How CVD works: the science
CVD diamond growth is fundamentally different from HPHT in one important way: it does not attempt to recreate the conditions inside the earth. Instead, it exploits a different principle entirely — that carbon atoms in a specific energy state will preferentially form diamond bonds rather than graphite bonds when deposited onto a diamond surface.
The process begins with a diamond seed plate. This is a thin slice of diamond — typically 1 to 3 millimetres thick and a few centimetres across — cut from either a natural diamond or a previously grown HPHT diamond. The seed plate is polished flat, cleaned, and placed inside a vacuum chamber.
The chamber is evacuated to very low pressure — typically between 10 and 300 Torr, far below atmospheric pressure. A mixture of gases is then introduced: primarily hydrogen (H₂) at about 95–98%, with methane (CH₄) providing the carbon source at 2–5%. Other gases including nitrogen, argon, or boron may be added in tiny quantities to modify the crystal's properties.
Energy is applied to the gas — typically by a microwave generator operating at 2.45 GHz (the same frequency as a kitchen microwave). The energy ionises the gas into a plasma: a soup of ions, electrons, and highly reactive atomic species. At the heart of the plasma, temperatures reach 3,000–5,000°C. The seed plate, sitting just below the plasma zone, reaches 700–1,200°C.
In the plasma, methane molecules are broken down into individual carbon atoms and various hydrocarbon radicals. These reactive species bombard the seed plate surface. On a diamond surface, carbon atoms find their most stable positions in the diamond crystal lattice. Layer by layer, atom by atom, the diamond grows upward. The hydrogen plays a critical supporting role: it preferentially etches graphite while leaving diamond intact, ensuring that any graphitic carbon that might form is removed before it can poison the crystal growth.
After three to four weeks of continuous growth, the chamber is carefully shut down and the grown crystal is removed. It typically looks brownish or dark — not yet the transparent gem it will become. It undergoes further processing before it reaches a jeweller's bench.
Inside a CVD reactor: microwave plasma breaks carbon gas into atoms that deposit layer by layer onto the seed plate below
CVD reactor types
Several CVD reactor designs are used commercially, each with different trade-offs between crystal quality, growth rate, and cost.
Microwave plasma CVD (MPCVD)
The dominant technology for gem-quality diamond production. A microwave generator creates a plasma ball directly above the seed substrate. MPCVD reactors produce the highest quality crystals because the plasma can be precisely controlled and the absence of electrodes eliminates metal contamination. The main commercial MPCVD reactor manufacturers are Seki Diamond Systems (Japan/USA) and Lambda Technologies. A single MPCVD reactor for gem-quality growth costs between $300,000 and $800,000 depending on size and specification.
Hot filament CVD (HFCVD)
An older and cheaper design where the gas is activated by passing it over heated tungsten filaments (typically at 2,000–2,500°C) rather than by plasma. HFCVD reactors are simpler and less expensive to build and operate, but the tungsten filaments contaminate the growing crystal with trace tungsten, limiting crystal quality. HFCVD is more commonly used for industrial diamond coating applications than for gem production.
DC arc jet CVD
A high-power plasma jet reactor that produces very fast growth rates but lower crystal quality. Used for certain industrial applications and research but not typical for gem production.
CVD diamond producers worldwide
CVD production is geographically more distributed than HPHT, with significant capacity in China, India, the United States, and Singapore.
