describes a ''magnetic feedback chemostat'' for decontamina
ting various heavy metal solutions, from industrial sources, with dire
ct precipitation as metallic sulphides or with bacterially-produced Fe
S magnetic adsorbents. The proposal has implications for dramatically
improving the economics of this biomagnetic separation process. Variat
ions in magnetic susceptibility of FeS in the region of compositional
interest, on the S-rich of 50-50 atomic %, can reduce the cost of heav
y metal extraction by a factor of 50-fold. Appreciable variations in t
he magnetic properties of the bacterial-FeS occur and this leads to a
variability of the overall process rate through the magnetic separator
which affects the cost. The problem is that under a particular set of
conditions produced by the solution to be treated, the bacteria which
produce the most magnetic product are outgrown by those with a less m
agnetic product. To select the desired bacteria which produce a strong
ly magnetic adsorbent, the method proposed is to grow, at various dilu
tion rates, a mixed culture of sulphate reducing bacteria (SRB) in the
solution to be treated in a chemostat. This will be used to treat an
influent df heavy metals and other compounds from polluted industrial
sources. Nutrient plus sufficient Fe will be added to the influent for
the growth of the SRB together with the production of the FeS adsorbe
nt. The overflow from the chemostat will go to a Vortex magnetic separ
ator in which the magnetic FeS and the associated SRB are retuned to t
he chemostat. The bacteria producing the required magnetic product wil
l therefore be selected and preferentially multiplied in the chemostat
, This method will yield SRB producing the desired product starting fr
om inocula obtained from various natural sources, In this way differen
t bacterial consortia will be selected, appropriate to each industrial
requirement. Copyright (C) 1996 Elsevier Science Ltd