Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 1-10 Mm |
Grade | Aaaaa |
Technique | Synthetic |
Treated | Yes |
Weight | 2 |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Color | Available in Red, Blue, Green Etc |
Shape | Round |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | '1000 |
Color | Available in Red, Blue, Green Etc |
Grade | aaaaa |
Size | 1-10 mm |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Packaging Type | Packet |
Usage | Artificial Jewellery |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 10 Mm |
Grade | AAAAA |
Technique | Synthetic |
Treated | Yes |
Weight | 2 |
Brand | A N Gems |
Carat | 1 Ct To 20 Ct |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 20mm |
Grade | aaaa |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Packaging Type | all |
Carat | all |
Usage/Application | jewellery |
Country of Origin | Made in India |
Cubic zirconia (CZ) is the cubic crystalline form of zirconium dioxide (ZrO2). The synthesized material is hard and usually colorless, but may be made in a variety of different colors. It should not be confused with zircon, which is a zirconium silicate (ZrSiO4). It is sometimes erroneously called cubic zirconium.
Because of its low cost, durability, and close visual likeness to diamond, synthetic cubic zirconia has remained the most gemologically and economically important competitor for diamonds since commercial production began in 1976. Its main competitor as a synthetic gemstone is a more recently cultivated material, synthetic moissanite.
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 20mm |
Grade | Aaaa |
Technique | All |
Treated | Yes |
Weight | 1 To 100cts |
Packaging Type | all |
Carat | all |
Usage/Application | jewellery |
Country of Origin | Made in India |
Cubic zirconia (CZ) is the cubic crystalline form of zirconium dioxide (ZrO2). The synthesized material is hard and usually colorless, but may be made in a variety of different colors. It should not be confused with zircon, which is a zirconium silicate (ZrSiO4). It is sometimes erroneously called cubic zirconium.
Because of its low cost, durability, and close visual likeness to diamond, synthetic cubic zirconia has remained the most gemologically and economically important competitor for diamonds since commercial production began in 1976. Its main competitor as a synthetic gemstone is a more recently cultivated material, synthetic moissanite.
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Color | Transparent |
Quantity Per Pack | 1000 |
Grade | Aaaaa |
Size | 1-10 Mm |
Technique | Synthetic |
Treated | Yes |
Weight | 2 |
Brand | A N Gems |
Carat | 1 To 20 Cts |
Usage/Application | Jewelry |
Heated | Yes |
Packaging Type | Packet |
Shape | Diamond |
Usage | Artificial Jewellery |
Additional Information:
Product Details:
Minimum Order Quantity | 500 Piece |
Quantity Per Pack | 1000 |
Color | Available In Red, Blue, Green Etc |
Size | 1-10 Mm |
Technique | Synthetic |
Treated | Yes |
Weight | 2 |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Diamond Shape | Round |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Color | Available in Red, Blue, Green Etc |
Size | 1-10 mm |
Grade | aaaaa |
Shape | Diamond |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 3.20 mm |
Grade | aaaaa |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Shape | Diamond |
Colour | Available in Red, Blue, Green Etc |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 5 mm |
Grade | aaaa |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Shape | Diamond |
Colour | Available in Red,Blue,Green Etc |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 6 mm |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Shape | Diamond |
Colour | Available in Red,Blue,Green Etc |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 2.40 mm |
Grade | aaaa |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Usage/Application | Artificial Jewellery |
Shape | Available in Round,Oval Etc |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | ALL |
Grade | AAAAA |
Treated | NO |
Weight | ALL |
Usage/Application | Artificial Jewellery |
Packaging Size | 1000 Piece |
Shape | Round |
Color | Purple |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 CARAT |
Size | 1.60 mm |
Brand | Royal Dazzle |
Packaging Type | Box |
Usage/Application | Artificial Jewellery |
Packaging Size | 1000 Piece |
Shape | Round |
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 1-10 mm |
Grade | aaaaa |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
Shape | Round |
Colour | Available in Red,Blue,Green Etc |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Color | White |
State | Crystal |
Size | 0.70-1.50 mm |
Usage/Application | Artificial Jewellery |
Packaging Type | Packet |
Stone Shape | Round |
Cubic zirconia is the cubic crystalline form of zirconium dioxide. The synthesized material is hard and usually colorless, but may be made in a variety of different colors. It should not be confused with zircon, which is a zirconium silicate. It is sometimes erroneously called cubic zirconium.
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 0.70-1.50 Mm |
Shape | Round |
Packaging Type | Packet |
Usage/Application | Artificial Jewellery |
State | Crystal |
Color | Blue |
Product Details:
Minimum Order Quantity | 500 Piece |
Size | 1mm to 10 mm |
Grade | AAAAA |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Brand | a n gems |
Additional Information:
Product Details:
Size | 1 Mm To 10 Mm |
Grade | AAAAA |
Technique | Synthetic |
Treated | Yes |
Weight | 2 |
Brand | A N Gems |
Packaging Type | Loose |
Carat | 1 Ct To 20 Ct |
Usage/Application | Jewelry |
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1 To 10 Mm |
Grade | All |
Technique | Synthetic |
Treated | Yes |
Weight | 2 |
Brand | A N Gems |
Packaging Type | All |
Usage/Application | Jewewllery |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 1 to 10 mm |
Packaging Type | all |
State | Solid |
Shape | all |
Packaging Size | all |
Grade | aaaa |
Machine Cut Round | yes |
Design | round |
Weight | as u wish |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Unit |
Size | 1 MM TO 10 MM |
Grade | AAAAA |
Color | WHITE |
Technique | synthetic |
Treated | yes |
Weight | 2 |
Packaging Type | Box |
Carat | ALL |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Cubic zirconia (CZ) is the cubic crystalline form of zirconium dioxide (ZrO2). The synthesized material is hard and usually colorless, but may be made in a variety of different colors. It should not be confused with zircon, which is a zirconium silicate (ZrSiO4). It is sometimes erroneously called cubic zirconium.