| Producer | Country | Focus | Notable for |
|---|---|---|---|
| IIa Technologies | Singapore | Premium gem CVD | Type IIa high-colour diamonds; early pioneer of gem-quality CVD |
| Lightbox (De Beers) | USA (Oregon) | Gem CVD, fashion price point | Deliberately priced at $800/ct to influence market positioning |
| WD Lab Grown Diamonds | USA (Maryland) | Premium CVD gems | Large stone production; focus on colourless and fancy blue |
| Fenix Lab Diamonds | India (Surat) | Commercial gem CVD | One of India's largest integrated CVD growers and cutters |
| Greenlab Diamonds | India (Gujarat) | Commercial gem CVD | Focus on IGI-certified gem production for export |
| Henan Huajing | China | Large-scale commercial CVD | One of China's largest CVD capacity producers |
| Zhongnan Diamond | China | Industrial + gem CVD | Significant scale; supplies rough to Indian cutters |
| Pure Grown Diamonds | USA | Gem CVD | Early US market entrant; graded by IGI |
What CVD diamonds look like: quality characteristics
CVD diamonds have specific quality characteristics that differ from both natural diamonds and HPHT diamonds. Understanding these helps buyers and jewellers evaluate CVD-grown gems accurately.
Colour in as-grown CVD diamonds
Fresh CVD-grown diamonds almost never come out of the reactor looking their best. The majority have a brownish, greyish, or sometimes near-colourless body colour as grown. The brown colour comes from structural defects called vacancies and vacancy clusters that form during the rapid layer-by-layer growth. This is not nitrogen (as in HPHT yellows) — it is a different mechanism entirely.
The good news is that most of this brown colour is removable by post-growth treatment, which is covered in the next section. After treatment, CVD diamonds commonly achieve D-F colour grades, which is one reason CVD dominates the premium colourless gem market.
Characteristic CVD inclusions
CVD diamonds can contain specific inclusion types that differ from natural and HPHT diamonds. The most common are pinpoint-sized graphitic inclusions — tiny specks of unreacted graphite that were not etched away by the hydrogen in the plasma. These appear as dark dots under magnification. CVD diamonds can also show characteristic strain lines (internal graining) visible under cross-polarised light, reflecting the layer-by-layer growth pattern.
Importantly, CVD diamonds do not contain metallic inclusions and are not magnetic — distinguishing them from HPHT diamonds with flux inclusions.
Fluorescence in CVD diamonds
CVD diamonds typically show no fluorescence or very weak blue fluorescence under longwave UV, which is similar to natural Type IIa diamonds. Under the shortwave UV used in the De Beers DiamondView instrument, CVD diamonds show characteristic orange-red fluorescence patterns that are different from both HPHT and natural diamonds. This UV fluorescence pattern is one of the primary diagnostic tools for identifying CVD-grown origin.
Post-growth treatment: what happens after the reactor
Most CVD gem diamonds undergo post-growth processing before they are cut and sold. This is standard industry practice and is not concealed — but it is not widely communicated to consumers either.
HPHT annealing to improve colour
The most common post-growth treatment for CVD diamonds is HPHT annealing — subjecting the grown crystal to high pressure and high temperature (but in a different pressure-temperature regime than used for HPHT growth) to heal the structural defects that cause the brownish colour. This process can improve a brownish as-grown CVD crystal to near-colourless or even colourless. A D colour CVD diamond you see in a jewellery store may have started as a K or L colour crystal that was then HPHT-treated to remove the brown tint.
This treatment is detectable by spectroscopy. GIA and IGI certificates for CVD diamonds note post-growth treatments when detected. The treatment does not make the diamond less real or less durable — it is a standard processing step, equivalent in some ways to heat treatment used on many coloured gemstones.
Laser sawing and cutting
CVD diamonds grow as thick plates or slabs rather than the cubic or octahedral crystals that HPHT produces. These plates are laser-sawn into individual rough crystals of the appropriate size and shape for cutting. This sawing step is more efficient than with natural round rough but requires different planning software and cutting approaches than traditional natural diamond processing.
