126 Chapter Four
Box 4.15 Use of clay catalysts in clean up of environmental contaminationThe interaction between some organic
contaminants and mineral surfaces has
recently attracted attention as a way of
cleaning up contaminants in natural waters.
The large cation exchange capacity of
smectite clay minerals (Section 4.5.2), in
particular, has prompted research into their
use as a catalyst, i.e. a substance that alters
the rate of a chemical reaction without itself
changing. Clay catalysts have potential
applications as adsorbents to treat
contaminated natural waters or soils.
The compound 2,3,7,8-tetrachlorodibenzo-
p-dioxin is one of the most toxic priority
pollutants on the US Environmental
Protection Agency’s list. Dioxin compounds
act as nerve poisons and are extremely toxic.
There is no lower limit at which dioxins are
considered safe in natural environments.
The destruction of dioxins by biological,
chemical or thermal means is costly, not least
because their low (but highly significant)
concentrations are dispersed in large volumes
of other (benign) material. Thus large
volumes of material must be treated in dioxin
destruction processes.
It is desirable to concentrate soluble
contaminants like dioxin by adsorption on
to a solid before destruction. The optimal
solid adsorbent should be cheap, benign,
recyclable and easy to handle and have a
high affinity for—and be highly selective to- the contaminant. Finely ground activated
carbon and charcoal have been used as
adsorbents but they suffer from oxidation
during thermal destruction of the
contaminant, making them non-recyclable
and expensive.
Smectite clay catalysts are potential
alternative adsorbents, although some
modifications of the natural mineral are
necessary. Interlayer sites in smectite
dehydrate at temperatures above 200°C,
collapsing to an illitic structure. Since the ion-
exchange capacity of smectite centres on the
interlayer site, collapse must be prevented if
clay catalysts are to be used in thermal
treatments of chemical organic toxins. The
intercalation of thermally stable cations,
which act as molecular props or pillars, is one
T
T
OT
T
OT
T2 : 1package OAl 13 O 4 (OH) 28
pillars or props3+Fig. 1Schematic diagram showing props or pillars in
the interlayer position in smectite clay. T,
tetrahedral sheet; O, octahedral sheet.method of keeping the interlayer sites open
in the absence of a solvent like water (Fig. 1).
Various pillaring agents can be used, for
example the polynuclear hydroxyaluminium
cation (Al 13 O 4 (OH)^328 +), which is stable above
500°C.
The pillar also increases the internal
surface area of the interlayer site, making it
more effective as an adsorbent. Moreover, by
introducing cationic props of different sizes
and spacings (spacing is determined by the
radius of the hydrated cation and the
charge), it is possible to vary the size of
spaces between props. It is thus possible to
manufacture highly specific molecular sieves,
which could be used to trap large ions or
molecules (e.g. organic contaminants) whilst
letting smaller, benign molecules pass
through.
Smectite clays do not have a strong
affinity for soluble organic contaminants and
this is improved using a surface-active agent
(surfactant). A surfactant is a substance
introduced into a liquid to affect (usually to
increase) its spreading or wetting properties
(i.e. those properties controlled by surface
tension). Detergents and soaps are examples
of surfactants. A soap molecule has two
features essential for its cleansing action: a
long, non-polar hydrocarbon chain and a(continued)