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Wednesday, April 4, 2018 10:30 am - 10:30 am EDT (GMT -04:00)

‘Free-space’ Chiral Quantum Optics and a ‘Few-Atom’ Quantum Antenna

Peter Zoller - University of Innsbruck

We start with an overview of chiral quantum optics as quantum light-atom interfaces with broken left- right symmetry and associated quantum optical phenomena and applications. While chiral quantum optics is traditionally discussed in context of nano-photonics and nano fibers , we propose here a novel ‘free-space’ chiral quantum optics realized as atoms in free space coupled to a ‘few-atom’ quantum antenna. In particular, we discuss free space photonic quantum links between atoms (qubits) equipped with sending and receiving quantum antennas.

Friday, April 6, 2018 11:45 am - 11:45 am EDT (GMT -04:00)

RAC1 Journal Club/Seminar Series

Xiaodong MaXiaodong Ma: Topological insulator and the quantum anomalous Hall effect

The quantum anomalous Hall effect (QAHE) is defined as a quantized Hall effect in a system without an external magnetic field. Its physical origin relies on the intrinsic topological inverted band structure and ferromagnetism.

Monday, April 9, 2018 2:30 pm - 2:30 pm EDT (GMT -04:00)

Excitations in Topological Superfluid 3He

Yoonseok Lee, University of Florida

After the discovery of topological insulators, the concept of topology permeated the various fields of condensed matter physics. Symmetry of a quantum system plays an intriguing role in close association with topology, expanding the range of topological quantum systems to superconductors/superfluids. Superfliuid 3He, which has been a prime example of symmetry breaking phase transition, is also recognized as a quantum system with various topological nature.

Tuesday, April 10, 2018 10:30 am - 10:30 am EDT (GMT -04:00)

Cryogenic Dissipation in Nanoscale Optomechanical Cavities

Bradley Hauer, University of Alberta

Cavity optomechanics, a field which studies the interplay between the photonic and phononic modes of an optical cavity, has seen rapid progress over the past decade. Micro/nano-scale optomechanical cavities have demonstrated potential for use in technologies such as quantum-limited metrology and transduction, as well as probes for exploring the fundamental nature of quantum mechanics.

Tuesday, April 10, 2018 1:30 pm - 1:30 pm EDT (GMT -04:00)

Spatial noise filtering through error correction for quantum sensing

David Layden - Massachusetts Institute of Technology (MIT)

Sensors based on quantum effects can measure various external quantities, such as magnetic fields, with high precision. Moreover, their sensitivity can scale more favourably with their size than is allowed classically — a property analogous to quantum speedups in computing. As with quantum computers, the performance of quantum sensors is limited by decoherence. Quantum error correction (QEC) has recently emerged as a promising approach to mitigate this decoherence, and therefore, to enhance sensitivity.

Wednesday, April 11, 2018 1:00 pm - 1:00 pm EDT (GMT -04:00)

Mind the gap: Cheeger inequalities and adiabatic algorithms

Michael Jarret, Perimeter Institute for Theoretical Physics

The runtime of Adiabatic optimization algorithms are typically characterized by the size of the spectral gap of the corresponding Hamiltonian. Gap analysis nonetheless remains a challenging problem with few general approaches.

Thursday, April 12, 2018 12:00 pm - 12:00 pm EDT (GMT -04:00)

Transformative Quantum Technologies (TQT) Lunch and Learn

A Case Study in Patent Development

This presentation will delve into a practical example of a patent procedure associated to a specific quantum technology: a vectorial magnetometer. We will explore the specifics of the technology and its applications, review previously existing approaches and define the inventive step, explore the phrasing of the claims, and revisit the prior patents from the freedom-to-operate point of view.

Thursday, April 19, 2018 12:00 pm - 12:00 pm EDT (GMT -04:00)

The Polynomial Method Strikes Back: Tight Quantum Query Bounds via Dual Polynomials

Robin Kothari, Microsoft Research (PLEASE NOTE NEW DATE AND TIME)

We use the polynomial method to prove optimal or nearly optimal lower bounds on the quantum query complexity of several problems, resolving open questions from prior work. The problems studied include k-distinctness, image size testing, k-junta testing, approximating statistical distance, approximating Shannon entropy, and surjectivity.​ Paper available at https://arxiv.org/abs/1710.09079. This is joint work with Mark Bun and Justin Thaler.