Mohamed N. Rahaman

Materials for Biomedical Engineering


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target="_blank" rel="nofollow" href="#ulink_2eb44b66-b1f9-5600-8f31-125eb64beb3e">Table 3.2 Crystal structure and atomic radius of some common metals at room temperature.

Metal Crystal structurea Atomic radius (nm) Metal Crystal structurea Atomic radius (nm)
Aluminum FCC 0.1431 Molybdenum BCC 0.1363
Cadmium CPH 0.1490 Nickel FCC 0.1246
Chromium BCC 0.1249 Platinum FCC 0.1387
Cobalt CPH 0.1253 Silver FCC 0.1445
Copper FCC 0.1278 Tantalum BCC 0.1430
Gold FCC 0.1442 Titanium CPH 0.1445
Iron (α) BCC 0.1241 Tungsten BCC 0.1371
Lead FCC 0.1750 Zinc CPH 0.1332

      a FCC, face‐centered cubic; CPH, close‐packed hexagonal; BCC, body‐centered cubic.

      3.3.2 Crystal Structure of Ceramics

      The simplest ionic‐bonded ceramics are compounds composed of ions of a metal and a non‐metal that have discrete charges of opposite sign as in NaCl, for example (Chapter 2). Electrostatic bonding between the cations and anions provide the dominant contribution to the bonding energy. The bonding is non‐directional and the ions tend to pack as densely as possible. One type of ion surrounds itself with as many ions of the opposite sign as possible, with the constraint that ions of the same sign must not touch, maximizing the electrostatic potential energy of attraction. Thus, the majority of ceramics with a high degree of ionic bonding have crystal structures based on FCC or CPH packing.

Schematic illustration of arrangement of sodium ions (Na+) and chlorine ions (Cl-) in a sodium chloride unit cell.

      Aluminum oxide (Al2O3 ), often referred to as alumina or α‐alumina, is used as articulating bearings in hip implants (Chapter 1). Although alumina has aclose‐packed hexagonal (CPH) structure, the arrangement of the ions has to take into account the dissimilar cation to anion ratio (2 : 3) and the geometrical restriction that each type of ions must not touch. The structure can be viewed as composed of layers of O2− ions stacked in a direction perpendicular to the basal plane between which two‐thirds of the interstitial atomic sites are occupied by Al3+ ions and one‐third is empty.

      Many of the strongest, hardest, and most refractory ceramics have structures with a high degree of covalent bonding. Several of these ceramics, such as carbon in the form of diamond, silicon carbide (SiC) and silicon nitride (Si3N4 ), for example, show a tetrahedral arrangement of the bonds due to sp3 hybridization of the valence electron orbitals in atoms such as carbon and silicon (Chapter 2). As there are a fixed number of directional bonds in covalent bonding, the position and number of neighboring atoms in the structure are also fixed. Diamond is often considered prototypical of solids that show strong covalent bonds. It consists of a cubic unit cell in which the atoms are located at the corners of a tetrahedron due to sp3 hybridization of the valence electron orbitals of the carbon atoms (Section 3.3.4). Silicon nitride is used in spinal fusion implants and it is being developed for use as femoral head bearings in hip implants. It has a hexagonal crystal structure in which each silicon atom is bonded to four nitrogen atoms due to sp3 hybridization of the silicon atom. These SiN4 tetrahedra are joined together by three nitrogen atoms in a trigonal planar arrangement due to sp2 hybridization of the electron orbitals in nitrogen.