Lec-24 Adsorption.

Although adsorption has been used as a physical-chemical process for many years, it is

only over the last four decades that the process has developed to a stage where it is now

a major industrial separation technique. In adsorption, molecules distribute themselves

between two phases, one of which is a solid whilst the other may be a liquid or a gas.

The only exception is in adsorption on to foams, a topic which is not considered in this

chapter.

Unlike absorption, in which solute molecules diffuse from the bulk of a gas phase to

the bulk of a liquid phase, in adsorption, molecules diffuse from the bulk of the fluid to

the surface of the solid adsorbent forming a distinct adsorbed phase.

Typically, gas adsorbers are used for removing trace components from gas mixtures.

The commonest example is the drying of gases in order to prevent corrosion, condensation

or an unwanted side reaction. For items as diverse as electronic instruments and biscuits,

sachets of adsorbent may be included in the packaging in order to keep the relative

humidity low. In processes using volatile solvents, it is necessary to guard against the

incidental loss of solvent carried away with the ventilating air and recovery may be

effected by passing the air through a packed bed of adsorbent.

Adsorption may be equally effective in removing trace components from a liquid phase

and may be used either to recover the component or simply to remove a noxious substance

from an industrial effluent.

Any potential application of adsorption has to be considered along with alternatives

such as distillation, absorption and liquid extraction. Each separation process exploits

a difference between a property of the components to be separated. In distillation, it

is volatility. In absorption, it is solubility. In extraction, it is a distribution coefficient.

Separation by adsorption depends on one component being more readily adsorbed than

another. The selection of a suitable process may also depend on the ease with which the

separated components can be recovered. Separating n- and iso-paraffins by distillation

requires a large number of stages because of the low relative volatility of the components.

It may be economic, however, to use a selective adsorbent which separates on the basis

of slight differences in mean molecular diameters, where for example, n- and iso-pentane

have diameters of 0.489 and 0.558 nm respectively. When an adsorbent with pore size of

0.5 nm is exposed to a mixture of the gases, the smaller molecules diffuse to the adsorbent

surface and are retained whilst the larger molecules are excluded. In another stage of the

process, the retained molecules are desorbed by reducing the total pressure or increasing

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