Abstract: Disclosed herein are methods of manufacturing synthetic CVD diamond material including orienting and controlling process gas flow in a microwave plasma reactor to improve performance. The microwave plasma reactor includes a gas flow system with a gas inlet comprising one or more gas inlet nozzles disposed opposite the growth surface area and configured to inject process gases towards the growth surface area. The method comprises injecting process gases towards the growth surface area at a total gas flow rate equal to or greater than 500 standard cm3 per minute wherein the process gases are injected into the plasma chamber through the one or more gas inlet nozzles with a Reynolds number in a range 1 to 100.

Abstract: A solid state system comprising a host material and a quantum spin defect, wherein the quantum spin defect has a T2 at room temperature of about 300 ?s or more and wherein the host material comprises a layer of single crystal CVD diamond having a total nitrogen concentration of about 20 ppb or less, wherein the surface roughness, Rq of the single crystal diamond within an area defined by a circle of radius of about 5 ?m centered on the point on the surface nearest to where the quantum spin defect is formed is about 10 nm or less, methods for preparing solid state systems and the use of single crystal diamond having a total nitrogen concentration of about 20 ppb or less in spintronic applications are described.

Abstract: A device for achieving multi-photon interference is provided based on nitrogen-vacancy defects in diamond material. Nitrogen-vacancy defects having a narrow band width and a similar emission frequency are identified within a high quality diamond material. The device has an excitation arrangement configured to individually address nitrogen-vacancy defects and optical outcoupling structures for increasing outcoupling of photons from each nitrogen-vacancy defect. A tuning arrangement is configured to tune the emission from each nitrogen-vacancy defect to reduce differences in frequency and the photons are overlapped. A detector is provided to detect the photon emissions. The detector is configured to resolve sufficiently small differences in photon detection times such that tuned photon emissions from the nitrogen-vacancy defects are quantum mechanically indistinguishable resulting in quantum interference between indistinguishable photon emissions from different nitrogen-vacancy defects.

Abstract: Single crystal diamond having a high chemical purity i.e. a low nitrogen content and a high isotopic purity i.e. a low 13C content, methods for producing the same and a solid state system comprising such single crystal diamond are described.

Abstract: A synthetic single crystal diamond material comprising: a first region comprising electron donor defects; a second region comprising quantum spin defects; and a third region between the first and second regions. The second and third regions have a lower concentration of electron donor defects than the first region. The first and second regions are sufficiently close to allow electrons to be donated from the first region to the second region, thus forming negatively charged quantum spin defects in the second and positively charged defects in the first region, and sufficiently far apart to reduce other coupling interactions between the first and second regions which would otherwise unduly reduce the decoherence time of the plurality of quantum spin defects and/or produce strain broaden of a spectral line width of the plurality of quantum spin defects in the second region.

Abstract: A method of manufacturing an optical element, the method comprising: growing a first layer of single crystal diamond material via a chemical vapor deposition technique using a gas phase having a first nitrogen concentration; growing a second layer of single crystal diamond material over said first layer via a chemical vapor deposition technique using a gas phase having a second nitrogen concentration, wherein the second nitrogen concentration is lower than the first nitrogen concentration; forming an optical element from at least a portion of the second layer of single crystal diamond material; and forming an out-coupling structure at a surface of the optical element for increasing out-coupling of light.

Abstract: A device for achieving multi-photon interference, said device comprising: at least two solid state photon emitters, each solid state photon emitter comprising nuclear and electron spin states coupled together, each solid state photon emitter being configured to produce photon emission comprising a photon emission peak, wherein the photon emission peaks from different solid state photon emitters have a first frequency difference between peak intensities, and wherein the electron spin states of each solid state photon emitter are resolvable; an excitation arrangement configured to individually address the at least two solid state photon emitters; a plurality of optical out coupling structures wherein each solid state photon emitter is provided with an associated optical out coupling structure; a tuning arrangement configured to reduce the first frequency difference between the peak intensities of the photon emission peaks from the at least two solid state photon emitters to a second frequency difference which i

Abstract: A thin plate of synthetic single crystal diamond material, the thin plate of synthetic single crystal diamond material having: a thickness in a range 100 nm to 50 ???; a concentration of quantum spin defects greater than 0.1 ppb (parts-per-billion); a concentration of point defects other than the quantum spin defects of below 200 ppm (parts-per-million); and wherein at least one major face of the thin plate of synthetic single crystal diamond material comprises surface termination species which have zero nuclear spin and/or zero electron spin.

Abstract: A single crystal synthetic CVD diamond material comprising: a growth sector; and a plurality of point defects of one or more type within the growth sector, wherein at least one type of point defect is preferentially aligned within the growth sector, wherein at least 60% of said at least one type of point defect shows said preferential alignment, and wherein the at least one type of point defect is a negatively charged nitrogen-vacancy defect (NV?).