Because of its low cost, durability, and close visual likeness to diamond, synthetic cubic zirconia has remained the most gemologically and economically important competitor for diamonds since commercial production began in 1976. Its main competitor as a synthetic gemstone is a more recently cultivated material, synthetic moissanite
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 1 mm to 15 mm |
Surface Finish | full |
Pattern | new |
Coverage area | all |
Packaging Type | all |
State | Solid |
Carat | avl |
Shape | all |
Packaging Size | all |
Usage/Application | jewellery |
Grade | aaaa |
Machine Cut Round | yes |
Design | all |
Weight | all |
Country of Origin | Made in India |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 1mm to 8mm |
Packaging Type | Packet |
State | Solid |
Shape | all |
Packaging Size | all |
Grade | aaaa |
Machine Cut Round | yes |
Design | all |
Weight | as u wish |
Product Type | synthetic |
Brand | dazzle |
Country of Origin | Made in India |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Quantity Per Pack | 1000 |
Size | 1mm to 15mm |
Packaging Type | all |
State | Solid |
Shape | all |
Packaging Size | all |
Grade | aaaa |
Machine Cut Round | yes |
Design | all |
Weight | as u wish |
Product Type | synthetic |
Brand | dazzle |
Color | all |
Country of Origin | Made in India |
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15mm |
Grade | aaaaa |
Technique | all |
Treated | yes |
Weight | 1 TO 100 Cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm to 10 mm |
Grade | AAAAA |
Treated | yes |
Weight | 1to 100 cts |
Brand | a n gems |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm to 15 mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm to 15 mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1 mm To 15 mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm to 20mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Shape | octogan |
Packaging Type | all |
Usage/Application | jewewllery |
Heated | yes |
Packaging Size | all |
Machine Cut Round | yes |
Design | octogan |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15 mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 20mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 20mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15 mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 15mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Shape | octogan |
Packaging Type | all |
Packaging Size | all |
Usage/Application | jewewllery |
Machine Cut Round | yes |
Design | octogan |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information:
Product Details:
Minimum Order Quantity | 1000 Piece |
Size | 1mm To 20mm |
Grade | AAAAA |
Technique | all |
Treated | yes |
Weight | 1 to 100cts |
Brand | a n gems |
Packaging Type | all |
Usage/Application | jewewllery |
Country of Origin | Made in India |
Synthetic diamond are different from natural diamond created by geological processes and imitation diamond made of non-diamond material. Numerous claims of diamond synthesis were documented between 1879 and 1928; most of those attempts were carefully analyzed but none were confirmed. In the 1940s, systematic research began in the United States, Sweden and the Soviet Union to grow diamonds using CVD diamond (chemical vapor deposition) and HPHT diamond (high-pressure high-temperature) processes. The first reproducible synthesis was reported around 1955. Those two processes still dominate the production of synthetic diamond. A third method, known as detonation synthesis, entered the diamond market in the late 1990s. In this process, nanometer-sized diamond grains are created in a detonation of carbon-containing explosives. A fourth method, treating graphite with high-power ultrasound, has been demonstrated in the laboratory, but currently has no commercial application.
The properties of synthetic diamond depend on the details of the manufacturing processes; however, some synthetic diamonds (whether formed by HPHT or CVD) have properties such as hardness, thermal conductivity and electron mobility that are superior to those of most naturally formed diamonds. Synthetic diamond is widely used in abrasives, in cutting and polishing tools and in heat sinks. Electronic applications of synthetic diamond are being developed, including high-power switches at power stations, high-frequency field-effect transistors and light-emitting diodes. Synthetic diamond detectors of ultraviolet (UV) light or high-energy particles are used at high-energy research facilities and are available commercially. Because of its unique combination of thermal and chemical stability, low thermal expansion and high optical transparency in a wide spectral range, synthetic diamond is becoming the most popular material for optical windows in high-power CO2 lasers and gyrotrons. It is estimated that 98% of industrial grade diamond demand is supplied with synthetic diamonds.[2]
In the United States, the Federal Trade Commission has indicated that the terms laboratory-grown, laboratory-created, and [manufacturer-name]-created "would more clearly communicate the nature of the stone".[1] Both CVD and HPHT diamonds can be cut into gems and various colors can be produced: clear white, yellow, brown, blue, green and orange. The advent of synthetic gems on the market created major concerns in the diamond trading business, as a result of which special spectroscopic devices and techniques have been developed to distinguish synthetic and natural diamonds
Additional Information: