185 high-performance-quantum-computing-"https:"-"https:"-"https:"-"https:" positions at University of Birmingham
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2D materials, searching for exotic quantum functionalities to form new sustainable electronics and new types of computing. Tuning nanostructures of these materials with extreme pressure will unlock
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We are seeking motivated candidates for a 3.5-year PhD project in Quantum Magnetism in the School of Physics and Astronomy at the University of Birmingham. Quantum magnetism is a research field at
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the development of a high k Si3N4 that retains its mechanical performance is very desirable and the subject of current research around the world. The highest k value yet achieved in a laboratory is ~170 Wm-1K-1
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Quantum field theory (QFT) is the framework that describes most quantum phenomena in the universe. One of the greatest open problems in QFT is to give a systematic way to understand strongly
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About the Role The Oxford Applied and Theoretical Machine Learning group at the Department of Computer Science is looking for a entrepreneurial Programme Manager to help run the group, in a very
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Topological phases of matter have reshaped how we think about quantum systems. Unlike conventional phases (such as solids, liquids, or magnets), which are characterized by local order, topological
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) in computational materials chemistry/physics, or related relevant area. The candidate must have demonstrable experience working with high-performance computing infrastructure. The candidate must have a
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Job Description Position Details School of Computer Science Location: University of Birmingham, Edgbaston, Birmingham UK Full time starting salary is normally in the range £29,647 to £31,460, with
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, they can utilise temporal and spatial diversity whilst simultaneously exploiting shared, intelligent adaptive signal processing whose combined performance and resilience can easily exceed that of the sum
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exchange energy at such rapid rate that they blend together to form hybrid states at room temperature (strong coupling regime). We recently shown that one can control the quantum state and interaction