assigned to the stretching vibratio

assigned to the stretching vibration of theC=Nbond (imine bond).Two other newbands
appear at 1,680 and 1,607 cm-1 which are due to the remaining aldehyde C=O group
and the stretching vibration of C=C bonds of the phenyl ring, respectively.
The presence of the chiral half unit of salen anchored on silica can be shown
(Fig. 3, curve d) by the disappearance of the band at 1,680 cm-1 due to the
subsequent condensation of the remaining aldehyde C=O group with one amino group in the (1R,2R)-(-)-1,2-diaminocyclohexane chiral auxiliary. This is supported
by the increase of the intensity of the band assigned to the stretching
vibration of the C=N bond and the appearance of a new band at 1,390 cm-1 due to
C–N stretching frequency.
The comparison of the spectra of the free chiral salen ligand and sample 7 showed
evidence of the immobilization of the chiral salen ligand over the support (Fig. 3,
curves e and f), since the three most characteristic bands of the free chiral salen ligand
appeared in IR spectrum of silica supported chiral salen ligand. These bands are
attributed to C–N stretching frequency at 1,390 cm-1 and to the stretching vibrations
of C=N and C=C bonds which are slightly shifted from 1,630 and 1,595 cm-1 to
1,640 and 1,607 cm-1, respectively, for the immobilized chiral salen ligand.On coordination of the immobilized chiral salen ligand to the vanadyl group, the
characteristic bands of the metal salen complex appearing at 1535, 980 and
561 cm-1 are assigned to the stretching frequency of C=N, V=O and V–N bands,
respectively (Fig. 4). These bands are absent in the free and immobilized chiral
salen ligand (Fig. 4, curve c) but can be clearly observed for the VO(salen)
complexes either free (Fig. 4, curve a) or anchored on the silica (Fig. 4, curve b).
The solid reflectance UV–vis spectrum (Fig. 5) also supported successful
coordination of the immobilized salen ligand with the vanadyl group, since the
spectrum of the VO(salen) complex supported on silica (curve b) is similar to that of
the homogeneous complex (curve a). The characteristic charge transfer bands of
homogenous VO(salen) complex are present in the immobilized complex spectrum,
but the bands are slightly shifted from 360, 390 and 412 nm to 368, 394 and
417 nm, in order. The d–d transition band near 630 nm was also observed in the
immobilized complex spectrum though with a lower resolution than that for the
transmission spectrum of homogenous VO(salen) complex.The N2 adsorption–desorption isotherms and the corresponding BJH pore size
distributions based on the desorption branch for the silica samples are shown in Figs. 6
and 7. The nitrogen isotherm of the untreated silica sample shows a sharp capillary
condensation step at a relative pressure from 0.7 indicating a mesoporous structure of
the silica with a uniform pore size distribution. Compared to the untreated silica
sample, the aminopropylsilyl-functionalized silica and Si–VO(salen) show a significant
change in theN2 adsorption–desorption isothermand the pore size distribution.A
large decrease in BET surface area was observed on functionalization of modified
silica, with a reduction in the pore diameter and pore volume, suggesting that
VO(salen) complex is present inside the pores of the support material (see Table 1)