Abstract: A method of a growing an embedded single crystal diamond structure, comprising: disposing a single crystal diamond on a non-diamond substrate, wherein the non-diamond substrate is larger than the single crystal diamond; masking a top portion of the single crystal diamond using a masking material; and using a chemical vapor deposition (CVD) growth chamber, growing polycrystalline diamond material surrounding the single crystal diamond in order to join the single crystal diamond to the polycrystalline diamond material.

Abstract: A method of a growing an embedded single crystal diamond structure, comprising: disposing a single crystal diamond on a non-diamond substrate, wherein the non-diamond substrate is larger than the single crystal diamond; masking a top portion of the single crystal diamond using a masking material; and using a chemical vapor deposition (CVD) growth chamber, growing polycrystalline diamond material surrounding the single crystal diamond in order to join the single crystal diamond to the polycrystalline diamond material.

Abstract: A method of a growing an embedded single crystal diamond structure, comprising: disposing a single crystal diamond on a non-diamond substrate, wherein the non-diamond substrate is larger than the single crystal diamond; masking a top portion of the single crystal diamond using a masking material; and using a chemical vapor deposition (CVD) growth chamber, growing polycrystalline diamond material surrounding the single crystal diamond in order to join the single crystal diamond to the polycrystalline diamond material.

Abstract: A method of producing a large single crystal diamond comprising of: (i) arranging two or more single crystal diamond substrates adjacent to one another in a diamond growth chamber, wherein each single crystal diamond substrate include at least 2 adjacent surfaces having different crystallographic orientations, (ii) using a diamond growth process, growing the single crystal diamond substrates in an upward growth direction as well as in a lateral growth direction.

Abstract: A method utilising microwave plasma chemical vapour deposition (MPCVD) process of producing electronic device grade single crystal diamond comprising of: (a) selecting a diamond seed or substrate having a pre-determined orientation, (b) cleaning and/or etching of non-diamond phases and other induced surface damages from the diamond seed or substrate, whereby this step can be performed one or more times, (c) growing a layer of extremely low crystal defect density diamond surface on the cleaned/etched diamond seed or substrate, whereby this step can be performed one or more times, and (d) growing electronics device grade single crystal diamond on top of the layer of the low crystal defect density diamond surface.

Abstract: An apparatus for producing diamond and performing real time in situ analysis, comprising: a housing, a reaction chamber, the reaction chamber being structurally connected to the housing, the reaction chamber comprising of an enclosed area adapted to house the growing of diamonds, a radiating means, the radiating means being mounted above the reaction chamber within the housing, the radiating means adapted to emit microwave into the reaction chamber to effect the growth of diamonds within the reaction chamber, a dielectric cover being provided at the top of the reaction chamber and adapted to allow the radiation wave from the radiating means to enter the reaction chamber, a recording means mounted within the annual housing and above the reaction chamber, a measuring mechanism arranged at the periphery of the reaction chamber, a microscope adjacently arranged on the outside of the reaction chamber.

Abstract: An apparatus for growing diamonds, the apparatus comprising: one or more chambers, each chamber is in fluid connection with one or more other chambers, each chamber comprising one or more substrate stage assembly within the chamber to support a substrate stage having a plurality of diamond seeds disposed thereon.

Abstract: A monocrystalline diamond having a corrected full width at half maxima after accounting for the Rayleigh width of a 514.5 nm laser, and exhibiting: a presence or absence of negatively-charged silicon vacancy defect depending on the diamond quality; a concentration level of neutral substitutional nitrogen at an absorption coefficient of 270 nm; an FTIR transmittance value at a 10.6 ?m wavelength; a concentration of positively-charged substitutional nitrogen when the peak height is at 1332.5 cm?1; an absence of nitrogen-vacancy-hydrogen defect species when the wavelength is at 3123 cm?1; normalisation of spectra when the first order Raman peak is at 552.37 nm using 514.5 nm laser excitation; either a black or white sector and having a refractive index of retardation to thickness of diamond plates; or a reddish glow and a blue glow when the diamond is placed under 355 nm laser irradiation at room temperature in the dark.

Abstract: An apparatus for producing diamond and performing real time in situ analysis, comprising: a housing, a reaction chamber, the reaction chamber being structurally connected to the housing, the reaction chamber comprising of an enclosed area adapted to house the growing of diamonds, a radiating means, the radiating means being mounted above the reaction chamber within the housing, the radiating means adapted to emit microwave into the reaction chamber to effect the growth of diamonds within the reaction chamber, a dielectric cover being provided at the top of the reaction chamber and adapted to allow the radiation wave from the radiating means to enter the reaction chamber, a recording means mounted within the annual housing and above the reaction chamber, a measuring mechanism arranged at the periphery of the reaction chamber, a microscope adjacently arranged on the outside of the reaction chamber.

