Lab created diamonds are man-made diamonds that consist of actual carbon atoms arranged in the characteristic diamond crystal structure. Diamond simulants, such as cubic zirconia and moissanite, are diamond look-alikes and are not true carbon crystals.
Lab created diamonds (also known as man-made diamonds, synthetic diamonds or pure grown diamonds) are grown in highly-controlled laboratory conditions that simulate the earth’s natural growing environment, producing real diamonds that are optically, physically and chemically identical to earth mined diamonds.
Lab created diamonds are made using one of two techniques. Each process produces pure carbon diamonds when complete, however they are often used for different application. High Pressure High Temperature (HPHT) is our primary growing process, while Chemical Vapor Deposition (CVD) is commonly used to produce diamonds for industrial purposes.
Additionally, lab diamonds are also grown from the tiny carbon seeds of pre-existing diamonds. Advanced technology – either extreme pressure and heat or a special deposition process – replicates the natural method of diamond formation. Lab grown fancy colored diamonds are formed when small amounts of specific trace elements are present during the growth phase of the diamond, just like in nature.
Lab made diamonds are an eco-friendly product. By choosing a grown diamond versus an earth-mined diamond you’re reducing the harmful impact mining has on the environment and native communities.
FACT: The amount of land disturbed in the creation of a man made diamond = 0.00000071 hectares/carat. The use of water is also minimized with approximately 70 litres used in the creation of a 1 carat grown diamond.
Properties |
Earth-Mined |
Lab-Created |
---|---|---|
Guaranteed Conflict Free | No | Yes |
Hardness Mohs | 10 | 10 |
SP3 Carbon Diamond Bonds % | 100% | 100% |
Internal Crystal Structure | Face-Centered-Cubic / Singly Refractive | Face-Centered-Cubic / Singly Refractive |
Hardness Comparable | n/a | Same as Mined Diamond |
Cuts Glass | Yes | Yes |
Clarity | Varies | IF to IS |
Index of Refraction | 2.42 | 2.42 |
Color | Various Grades | D to F Grades |
Cut | Varies on Cost | Ideal to Very Good |
Final Polish | Diamond Powder | Diamond Powder |
Availability | Abundant, but supply is tightly restricted | Available in a variety of colors, shapes and sizes |
Price | $$$$$ | Up to 40% less than mined diamonds |
HOW DIAMONDS ARE CLASSIFIED BY TYPE
Beginning in the 1930s, scientists began to recognize that certain kinds of diamonds displayed similar features. They grouped the diamonds into two main categories called type I and type II based on differences in transparency under ultraviolet radiation. Scientists were able to further divide type I and type II diamonds into two subcategories by the arrangement of carbon—and impurity—atoms in the diamond structure. In 1959 they discovered that nitrogen was the principal chemical impurity in diamond and that while type I diamonds contained this impurity, type II diamonds did not.
The vast majority of natural diamonds are what scientists call type Ia. Type Ia diamonds contain plentiful nitrogen in clusters or pairs. This kind of diamond cannot be grown artificially. Type Ib diamonds contain scattered and isolated nitrogen atoms that are not in pairs or clusters. Type Ib diamonds are rare in nature. Type IIa diamond contain almost no nitrogen, while IIb diamond contains boron.
Synthetic diamonds correspond to types Ib, IIa, and IIb, all rare categories among natural diamonds.
At GIA type I and type II diamonds can be distinguished by the latter’s transparency under short-wave ultraviolet radiation, and both types can be definitively separated by infrared spectroscopy.
Type (Color) |
Natural | HPHT Synthetic |
CVD Synthetic |
Ia (near-colorless) | Common | — | — |
Ib (yellow) | Rare | Available | Rare |
IIa (colorless) | Rare | Rare | Available |
IIb (blue) | Rare | Rare | Rare |
DIAMOND GROWTH
Natural diamond crystals formed millions—sometimes billions—of years ago deep in the earth, at depths of 100 miles (160 km) or more, and were brought up to the surface much later by explosive volcanic eruptions. These eruptions formed narrow vertical pipes of an igneous rock called kimberlite. Kimberlite pipes are mined to recover the diamonds, and the ore is mechanically broken down to free the crystals. The amount of diamond in kimberlite is very low—perhaps one part per million—so miners must process large amounts of ore to recover the diamonds.