CVD vs HPHT: practical comparison for buyers
| Factor | CVD | HPHT |
|---|---|---|
| Pressure required | Near-vacuum (very low) | Extreme (870,000+ psi) |
| Temperature | 700–1,200°C (seed plate) | 1,300–1,600°C |
| Energy source | Microwave or radio frequency | Mechanical press |
| Natural colour tendency | Colourless to brownish | Yellow-brown tendency |
| Best colour grades | D–F achievable after treatment | G–J most common gem range |
| Characteristic inclusions | Graphitic pinpoints, strain graining | Metallic flux (magnetic), hourglass graining |
| Magnetic? | No | Sometimes (if metallic flux present) |
| Post-growth treatment | Usually HPHT annealed for colour | Sometimes annealed; HPHT is the primary process |
| Dominant gem use | Colourless gem diamonds | Fancy yellow/orange; also near-colourless |
| India production | Growing significantly (Surat/Gujarat) | Primarily cutting imported Chinese rough |
| Cost trend | Falling rapidly as scale increases | Falling but less dramatically than CVD |
India and CVD: a manufacturing revolution in Surat
India's position in CVD diamonds is one of the most significant industrial shifts the country's diamond industry has experienced since it first established its cutting and polishing dominance in the 1970s.
Surat's advantage has always been human skill at scale. The city has generations of trained diamond cutters, polishers, and planners. When CVD rough began flowing in significant volumes after 2018, Surat was perfectly positioned to process it. The same workers who cut natural diamonds can cut CVD diamonds with the same tools and skills — the material is identical.
What changed was the upstream. Indian entrepreneurs began investing in CVD reactor capacity in Gujarat and Rajasthan, aiming to control the full value chain from growing to cutting to export. Companies like Fenix Lab Diamonds in Surat and several others have built integrated operations: reactors, polishing factories, and export infrastructure under one roof.
The Indian government has actively supported this. The 2023 Union Budget reduced customs duty on lab-grown diamond seeds to zero and announced a five-year research grant of Rs 250 crore for IIT Madras to develop indigenous CVD diamond growing technology. The policy intention is clear: India wants to be not just the world's diamond cutter but a significant diamond grower as well.
By 2024, India's lab-grown diamond exports (predominantly CVD) exceeded $2 billion annually. The United States remains the largest market for Indian lab-grown diamonds, taking approximately 60% of export value, followed by Belgium and the UAE. The growth trajectory suggests India will continue to increase its share of global CVD production through the decade.
Frequently asked questions
Is a CVD diamond better than an HPHT diamond?
Neither is better in absolute terms. CVD tends to produce higher colour grades in the colourless range, which is why it dominates the premium gem market. HPHT is better for producing fancy yellow and orange diamonds and has a longer commercial history for industrial applications. For a buyer choosing a colourless engagement ring diamond, CVD is more likely to achieve D-F colour at a comparable price. For a fancy yellow, HPHT is the more common choice.
Why do CVD diamonds often come out brown?
The brownish colour in as-grown CVD diamonds comes from structural defects called vacancy clusters that form during rapid layer-by-layer crystal growth. These defects absorb light in the blue-violet range, giving the stone a brownish appearance. They are not caused by nitrogen (as in HPHT yellow) and can be largely removed by post-growth HPHT annealing treatment. Most CVD gem diamonds you see in a jewellery store have been treated to improve their colour from the as-grown state.
How long does CVD diamond growth take?
Typically three to four weeks for a gem-quality crystal of one to two carats rough weight. Larger crystals take proportionally longer. Growth rates in modern reactors are approximately 0.1–0.2mm per hour under optimised conditions. The process runs continuously 24 hours a day for the entire growth period. Improving growth rate while maintaining crystal quality is one of the primary areas of ongoing research among CVD producers.
Can CVD diamonds be detected?
Yes, by spectroscopic methods. Standard gemological tools (loupe, microscope, basic UV lamp) cannot reliably identify CVD origin. Specialist instruments including the De Beers DiamondView (shortwave UV fluorescence), FTIR spectroscopy, and photoluminescence testing can identify CVD-grown origin with high confidence. All GIA and IGI certificates for CVD diamonds note "Laboratory-Grown" and specify the growing method when known. The girdle is laser-inscribed with the certificate number and lab-grown notation.
What is a lab-grown diamond · The HPHT process explained · Natural vs lab-grown: the full comparison · The price collapse story