Abstract: A method utilising microwave plasma chemical vapour deposition (MPCVD) process of producing electronic device grade single crystal diamond comprising of: (a) selecting a diamond seed or substrate having a pre-determined orientation, (b) cleaning and/or etching of non-diamond phases and other induced surface damages from the diamond seed or substrate, whereby this step can be performed one or more times, (c) growing a layer of extremely low crystal defect density diamond surface on the cleaned/etched diamond seed or substrate, whereby this step can be performed one or more times, and (d) growing electronics device grade single crystal diamond on top of the layer of the low crystal defect density diamond surface.

Abstract: A monocrystalline diamond having a corrected full width at half maxima after accounting for the Rayleigh width of a 514.5 nm laser, and exhibiting: a presence or absence of negatively-charged silicon vacancy defect depending on the diamond quality; a concentration level of neutral substitutional nitrogen at an absorption coefficient of 270 nm; an FTIR transmittance value at a 10.6 ?m wavelength; a concentration of positively-charged substitutional nitrogen when the peak height is at 1332.5 cm?1; an absence of nitrogen-vacancy-hydrogen defect species when the wavelength is at 3123 cm?1; normalisation of spectra when the first order Raman peak is at 552.37 nm using 514.5 nm laser excitation; either a black or white sector and having a refractive index of retardation to thickness of diamond plates; or a reddish glow and a blue glow when the diamond is placed under 355 nm laser irradiation at room temperature in the dark.

Abstract: Disclosed are methods for producing ZnO nanostructures, the methods comprising heating an aqueous solution comprising a zinc compound, a base, and a polymer which is polyvinylpyrrolidinone or poly(ethylene glycol).

Abstract: A method of forming mono-crystalline diamond by chemical vapor deposition, the method comprising the steps of: (a) providing at least one diamond seed; (b) exposing the seed to conditions for growing diamond by chemical vapor deposition, including supplying reaction gases that include a carbon-containing gas and hydrogen for growing diamond and include a nitrogen-containing gas; and (c) controlling the quantity of nitrogen-containing gas relative to other gases in the reaction gases such that diamond is caused to grow by step-growth with defect free steps without inclusions. The nitrogen is present in the range of 0.0001 to 0.02 vol %. Diborane can also be present in a range of from 0.00002 to 0.002 vol %. The carbon-containing gas can be methane.

Abstract: An apparatus for growing diamonds, the apparatus comprising: one or more chambers, each chamber is in fluid connection with one or more other chambers, each chamber comprising one or more substrate stage assembly within the chamber to support a substrate stage having a plurality of diamond seeds disposed thereon.

Abstract: The present invention is related to an apparatus for the manufacture of gem grade diamonds. The apparatus has a plurality chambers (52) arranged in series to allow gas flow from a first chamber to a last chamber. Each chamber has a substrate stage assembly (10) to support a plurality of diamond seeds (19), a microwave generator (36) and a microwave source (38) to supply microwave energy into the chamber via a microwave arrangement (37)). A gas supply (54) to supply gases to form the diamonds to the first chamber. The gases supplied to the first chamber are used in sequence with the gases exiting the first chamber becoming the input for a second chamber and then subsequent chambers in series. A vacuum pump is after the final vacuum chamber.

Abstract: The present application discloses the details of a microwave plasma chemical vapor deposition process that uses Nitrogen and Diborane simultaneously in combination along with the Methane and Hydrogen gases to grow white color diamonds. The invention embodies using nitrogen to avoid inclusions and impurities in the CVD diamond samples and Diborane for the color enhancement during the growth of diamond. It is also found that heating of the so grown diamonds to 2000 C results in significant color enhancement due to the compensation of Nitrogen and Boron centers in the samples. The origin of the various colors in diamond is explained on the basis of the band diagram of CVD diamond.

Abstract: A method comprising patterning a substrate to form exposed regions of the substrate sized to deter entangled growth of carbon nanotubes thereon and growing vertically aligned nanotubes on the exposed regions of the substrate.

Abstract: Disclosed are methods for producing ZnO nanostructures, the methods comprising heating an aqueous solution comprising a zinc compound, a base, and a polymer which is polyvinylpyrrolidinone or poly(ethylene glycol).

Abstract: A method of forming mono-crystalline diamond by chemical vapour deposition, the method comprising the steps of: (a) providing at least one diamond seed; (b) exposing the seed to conditions for growing diamond by chemical vapour deposition, including supplying reaction gases that include a carbon-containing gas and hydrogen for growing diamond and include a nitrogen-containing gas; and (c) controlling the quantity of nitrogen-containing gas relative to other gases in the reaction gases such that diamond is caused to grow by step-growth with defect free steps without inclusions. The nitrogen is present in the range of 0.0001 to 0.02 vol %. Diborane can also be present in a range of from 0.00002 to 0.002 vol %. The carbon-containing gas can be methane.