Element Six, part of the De Beers Group, has launched DNV-B14™, its latest general-purpose Chemical Vapour Deposition (CVD) quantum-grade diamond, an ideal material for quantum technologies such as magnetic field devices, RF sensors, solid-state gyroscopes and room temperature masers.
The latest solution in Element Six’s DNV™ Series, DNV-B14™ expands the company’s range of advanced materials for emerging quantum technologies. Diamond containing nitrogen-vacancy (NV) centres offers researchers a unique solid-state platform with spin qubits that can be initialised and read out at room temperature, with long qubit lifetimes. These properties stem from diamond’s unique structure and strong bonds.
DNV-B14™ is designed to provide the end-user with a uniform and high density of NV spin centres - more than a 10-fold increase in NV density compared to DNV-B1™, the first material in the DNV™ Series. Launched last year, DNV-B1™ was winner of the SPIE Prism Award in the Quantum category in March 2021.
The combination of its engineered properties makes DNV-B14™ an ideal solution for experimentation and development of a range of technologies, such as ensemble NV-based vector magnetometry and room-temperature masers.
Dr Daniel Twitchen, Chief Technologist, stated that Element Six’s founder, Sir Ernest Oppenheimer said no great industry can exist or develop without fundamental research. The DNV™ Series represents exactly that, with sustained R&D within their CVD team spanning over ten years and working across an eco-system that includes large companies, start-ups and some of the world’s leading Universities.
Element Six diamond with NV densities comparable to DNV-B14™ has already been utilised in the development of high-sensitivity fibre-coupled magnetometers. Without the need for cumbersome cooling equipment, such devices can be made compact, and even portable. They are the ideal enabler of medical diagnostic techniques such as magnetocardiography (MCG) and magnetoencephalography (MEG).
Element Six’s engineered diamond research has also accelerated the delivery of many other breakthroughs in quantum research, including in 2018, when Imperial College London utilised engineered single crystal material in the development of the world’s first continuous-wave, room-temperature, solid-state maser (the microwave equivalent of a laser). Lockheed Martin’s 2019 Dark Ice program also relies on a DNV-enabled magnetometer that measures the direction and strength of nearly imperceptible magnetic field anomalies, opening up new possibilities in GPS-denied navigation.
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