A new method of following sorption/desorption rates in zeolite crystal
s by monitoring the transient response of the surface temperature by i
.r. has been developed. Unlike conventional sorption rate measurements
, this method is not limited to isothermal or quasi-isothermal conditi
ons, and the rapid response of the i.r. detector means that the method
can be applied to study relatively fast systems. The shape of the res
ponse curves can provide useful information concerning the nature of t
he mass-transfer resistance, thus allowing the intrusion of a surface
barrier to be detected. The validity of this technique has been confir
med by a detailed study of sorption/desorption rates for methanol in N
aX crystals. At room temperature, the results obtained by the new meth
od are consistent with the data obtained, for the same system, by both
zero-length column (ZLC) and pulsed field gradient (PFG) n.m.r. self-
diffusion measurements. The PFG n.m.r. data show an unusual variation
of self-diffusivity and activation energy with loading; the limiting a
ctivation energy, extrapolated to zero loading, agrees well with the Z
LC value (11 kJ/mol). Sorption rates in successive experiments, after
''regeneration'' at 300-degrees-C, show a regular decline accompanied
by an increasing surface resistance to mass transfer. This was attribu
ted to a slow buildup of ''coke'' at the crystal surface.