Natural diamonds grow under a range of temperature and pressure conditions. The temperatures are higher than those used to grow synthetic diamonds. At high temperatures, diamonds grow as octahedral crystals, but in the lower temperatures of the laboratory, they grow as crystals with both octahedral and cubic faces. The great age of natural diamonds means that the nitrogen impurities in most diamonds have had time to aggregate into pairs or clusters, making the vast majority—over 95 percent—type Ia.
Synthetic diamonds are grown over a very short time—several weeks to one month or more—under conditions different from natural diamond formation deep in the earth. Because of the very short growth period, the shape of a synthetic diamond crystal is very different from that of a natural diamond.
DIAMOND SYNTHESIS
Scientists first grew synthetic diamonds in the mid-1950s as tiny crystals. Production of larger crystals suitable for jewelry use began in the mid-1990s and continues today, with more companies becoming involved with diamond growth. Synthetic diamonds are grown in several countries for both jewelry and industrial applications—which may be the more important use for the material (Large Colorless HPHT Synthetic Gem Diamonds from China, Gem News International, Gems & Gemology, Spring 2016, Vol. 52, No. 1).
The traditional synthesis method, called high-pressure, high-temperature (HPHT) growth, involves diamond formation from a molten metal alloy, such as iron (Fe), nickel (Ni), or cobalt (Co). The newer method, referred to as chemical vapor deposition (CVD) or low-pressure, high-temperature (LPHT) growth, involves diamond formation from a gas in a vacuum chamber.
In both methods a diamond crystal or plate is used as a seed to initiate growth.
HPHT SYNTHESIS
HPHT diamond growth takes place in a small capsule within an apparatus capable of generating very high pressures. Within the capsule, diamond powder starting material dissolves in the molten metal flux, and then it crystallizes on the seed to form the synthetic diamond crystal. Crystallization occurs over a period of several weeks to a month or more to create one or a few crystals.
HPHT synthetic diamond crystals typically show cubic faces in addition to octahedral ones. Because the shapes of natural and HPHT synthetic diamond crystals are different, their internal growth patterns also differ dramatically. These growth patterns can be among the most reliable ways to separate them.
The resulting faceted synthetic gems often exhibit visual features such as color distribution, fluorescence zoning, and graining patterns related to their cross-shaped, growth-sector structure, as well as the presence of occasional dark flux-metal inclusions. In some cases the material exhibits persistent phosphorescence after the ultraviolet lamp is turned off. These synthetic diamonds can be positively identified using laboratory techniques such as visible and photoluminescence spectroscopy.
Most HPHT-grown crystals are yellow, orangy yellow, or brownish yellow. Almost all are type IIb, which is rare in natural diamonds.
Creating colorless HPHT synthetics has been challenging, as modifications to growth conditions and equipment are necessary to exclude nitrogen. In addition, growth rates for high-purity colorless diamond (type IIa or weak type IIb) are lower than for type Ib synthetic diamond, necessitating longer growth times and greater control over the temperature and pressure conditions. While it has traditionally been difficult to grow high-quality colorless HPHT crystals, recent developments have produced crystals sufficient for faceted stones over 10 carats in weight (Large Blue and Colorless HPHT Synthetic Diamonds, Lab Notes, Gems & Gemology, Summer 2016, Vol. 52, No. 2).
The addition of boron in the growth system results in blue crystals. Other colors—such as pink and red—can be produced by post-growth treatment processes that involve radiation and heating, but they are less common.
CVD SYNTHESIS
CVD diamond growth takes place inside a vacuum chamber filled with a carbon-containing gas, such as methane. A source of energy—like a microwave beam—breaks down the gas molecules, and the carbon atoms are attracted downward to flat diamond seed plates. Crystallization occurs over a period of several weeks to create a number of crystals at the same time. The exact number depends on the size of the chamber and the number of seed plates. The tabular crystals often have a rough edge of black graphite. They often also display a brown color that can be removed by heat treatment prior to faceting for gem purposes.
Most CVD crystals are brownish or grayish, but if a tiny amount of nitrogen or boron is introduced into the chamber, yellow, pink-orange, or blue crystals can be created. Colorless crystals are easier to produce with this method, but they require a longer time to grow. Most of the CVD-grown colorless material on the market is believed to have been brown crystals decolorized by HPHT annealing. CVD synthetic diamonds are most commonly type IIa.
CVD synthetic diamonds have different gemological properties than HPHT-grown material. They tend to display even coloration and banded “strain” patterns when observed between crossed polarizing filters, and they are of high clarity with few, if any, tiny dark carbon inclusions.
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