2017 — 2021 |
Fu, Liang Checkelsky, Joseph [⬀] |
N/AActivity Code Description: No activity code was retrieved: click on the grant title for more information |
Convergence Ql: Nsf/Doe Quantum Science Summer School @ Massachusetts Institute of Technology
Non-technical Abstract:
The invention of quantum mechanics in the early decades of 20th century introduced strangeness and spookiness to the seemingly complete classical world. This first quantum revolution enabled the amazing technological developments of the 20th century, resulting e.g. in modern electronics and immense societal impact. Today the world is witnessing the early days of the second quantum revolution, where the convergent elements of quantum mechanics like quantum superposition or quantum entanglement will lead to widespread practical applications in quantum computing, quantum cryptography or quantum sensing. One of the major obstacles in achieving this goal is lack of specialized workforce. The required qualifications comprise deep understanding of quantum mechanics, but also include practical knowledge of the convergent fields of microwave electronics, cryogenic and ultra-high vacuum technologies, quantum materials, advanced computer programming and algorithm optimization, with elements of device and system engineering. Existing educational programs usually specialize in only one or two of the above areas. This project helps fill the void in educating the future cadre for quantum revolution by putting together a transdisciplinary group of practitioners experienced in various aspects of quantum science with a group of select graduate students from across the US in the form of an annually recurring Summer School. The cultural and intellectual challenge comes from a need to equip students with practical knowledge of multiple fields relevant to quantum revolution, but also from the desire to foster their ability to learn and maintain the curiosity needed for future progress. The interactions of students with leaders in the field are based on a mixture of direct presentations, tutorials and talks, with interactive activities including round table discussions, student presentations, and courses in practical use of quantum technology. Interactions between speakers from various disciplines, from condensed matter physics through quantum chemistry and engineering, are expected to generate new ideas at the boundaries of fields.
Technical Abstract: As the first quantum revolution of the 1920s led to the modern digital and telecommunications age of the present day, the current position of quantum science suggests that a second quantum revolution is at hand which is expected to have wide reaching implications not only for our fundamental understanding of the natural world but also for computing, energy, and global connectivity. A critical component of this development is the education of the next generation of scientists in the principles, methods, and goals of this "Quantum Leap". This is motivated by the observation that the rapidly growing quantum industry is facing an acute shortage of uniquely qualified workforce. New approaches to education in quantum science are particularly important given the breadth of disciplines brought together in this area- reaching across mathematics, chemistry, physics, materials science, and engineering. As part of initiating this educational effort, this project puts forth a summer school for graduate students as a direct tool to provide an in-depth immersion in the emerging field of convergent quantum science and technology. The approach of this gathering is a summer school wherein students are exposed to education in science and technology beyond what they could be exposed to in traditional classroom settings or typical conferences/workshops. Lecturers focus on pedagogical lectures on these topics rather than seminar style research presentations. Afternoon sessions are aimed at interactive activities involving students and presenters. Themed panels with speakers and organizers serving as panel members for both scientific and career related sessions are planned. The lecturers are encouraged to participate in several days rather than one or two days, to include the additional benefit of cross-disciplinary "pollination" of ideas between lecturers from different disciplines. The program combines aspects of classroom style education, research seminars, multitude of interactive forms and an active discussion forum. The two week duration for the school encourages both formal and informal discussion between students and lecturers as well as among the students themselves.
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2020 — 2021 |
Lee, Patrick (co-PI) [⬀] Lee, Patrick (co-PI) [⬀] Moodera, Jagadeesh [⬀] Fu, Liang Wei, Peng (co-PI) [⬀] Oliver, William (co-PI) [⬀] |
N/AActivity Code Description: No activity code was retrieved: click on the grant title for more information |
Nsf Convergence Accelerator Track C: Synergistic Thrusts Towards Practical Topological Quantum Computing @ Massachusetts Institute of Technology
The NSF Convergence Accelerator supports use-inspired, team-based, multidisciplinary efforts that address challenges of national importance and will produce deliverables of value to society in the near future. This project seeks to develop approaches that address issues of decoherence and crosstalk by scalable topological superconductors (TSC). Investigation for achieving realistic large-scale quantum computers is required to advance the field of quantum information science. This project will integrate Majorana zero modes (MZMs) into conventional superconducting qubit architectures to advance their application to quantum computing. By having outreach programs towards K-12 students and research experiences for undergraduates, this project will broaden participation in quantum with a focus on underrepresented minorities. The project will build and establish a cross-sector team that will develop advances in controlling the topological nature of materials to advance quantum computing to deliver fault-tolerant qubits and their quantum interconnects. This project seeks (1) to understand and demonstrate the non-local topological nature of the MZMs by detecting the electron teleportation through a pair of MZMs; (2) to establish the basic elements for measuring the parity state in a teleportation-based T-qubit; (3) to explore flux quantization caused by a supercurrent loop that is mediated by the MZMs and set up the basic flux (or pseudo-spin) measurements of a T-qubit; (4) to identify and plan the Phase II research program, and (5) to build a strong team of academic, governmental lab, and industrial partners. Building on recent developments of a new TSC material platform, this project aims to demonstrate the quantum nature and the non-local topological protection of MZMs in the platform as well as build topological qubits that can be integrated into existing quantum computing circuitry. This may lead to greater functionality in superconducting circuits which can significantly advance topological quantum computing. The project deliverable includes a platform supporting topological qubit that is more robust and more scalable. By establishing a nationwide student exchange program and outreach activities to K-12 students, this project seeks to engage students in quantum research and training to broaden participation.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
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