| Literature DB >> 27516944 |
Mohammad Zulhasif Ahmad Khiri1, Khamirul Amin Matori1, Norhazlin Zainuddin2, Che Azurahanim Che Abdullah3, Zarifah Nadakkavil Alassan3, Nur Fadilah Baharuddin1, Mohd Hafiz Mohd Zaid3.
Abstract
This paper reported the uses of ark clam shellEntities:
Keywords: Ark clam shell; Hydroxyapatite; Sintering; Structural; Wet chemical precipitate
Year: 2016 PMID: 27516944 PMCID: PMC4967056 DOI: 10.1186/s40064-016-2824-y
Source DB: PubMed Journal: Springerplus ISSN: 2193-1801
Recent studies of synthesis HA powder from waste and various method in period of 2010–2015
| References | Raw material | Method | pH value | Powder properties |
|---|---|---|---|---|
| Venkatesan and Kim ( | Tuna bone | Drying | – | Pure HA in nano-sized range |
| Wu et al. ( | Oyster shell | Ball mailing and heat treatment | – | HA and β-TCP composition in the sample |
| Singh and Purohit ( | Garden Snail | Wet chemical precipitate | 10 | Pure HA in micron-sized range |
| Santhosh and Prabu ( | Sea shell | Wet chemical precipitate | 10 | Pure HA in nano-sized range |
| Rujitanapanich et al. ( | Oyster shell | Wet chemical precipitate | 8–10 | Improve crystallinity of HA at pH value of 10. |
| Kamalanathan et al. ( | Eggshell | Wet chemical precipitate | 10.5 and above | Pure HA at low temperature and present of α-TCP and TTCP at high temperature |
| Wu et al. ( | Eggshell | Wet chemical precipitate | – | HA/β-TCP biphase at low temperature and pure HA at high temperature |
| Chen et al. ( | Abalone shell | Solid-state conversion | 10 | Mix of HA, calcite and aragonite composition in the sample. HA nanorod is obtained |
| Yelmilda et al. (2015) | Cockle shell | Hydrothermal | 10–11 | Pure HA in nano-sized range and no toxic effect |
| Shavandi et al. ( | Mussel shell | Rapid microwave irradiation | 13 | Pure HA in nano-sized range |
| This study | Ark clam shell | Wet chemical precipitate | 8 | Pure HA as-synthesized and nano-sized range. HA/β-TCP biphase composition was present at high temperature |
Fig. 1X-ray diffraction of the a ark clam shell and b calcined clam shell at 900 °C for 4 h
Fig. 2FTIR spectrum of ark clam shell and calcined ark clam shell at 900 °C for 4 h
FTIR vibration modes of Clam shell powder and references
| Assignments | Vibrational frequencies (cm−1) | |||
|---|---|---|---|---|
| FTIR result | Gunasekaran et al. ( | Islam et al. ( | Hoque et al. ( | |
|
| 708 | 712 | 706 | 705 |
|
| 855 | 874 | 857 | 853 |
| Symmetric stretching vibration of CO3 2− | 1082 | – | 1082 | 1080 |
|
| 1454 | 1425 | 1455 | 1421 |
|
| 1786 | 1798 | 1794 | – |
| 2 | 2520 | 2514 | – | – |
| H2O stretching mode | 3743 | – | 3378 | – |
FTIR vibration modes of calcined ark clam shell powder and references
| Assignments | Vibrational frequencies (cm−1) | |||
|---|---|---|---|---|
| FTIR result | Singh and Purohit ( | Rujitanapanich et al. ( | Chen et al. ( | |
|
| 1456 | 1422 | 1416 | 874, 1418, 1462 |
|
| 3480 | 3431 | – | – |
|
| 3742 | – | 3642 | 3567 |
Fig. 3XRD patterns of sintered HA at different temperature for 4 h: a 200 °C, b 600 °C, c 800 °C, d 1000 °C, e 1100 °C and f 1200 °C
Fig. 4FTIR spectrum of sintered HA between 200 and 1200 °C for 4 h: a 200 °C, b 600 °C, c 800 °C, d 1000 °C, e 1100 °C, and f 1200 °C
FTIR vibration modes of HA sintered at 200 °C and references
| Assignments | Vibrational frequencies (cm−1) | |||
|---|---|---|---|---|
| FTIR result | Salma et al. ( | Singh and Purohit ( | Kamalanathan et al. ( | |
| PO4
3− bending | 565 | 560, 599 | 567 | 568 |
| PO4
3− stretching | 1024 | 1046 | 1046 | 1038 |
| CO3
2− group | 1454 | 1424, 1424 | 1422 | 1421 |
| OH− structure | 3744 | 1637, 3100–3700 | 3431 | 3425 |
The crystallite size and linear shrinkage of the HA sample at various sintering temperature
| Temperature (°C) | Crystallite size [D (nm)] | Linear shrinkage (%) | Density (g/cm3) |
|---|---|---|---|
| 200 | 26.58 | 0 | 2.76 |
| 600 | 29.54 | 3.08 | 2.81 |
| 800 | 37.98 | 6.15 | 2.96 |
| 1000 | 53.18 | 11.53 | 3.12 |
| 1100 | 66.32 | 14.84 | 2.93 |
| 1200 | 66.34 | 16.69 | 2.86 |
Fig. 5FESEM micrograph of HA: a 200 °C, b 600 °C, c 800 °C, and d 1000 °C under 50 k magnification and e 1100 °C and f 1200 °C under 5 k magnification
Fig. 6EDX spectra of HA at different sintering temperatures: a 200 °C, b 600 °C, c 800 °C, d 1000 °C, e 1100 °C, and f 1200 °C
The element composition present in the HA sample with different sintering temperature
| Sintering temperature (°C) | Weight of element composition (wt%) | Ca:P ratio | |||
|---|---|---|---|---|---|
| Ca | P | C | O | ||
| 200 | 25.64 | 13.12 | 17.48 | 43.76 | 1.95 |
| 600 | 31.61 | 16.61 | 7.05 | 44.74 | 1.90 |
| 800 | 27.83 | 15.27 | 8.20 | 48.70 | 1.82 |
| 1000 | 34.45 | 17.35 | 7.27 | 40.92 | 1.98 |
| 1100 | 37.06 | 18.76 | 3.78 | 40.40 | 1.97 |
| 1200 | 30.96 | 18.63 | 3.41 | 47.00 | 1.66 |