由磷灰石纤维制备孔隙率和孔径可控的多孔陶瓷及其性能评价

Development of porous ceramics with well-controlled porosities and pore sizes from apatite fibers and their evaluations.

作者信息

Kawata M, Uchida H, Itatani K, Okada I, Koda S, Aizawa M

机构信息

Department of Chemistry, Faculty of Science and Engineering, Sophia University, 7-1, Kioi-cho, Chiyoda-ku, Tokyo, Japan.

出版信息

J Mater Sci Mater Med. 2004 Jul;15(7):817-23. doi: 10.1023/b:jmsm.0000032823.66093.aa.

DOI:10.1023/b:jmsm.0000032823.66093.aa

PMID:15387418

Abstract

Porous hydroxyapatite (HAp) ceramics possessing well-controlled porosities and pore sizes were developed by firing apatite-fiber compacts mixed with carbon beads and agar. The total porosities could be controlled in the range from 40 to 85% by varying compaction pressure (20-40 MPa), firing temperature (1000-1300 degrees C) and carbon/HAp ratio (0/10-10/10 (w/w)). Most of the pores were regarded as open pores. The pore sizes were mainly affected by the carbon-bead diameter (5, 20 or 150 microm) and partly by the compaction pressure and the firing temperature. The pore sizes of the porous HAp ceramics derived from the carbon beads of 150 microm in diameter were distributed in the two separate ranges of several micrometers and more than 100 microm.

摘要

通过烧制与碳珠和琼脂混合的磷灰石纤维压块，制备出了具有可控孔隙率和孔径的多孔羟基磷灰石（HAp）陶瓷。通过改变压实压力（20 - 40 MPa）、烧制温度（1000 - 1300℃）和碳/HAp比例（0/10 - 10/10（w/w）），总孔隙率可控制在40%至85%的范围内。大多数孔隙被视为开孔。孔径主要受碳珠直径（5、20或150微米）影响，部分受压实压力和烧制温度影响。由直径150微米的碳珠制成的多孔HAp陶瓷的孔径分布在几个微米和100微米以上两个不同范围内。

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由磷灰石纤维制备孔隙率和孔径可控的多孔陶瓷及其性能评价

Development of porous ceramics with well-controlled porosities and pore sizes from apatite fibers and their evaluations.

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