vibrational mode at 569 cm
¹ and 602 cm
¹ and 1039 cm
¹. Similarly, MgHA

showed decreased intensities of OH
vibrations at 3568 cm
¹ and 633 cm
¹ and

significant broadening at 700–1700 cm
¹ for PO4

3
. In EuHA nanopowder, all the

characteristic peaks of hydroxyapatite were observed but with decreased transmit-

tance. In FHA nanopowder, OH
vibrations at 3569 cm
¹ and 631 cm
¹ were

absent. The characteristic band of OH...F...OH appeared at 721 cm
¹. In SiHA and

KSiHA nanopowders, bands corresponding to orthosilicate group appeared at

504 cm
¹ and 892 cm
¹, respectively. In MgSrHA nanopowder, phosphate bands

of ν1 PO4

3
and ν4 PO4

3
shifted towards lower frequency. The weak absorption

peak at 875 cm
¹ attributed to P-O-H vibration of HPO4

2
was also observed.

However, the band of OH...F...OH appeared at 716–727 cm
¹ in ZnFHA, SrFHA,

and MgSrFHA nanopowders.

The FTIR spectra of all heat-treated nanopowders showed almost similar patterns

with decreased intensities. On heat treatment of ZnFHA nanopowders, the loss in

intensity of the hydroxyl groups was observed around 3570 cm
¹ (Fig. 23.7).

The vibration at 874 cm
¹ related to P-O-H in HPO4

2
disappeared on heat

treatment, whereas peaks of phosphate became strong. In heat-treated ZnFHA

nanopowders, bands ascribed to configuration FFOHFF were seen at 740 cm
¹. In

SiHA and KSiHA heat-treated nanopowders, orthosilicate group (ν1 symmetric stretch,

~752 cm
¹; ν2 bending, ~504 cm
¹; ν3 asymmetric stretch, ~892 cm
¹) was observed.

23.5.3 Thermal Stability of Novel Hydroxyapatites

The thermal behavior of as-synthesized HA and FHA nanopowders was investigated

by thermogravimetric (TGA)/differential scanning calorimetry (DSC)/differential

thermogravimetric (DTG) techniques. The approximate weight of samples taken

Fig. 23.6 FTIR spectra of as-synthesized fluorine-substituted hydroxyapatite nanopowder

440

S. Kapoor et al.