where % CD is the percentage change

where % CD is the percentage change in Crosslink density of resin,
ΔH ðUF=AC resinÞ is the heat evolution during curing of UF/AC
resins and ΔH ðUF resinÞ is the heat evolution during curing of
UF resin.
Fig. 2 The heat evolution or enthalpy of reaction (ΔH) during
the curing of resins are calculated from the area under the
endothermic curve at 10 1C/min heating rate using DSC. In the
present study, additional heat evolution can be attributed to extra
Crosslink reactions occur due to the presence of activated charcoal
in UF resin. The Crosslink density of UF resin improved by 19, 36
and 49% with increasing concentration of activated charcoal as
shown in Table 3. The possible reasons for enhanced in cross-link
density is that the charcoal contains a large amount of reactive
carbonyl group and these carbonyl groups formed covalent bonding
with UF resin and increased the of amount of –CH2–O–CH2–
linkages in UF resin. The area under the peaks in DSC analysis
(i.e. enhanced in reaction enthalpy, ΔH) is directly proportional to
the –CH2–O–CH2– linkages in UF resin [20].
3.3. FTIR analysis
The functional groups suggested in AC are carboxyl groups,
phenolic hydroxyl groups, carbonyl groups and location groups
[21]. The FTIR spectra of net activated charcoal is shown in Fig. 3.
The C–OH stretching mode and the bending mode can be found at
3401 cm−1 and 1561 cm−1, respectively. The peak occurs at
1125 cm−1 is characteristics of C–O is stretching in lactonic,
alcoholic groups and carboxylate moieties [22].
The FTIR spectra of UF and UF/AC resins are shown in Fig. 4 and
Table 4. The spectrum of UF/AC resins shows a strong absorption
band between at 3420–3453 cm−1 region and 3421 cm−1 for pure
sample. These are the charteristics absorption bands of hydrogen
bonded N–H of –NH2, formed due to the methylenization reaction
happen during cross-linking [23]. The weak absorption band in all
resins appear near 2962–2963 cm−1, which describes the symmetrical
C–H stretching mode of CH2 of ether, CH2OH and N–CH2.
The strong absorption band is observed in the spectra, near
1640, 1645,1638 and 1639 cm−1 for AC0, AC1, AC2 and AC3
respectively, assigned to the stretching C¼0 (amide-I) in –CONH2
group. The very strong absorption bands around 1536, 1538 and
1544 for AC0, AC1 and AC2 respectively, it may be due to –NH
(amide II) are assigned. The stretching vibrations around 1350–
1400 cm−1 for resin samples, represent by the C–H bending mode
in CH2/CH2OH/N–CH2–N. The intermediate absorption band in
the around 1121–1140 cm−1 may appear due to stretching vibrations
of –N–CH2–N– group of the ether linkage. Bands around
775–780 cm−1 due to stretching vibrations of C–O in –CH2OH,
N–H stretch in 11 and 21 amines. The weak absorption bands near