Is There a Difference Between Natural and Laboratory-Grown Diamonds?

CVD, HPHT and Natural Diamonds
Laboratory-grown CVD rough diamond (left), laboratory-grown HPHT rough diamond (middle) and natural rough diamond (right),

Two specimens of faceted crystalised carbon - both are crystal clear and give off a kaleidoscope of spectral colours in direct light. They appear to be identical. One, however, is a billion or more years old and the other was recently grown in a laboratory.

Both are diamonds, of course. The first is a natural diamond created by forces deep within the young Earth. The second is from a laboratory and possesses essentially the same chemical, physical and optical properties as its natural counterpart.

Diamond – the material, not the gem – is a mineral consisting of “essentially pure carbon crystalised in the isometric cubic system”, according to the US Federal Trade Commission (FTC), which develops trading guides for the gem and jewellery industry.

Although the FTC says diamonds are essentially pure carbon, the vast majority of natural diamonds contain trace amounts of other substances, particularly nitrogen, which gives them a yellow colour or (rarely) boron, which imparts a blue colour. In addition, they usually contain inclusions, tiny bits of foreign material that were trapped in the still-forming diamond millions of years ago.

Laboratory-grown diamonds (also sometimes referred to as man-made or synthetic diamonds) entered the gem and jewellery market in commercial quantities about five years ago. Although identical in appearance to natural diamonds, they have very subtle differences that can only be detected by trained gemmologists and sophisticated equipment designed for that purpose.

A natural rough diamond and HPHT rough diamond side-by-side.
A comparison of rough diamonds shows a 0.83 ct natural diamond crystal on the left and a 1.02 ct HPHT crystal on the right. Both crystals are from the GIA Research Collection. Photo: Orsasa Weldon/GIA



Natural Diamonds

Natural diamonds formed deep in the earth under extreme pressure and high temperature as long as three billion years ago. Volcanic activity brought them to the surface where they lay in a type of volcanic rock formation known as kimberlite pipes, waiting to be mined. Only about five per cent of kimberlite pipes contain enough diamond to make them economically feasible to mine.

Open pit of the Arkhangelskaya kimberlite in Lomonosov, Russia. Photo: Karen Smit/GIA
Open pit of the Arkhangelskaya kimberlite in Lomonosov, Russia. Photo: Karen Smit/GIA

Laboratory-Grown Diamonds

Man-made diamonds suitable for industrial use were first produced in a laboratory in the 1950s. While gem-quality diamonds were produced in a laboratory for the first time in 1971, it was not until the mid-2010s that colourless laboratory-grown diamonds entered the gem and jewellery market in commercial quantities.

Today, laboratory-grown diamonds are created in two ways, according to Dr James Shigley, GIA Distinguished Research Fellow, who has been researching laboratory-grown diamonds at GIA for more than 30 years.

High pressure, high temperature (HPHT) diamonds are produced in a laboratory by mimicking the high pressure, high temperature conditions that form natural diamonds in the Earth. This process produces a distinctively shaped laboratory-grown diamond crystal.

The chemical vapour deposition (CVD) method involves breaking down the molecules of a carbon-rich gas, such as methane, into carbon and hydrogen atoms, which then are deposited on diamond seeds to produce a square-shaped, tabular diamond crystal.

Growing diamonds by either method typically requires less than a month for most sizes. Most CVD-grown diamonds require additional treatments like heat or irradiation to enhance or change their colours after the growth process.

Typically, laboratory-grown diamonds have weighed a carat or less, but as technology and techniques improve, larger stones have appeared in the market.

A row of HPHT synthetic diamond presses machinery in a large factory.
HPHT (high-pressure and high-temperature) presses enclosed in a factory which can produce gem-quality diamonds within a large range of sizes. Photo: Wuyi Wang/GIA


It is essential that laboratory-grown diamonds can be identified because consumers need to know what they are buying, and because there are often significant price differences between them and natural gemstones.

As part of its mission to protect and inform the gem-buying public, GIA offers diploma programmes, including the GIA Graduate Gemologist qualification, and seminars that teach diamond grading techniques and the latest methods used to distinguish natural from laboratory-grown diamonds and diamond simulants.

Because laboratory-grown diamonds are essentially chemically and optically the same as their natural counterparts, traditional gemmological observations and old-style “diamond detectors” are not able to tell them apart. Identification at a professional gemmological laboratory or using sophisticated devices developed by GIA and other organisations are the only reliable methods to separate them from natural diamonds.

Diamond Morphology – the Telltale Factor

“Natural diamonds that formed in the Earth over millions of years grow differently from diamonds created in a laboratory in a few weeks. In addition, HPHT- and CVD-created diamonds have a different growth morphology, or how growth conditions influenced the shape of the diamond crystal,” said Dr Shigley.

GIA Senior Research Scientist Dr Sally Eaton-Magaña further explained, “The identification criteria for HPHT and CVD diamonds are quite distinct from each other,” adding that laboratory-grown diamonds have become much more varied over the last 10 to 15 years, requiring GIA researchers to keep pace with new developments.

“We also regularly conduct research on emerging products and GIA has a programme to grow diamonds in the laboratory to stay ahead of any new trends,” Dr Eaton-Magaña said.

A chart listing the growth process, typical growth morphology and visual examples of natural, HPHT and CVD rough diamonds.
This chart shows the different diamond rough based on how they grew, or their growth morphology. Though this shape is lost after a diamond is cut and polished, identification is still possible by looking for fluorescence patterns that result from its particular growth morphology among other things.


GIA tests every diamond submitted to its gemstone grading and identification laboratory locations around the world to determine whether it is natural or laboratory-grown.

Laboratory-Grown Diamond Grading Report
In July, GIA will include the full GIA colour and clarity scales on its laboratory-grown diamond reports.

GIA has issued reports for laboratory-grown diamonds for more than 10 years. In March 2019, following the guidelines from the FTC, the Institute announced it will change the name of the reports to GIA Laboratory-Grown Diamond Reports from July 2019. To reduce the potential for confusion, GIA grading reports for laboratory-grown diamonds look significantly different to those for natural diamonds. In addition, the terms used to report colour and clarity grades for laboratory-grown diamonds are different to those used for natural diamonds. Instead of D-to-Z colour grades, broader category terms (Colourless, Near-Colourless, Faint, Very Light and Light) are used. Clarity grades, which are abbreviated on natural diamond reports (VVS1, SI2 etc.), use broader descriptive category terms (i.e. Very Very Slightly Included, Slightly Included) on the reports for laboratory-grown diamonds.


GIA iD100
The GIA iD100 allows retailers to rapidly and accurately screen loose and mounted diamonds as small as .005 ct.

To identify laboratory-grown diamonds, GIA developed the GIA iD100™ screening device. This desktop-sized instrument combines advanced spectroscopic technology with GIA’s 60 years of diamond and gemstone identification research to distinguish natural diamonds from laboratory-grown (HPHT and CVD) diamonds and diamond simulants.

GIA also offers the GIA Melee Analysis Service, which quickly and accurately screens parcels of very small diamonds – the most prevalent in the market.

Russell Shor is senior industry analyst at GIA in Carlsbad.