The pillared clays (PILCs) are very

The pillared clays (PILCs) are very promising catalyst support
due to their two-dimensional zeolite-like structure, adjustable pore
size, high thermal stability, and exchangeable acidity. The
PILC based catalysts have a broad range of application, such as the
removal of heavy metal from wastewater, the photodecomposition
of pollutants and the(SCR) of NOx

The PILCs could be prepared by exchanging the chargecompensating
cations of the clays with large inorganic cations
of metallic salts [9,10]. The most applied pillaring agent is polyoxocation
(Al, Ti, Ni, Zr, Fe, Cr, Mg, Cu, etc.) [9–11]. The metal
hydroxyl cations could form stable metal oxide clusters after thermal
treatment and provide pillared clays with large well defined
spaces between layers. Moreover, the pillared clays have been
enhanced with special properties, such as catalytic activity and
adsorption strength
metal is increased by the use of the aluminum-pillared clay and
the pillar makes more contribution to removing metal than the clay
[14]. Also, the nanosize of the titania pillar in Ti–PILC is very important
to develop catalytic activity in the photo-catalyst system and
the pillar causes a blue shift with respect to anatase TiO2 [15].Moreover,
the introduction of the metal pillar into the catalyst improves
the catalytic activity in SCR of NOx by NH3 system, which is due to
the increase of the surface acid of the catalysts [16]. However, little
attention has been directed toward the role of the titania pillar in
SCR of NO by propylene.
The objective of this work is to further investigate the influence
of the titania pillar on the properties of Cu-Ti-PILC and their
catalytic activity in the SCR reaction of NO by propylene as a
function of the Ti/clay rate. The XRD, N2 adsorption, TPR and
NO+O2-TPD techniques were employed to characterize the studied
catalysts.