Computability and compression of nonlocal games
Sajjad Nezhadi, University of Maryland - College Park
Quantum information science promises great potential to revolutionize our current technologies such as quantum computation, which can solve classically inaccessible problems. To build a practical quantum computer, it is essential to have precise control over individual quanta. By interfacing free-space photons and atomic platforms, we can maximize the performance of quantum computation, as each platform has its own advantages.
Where can an undergraduate degree in mathematics, science or engineering take you? Hear from panelists about their own career journeys launched from STEM degrees.
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Parametric couplings offers the exciting possibility to manipulate and control interactions between engineered quantum systems. Such systems are artificial mesoscopic systems whose dynamics are governed by the laws of quantum mechanics. Prominent examples of these mesoscopic systems are ultracold trapped atoms and ions, superconducting circuits and electro/optomechanical systems.
Efficient quantum algorithm for dissipative nonlinear differential equations
Jin-Peng Liu, University of Maryland - College Park
Join us for casual conversations with quantum researchers.
Alan Jamison, Assistant Professor at IQC and the Department of Physics and Astronomy at the University of Waterloo, joins us for our next virtual Fireside Chat. We’ll talk about working under a Nobel laureate, teaching online before it was cool, and how to chill a molecule to nearly absolute zero.
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Schur-Weyl duality and symmetric problems with quantum input
Laura Mancinska, University of Copenhagen
We're teaming up with Social Art for a fun night of virtual painting and quantum exploration.
The success of superconducting quantum computing (SQC) has so far been largely built upon the transmon qubit. Finding an alternative qubit that drastically outperforms transmon represents one of the most fundamental and exciting frontiers of SQC. The fluxonium qubit stands out as a promising candidate, due to its long coherence times and large anharmonicity. Furthermore, fluxonium can be directly integrated into the existing circuit-QED schemes for scaling.
Quantum Today is an exciting new seminar series that pulls its themes from recently published scientific articles. Join us as we sit down in conversation with researchers to talk about their work, what’s the impact and where their research will lead to.