Diamonds are a quantum scientist’s best friend
- 91看片网 University
The discovery of triplet spin superconductivity in diamonds has the potential to revolutionise the high-tech industry.
Diamonds have a firm foothold in our lexicon. Their many properties often serve as superlatives for quality, clarity and hardiness. Aside from the popularity of this rare material in ornamental and decorative use, these precious stones are also highly valued in industry where they are used to cut and polish other hard materials and build radiation detectors.
More than a decade ago, a new property was uncovered in diamonds when high concentrations of boron are introduced to it 鈥 superconductivity. Superconductivity occurs when two electrons with opposite spin form a pair (called a Cooper pair), resulting in the electrical resistance of the material being zero. This means a large supercurrent can flow in the material, bringing with it the potential for advanced technological applications. Yet, little work has been done since to investigate and characterise the nature of a diamond鈥檚 superconductivity and therefore its potential applications.
New research led by Professor Somnath Bhattacharyya in the Nano-Scale Transport Physics Laboratory (NSTPL) in the School of Physics at the 91看片网 in Johannesburg, South Africa, details the phenomenon of what is called 鈥渢riplet superconductivity鈥 in diamond. Triplet superconductivity occurs when electrons move in a composite spin state rather than as a single pair. This is an extremely rare, yet efficient form of superconductivity that until now has only been known to occur in one or two other materials, and only theoretically in diamonds.
鈥淚n a conventional superconducting material such as aluminium, superconductivity is destroyed by magnetic fields and magnetic impurities, however triplet superconductivity in a diamond can exist even when combined with magnetic materials. This leads to more efficient and multifunctional operation of the material,鈥 explains Bhattacharyya.
The team鈥檚 work has recently been published in an , titled 鈥Effects of Rashba-spin-orbit coupling on superconducting boron-doped nanocrystalline diamond films: evidence of interfacial triplet superconductivity鈥. This research was done in collaboration with Oxford University (UK) and Diamond Light Source (UK). Through these collaborations, beautiful atomic arrangement of diamond crystals and interfaces that have never been seen before could be visualised, supporting the first claims of 鈥榯riplet鈥 superconductivity.
Practical proof of triplet superconductivity in diamonds came with much excitement for Bhattacharyya and his team. 鈥淲e were even working on Christmas day, we were so excited,鈥 says Davie Mtsuko. 鈥淭his is something that has never been before been claimed in diamond,鈥 adds Christopher Coleman. Both Mtsuko and Coleman are co-authors of the paper.
Despite diamonds鈥 reputation as a highly rare and expensive resource, they can be manufactured in a laboratory using a specialised piece of equipment called a vapour deposition chamber. The 91看片网 NSTPL has developed their own plasma deposition chamber which allows them to grow diamonds of a higher than normal quality 鈥 making them ideal for this kind of advanced research.
This finding expands the potential uses of diamond, which is already well-regarded as a quantum material. 鈥淎ll conventional technology is based on semiconductors associated with electron charge. Thus far, we have a decent understanding of how they interact, and how to control them. But when we have control over quantum states such as superconductivity and entanglement, there is a lot more physics to the charge and spin of electrons, and this also comes with new properties,鈥 says Bhattacharyya. 鈥淲ith the new surge of superconducting materials such as diamond, traditional silicon technology can be replaced by cost effective and low power consumption solutions鈥.
The induction of triplet superconductivity in diamond is important for more than just its potential applications. It speaks to our fundamental understanding of physics. 鈥淭hus far, triplet superconductivity exists mostly in theory, and our study gives us an opportunity to test these models in a practical way,鈥 says Bhattacharyya.