The present invention relates to a free-standing single crystalline diamond part and a single crystalline diamond part production method. The method includes the steps of: —providing a single crystalline diamond substrate or layer; —providing a first adhesion layer on the substrate or layer; —providing a second adhesion layer on the first adhesion layer: —providing a mask layer on the second adhesion layer; —forming at least one indentation or a plurality of indentations through the mask layer and the first and second adhesion layers to expose a portion or portions of the single crystalline diamond substrate or layer; and—etching the exposed portion or portions of the single crystalline diamond substrate or layer and etching entirely through the single crystalline diamond substrate or layer.

The invention relates to the field of liquid phase synthesis of diamond or any other allotropic forms of carbon and more particularly to a process of liquid phase synthesis of carbonaceous films, according to which a voltage is applied, in a solution containing carbonaceous molecules, to a substrate on which a carbonaceous layer is to be deposited and photons are sent to the surface of the substrate. To this end, the invention also relates to a device for the liquid phase synthesis of carbonaceous films comprising a synthesis vessel inside which are arranged means for applying a voltage in a reaction zone, and photonic means are arranged to send photons to the reaction zone.

A diamond crystal substrate has a substrate surface that is one crystal plane among (100), (111), and (110) and that has atomic steps and terraces structure at an off-angle of 7° or less excluding 0°.

A diamond crystal substrate has a substrate surface that is one crystal plane among (100), (111), and (110) and that has atomic steps and terraces structure at an off-angle of 7° or less excluding 0°.

A method for forming a diamond product. Diamond material is provided and a damage layer comprising sp.sup.2 bonded carbon is formed in the material. The presence of the damage layer defines a first diamond layer above and in contact with the damage layer and a second diamond layer below and in contact with the damage layer. The damage layer is electrochemically etched to separate it from the first layer, wherein the electrochemical etching is performed in a solution containing ions, the solution having an electrical conductivity of at least 500 μS cm.sup.−1, and wherein the ions are capable of forming radicals during electrolysis. The diamond product is also described.

A method for forming a diamond product. Diamond material is provided and a damage layer comprising sp.sup.2 bonded carbon is formed in the material. The presence of the damage layer defines a first diamond layer above and in contact with the damage layer and a second diamond layer below and in contact with the damage layer. The damage layer is electrochemically etched to separate it from the first layer, wherein the electrochemical etching is performed in a solution containing ions, the solution having an electrical conductivity of at least 500 μS cm.sup.−1, and wherein the ions are capable of forming radicals during electrolysis. The diamond product is also described.

A method generates at least one deterministic F-center in a diamond layer. By implanting a dopant in the diamond layer and incorporating at least one foreign atom in the diamond layer by low-energy bombardment for the formation of the F-center in a second step, conversion rates of greater than 70% can be achieved. This is a significant increase in relation to undoped diamond, in which the conversion rates are only around 6%. Via doping with a donor, such as phosphorous, oxygen or sulphur, a good conversion into negatively charged F-centers can be achieved, which are used for Qubit applications.

A method generates at least one deterministic F-center in a diamond layer. By implanting a dopant in the diamond layer and incorporating at least one foreign atom in the diamond layer by low-energy bombardment for the formation of the F-center in a second step, conversion rates of greater than 70% can be achieved. This is a significant increase in relation to undoped diamond, in which the conversion rates are only around 6%. Via doping with a donor, such as phosphorous, oxygen or sulphur, a good conversion into negatively charged F-centers can be achieved, which are used for Qubit applications.

A substrate for a tool including at least one sidewall includes at least one diamond layer. The diamond layer has a thickness between 10 nanometers and 1000 nanometers and is formed from diamond grains sized to be 50% or less of diamond layer thickness, with the diamond coating being deposited on the surface of the substrate over the at least one sidewall.

A substrate for a tool including at least one sidewall includes at least one diamond layer. The diamond layer has a thickness between 10 nanometers and 1000 nanometers and is formed from diamond grains sized to be 50% or less of diamond layer thickness, with the diamond coating being deposited on the surface of the substrate over the at least one sidewall.