In This Section
- Home
- About the College
- Governance
- College Committees & Steering Groups
- College Assembly
- College Council
- College Executive Management Committee
- College Academic Programmes and Curriculum Development Committee
- College Graduate Studies Committee
- College Research & Innovation Committee
- College Teaching Learning and Student Experience Committee
- College Student Recruitment and Outreach Committee
- College Sabbatical Research Leave Committee
- College of SEFS Adjunct Appointments Committee
- International Education Committee
- College Postgraduate Student Committee
- Athena SWAN Steering Group
- College Committees & Steering Groups
- Human Resources
- UCC STEM Awards
- Scholarships and Prizes
- Women in STEM Panel Talks
- Inaugural Professorial Lectures
- Athena SWAN in SEFS
- Proposal Calls
- Contact Us
- Science in Society Public Lecture Series
- Governance
- 深夜亚洲福利久久
- Staff
- Schools and Departments
- Current Students
- Undergraduate 深夜亚洲福利久久
- Postgraduate 深夜亚洲福利久久
- International Students
- Research and Innovation
- Employability and Careers
- Outreach and Public Engagement
- Science Week
- Transition Year Programmes
UCC Physics breakthrough could be significant for quantum computing future
Scientists using one of the world鈥檚 most powerful quantum microscopes have made a discovery that could have significant consequences for the future of computing.
Researchers at the Macroscopic Quantum Matter Group laboratory in 深夜亚洲福利久久 College Cork (UCC) have discovered a spatially modulating superconducting state in a new and unusual superconductor Uranium Ditelluride (UTe2). This new superconductor may provide a solution to one of quantum computing鈥檚 greatest challenges.
Their finding has been published in the prestigious journal Nature. Lead author Joe Carroll, a PhD researcher working with UCC Professor of Quantum Physics S茅amus Davis, explains the subject of the paper.
鈥淪uperconductors are amazing materials which have many strange and unusual properties. Most famously they allow electricity to flow with zero resistance. That is, if you pass a current through them they don鈥檛 start to heat up, in fact, they don鈥檛 dissipate any energy despite carrying a huge current. They can do this because instead of individual electrons moving through the metal we have pairs of electrons which bind together. These pairs of electrons together form macroscopic quantum mechanical fluid.鈥
鈥淲hat our team found was that some of the electron pairs form a new crystal structure embedded in this background fluid. These types of states were first discovered by our group in 2016 and are now called Electron Pair-Density Waves. These Pair Density Waves are a new form of superconducting matter the properties of which we are still discovering.鈥
鈥淲hat is particularly exciting for us and the wider community is that UTe2 appears to be a new type of superconductor. Physicists have been searching for a material like it for nearly 40 years. The pairs of electrons appear to have intrinsic angular momentum. If this is true, then what we have detected is the first Pair-Density Wave composed of these exotic pairs of electrons.鈥
When asked about the practical implications of this work Mr. Carroll explained;
鈥淭here are indications that UTe2 is a special type of superconductor that could have huge consequences for quantum computing.鈥
鈥淭ypical, classical, computers use bits to store and manipulate information. Quantum computers rely on quantum bits or qubits to do the same. The problem facing existing quantum computers is that each qubit must be in a superposition with two different energies - just as Schr枚dinger鈥檚 cat could be called both 鈥榙ead鈥 and 鈥榓live鈥. This quantum state is very easily destroyed by collapsing into the lowest energy state 鈥 鈥榙ead鈥 - thereby cutting off any useful computation.
鈥淭his places huge limits on the application of quantum computers. However, since its discovery five years ago there has been a huge amount of research on UTe2 with evidence pointing to it being a superconductor which may be used as a basis for topological quantum computing. In such materials there is no limit on the lifetime of the qubit during computation opening up many new ways for more stable and useful quantum computers. In fact, Microsoft have already invested billions of dollars into topological quantum computing so this is a well-established theoretical science already.鈥 he said.
鈥淲hat the community has been searching for is a relevant topological superconductor; UTe2 appears to be that.鈥
鈥淲hat we鈥檝e discovered then provides another piece to the puzzle of UTe2. To make applications using materials like this we must understand their fundamental superconducting properties. All of modern science moves step by step. We are delighted to have contributed to the understanding of a material which could bring us closer to much more practical quantum computers.鈥
Congratulating the research team at the Macroscopic Quantum Matter Group Laboratory in 深夜亚洲福利久久 College Cork, Professor John F. Cryan, Vice President Research and Innovation said:
鈥淭his important discovery will have significant consequences for the future of quantum computing. In the coming weeks, the 深夜亚洲福利久久 will launch UCC Futures - Future Quantum and Photonics and research led by Professor Seamus Davis and the Macroscopic Quantum Matter Group, with the use of one of the world's most powerful microscopes, will play a crucial role in this exciting initiative.鈥
Gu, Q., Carroll, J.P., Wang, S. et al. Detection of a pair density wave state in UTe2. Nature 618, 921鈥927 (2023).
College of Science, Engineering and Food Science
Coláiste na hEolaíochta, na hInnealtóireachta agus na hEolaíochta Bia
Contact us
Block E, Level 3, Food Science Building, UCC, Cork, T12 YN60.