Abstract: A thin plate of synthetic single crystal diamond material, the thin plate of synthetic single crystal diamond material having: a thickness in a range 100 nm to 50 ???; a concentration of quantum spin defects greater than 0.1 ppb (parts-per-billion); a concentration of point defects other than the quantum spin defects of below 200 ppm (parts-per-million); and wherein at least one major face of the thin plate of synthetic single crystal diamond material comprises surface termination species which have zero nuclear spin and/or zero electron spin.

Abstract: A microfluidic cell comprising: a microfluidic channel (32) for receiving a fluid sample; and a sensor (30) located adjacent the microfluidic channel; wherein the sensor comprises a diamond material comprising one or more quantum spin defects (34). In use, a fluid sample is loaded into the microfluidic cell and the fluid is analyzed via magnetic resonance using the quantum spin defects.

Abstract: A single crystal synthetic CVD diamond material comprising: a growth sector; and a plurality of point defects of one or more type within the growth sector, wherein at least one type of point defect is preferentially aligned within the growth sector, wherein at least 60% of said at least one type of point defect shows said preferential alignment, and wherein the at least one type of point defect is a negatively charged nitrogen-vacancy defect (NV?).

Abstract: A microfluidic cell comprising: a microfluidic channel (32) for receiving a fluid sample; and a sensor (30) located adjacent the microfluidic channel; wherein the sensor comprises a diamond material comprising one or more quantum spin defects (34). In use, a fluid sample is loaded into the microfluidic cell and the fluid is analysed via magnetic resonance using the quantum spin defects.

Abstract: A synthetic single crystal diamond material comprising: a first region of synthetic single crystal diamond material comprising a plurality of electron donor defects; a second region of synthetic single crystal diamond material comprising a plurality of quantum spin defects; and a third region of synthetic single crystal diamond material disposed between the first and second regions such that the first and second regions are spaced apart by the third region, wherein the second and third regions of synthetic single crystal diamond material have a lower concentration of electron donor defects than the first region of synthetic single crystal diamond material, and wherein the first and second regions are spaced apart by a distance in a range 10 nm to 100 ?m which is sufficiently close to allow electrons to be donated from the first region of synthetic single crystal diamond material to the second region of synthetic single crystal diamond material thus forming negatively charged quantum spin defects in the second

Abstract: A method of manufacturing an optical element, the method comprising: growing a first layer of single crystal diamond material via a chemical vapour deposition technique using a gas phase having a first nitrogen concentration; growing a second layer of single crystal diamond material over said first layer via a chemical vapour deposition technique using a gas phase having a second nitrogen concentration, wherein the second nitrogen concentration is lower than the first nitrogen concentration; forming an optical element from at least a portion of the second layer of single crystal diamond material; and forming an out-coupling structure at a surface of the optical element for increasing out-coupling of light.

Abstract: Single crystal diamond having a high chemical purity i.e. a low nitrogen content and a high isotopic purity i.e. a low 13C content, methods for producing the same and a solid state system comprising such single crystal diamond are described.

Abstract: A solid state system comprising a host material and a quantum spin defect, wherein the quantum spin defect has a T2 at room temperature of about 300 ?s or more and wherein the host material comprises a layer of single crystal CVD diamond having a total nitrogen concentration of about 20 ppb or less, wherein the surface roughness, Rq of the single crystal diamond within an area defined by a circle of radius of about 5 ?m centred on the point on the surface nearest to where the quantum spin defect is formed is about 10 nm or less, methods for preparing solid state systems and the use of single crystal diamond having a total nitrogen concentration of about 20 ppb or less in spintronic applications are described.

Abstract: A modular chamber assembly comprising: — (i) one or more base portions, said base portion incorporating one or more spigots; (ii) a riser portion; (iii) optionally a lid to close the top of the riser portion; the base portion(s) and riser portion being adapted to nest one on top of another.

Abstract: A sump assembly (70) comprising: (i) a sump body (71) including a bottom and at least one side wall (72), the bottom and side wall(s) co-operating to define an open topped internal cavity within the sump body capable of containing fluids, the side walls further defining an opening (76) in the top of said sump; (ii) at least one flange (77) extending outwardly from the side wall(s), the flange incorporating fixing means (79) adapted, in use, to tie the sump into the surrounding structure; (iii) a mounting frame assembly (90) adapted, in use, to be keyed into the surrounding structure and to secure a dispensing unit in place; wherein the sump body and the flange(s) are of unitary construction, the flange(s) being formed as an integral part of the sump body.