involves two N atoms adjacent to ea

involves two N atoms adjacent to each other in the lattice. Although these two atoms occupy neighboring sites, each pair is isolated from other N atoms in the lattice. These N impurities are commonly referred to as A aggregates (or A centers), and the diamonds that contain them are termed type IaA. The other configuration involves four N atoms that symmetrically surround a vacancy. (A vacancy is a lattice site normally occupied by a carbon atom that is not occupied by any atom.) This complex grouping is formed when two A centers combine. These N impurity groupings are called B aggregates (or B centers), and the associated diamonds are type IaB. Other arrangements of N atoms (see box A) do occur, but they are not included in the diamond type classification system (Collins, 1982, 2001). Type II diamonds are divided into types IIa and IIb (again, see figure 2). Type IIa diamonds contain no easily measurable N or boron impurities. Natural type IIb diamonds likewise contain no IR-measurable N impurities. Instead, type IIb diamonds contain boron impurities that are thought to be isolated single atoms that replace carbon in the diamond lattice. Characteristic properties of type IIb diamonds, such as electrical conductivity, are a direct result of the boron impurities.
What Can a Gemologist Learn from Diamond Type? In many cases, the geologic conditions to which nat
ural diamonds have been exposed during their extended period in the earth and the conditions imposed in a laboratory during treatment or synthetic growth are quite different, yet the resulting structural lattice defects can yield natural, treated, and synthetic diamonds with very similar colors. (See box A for information about non–type related defects that also influence color.) Diamond impurities control the nature of the lattice defects that occur naturally and their evolution during lab growth or treatment. Therefore, a diamond’s type reflects its history, whether in nature or in the laboratory, or both—and an adequate understanding of diamond type is critical for identification purposes. Since the detection of many modern treatments and synthetics requires the facilities of a well-equipped gemological laboratory, it is important to know when to send a diamond for advanced testing. With a better understanding of how diamond type relates to natural color, treated color, and synthetic growth processes, a gemologist should be able to make that decision more easily.
Relationship of Type to Diamond Color and Treatments. Natural diamonds often show colors that correlate to their diamond type (figure 3). For example, type Ia colorless, brown, pink, and violet diamonds are unlikely to have been color-treated, whereas treated-color type Ia yellow, orange, red, blue, and green stones are relatively common.