Events | The Helen Diller Quantum Center

Events

May

2021

16:30

Prof. Daniel Gottesman: "Maximally sensitive sets of states"

Weekly seminar

06 May 2021

16:30

17:30

Abstract: Coherent errors in a quantum system can, in principle, build up much more rapidly than incoherent errors, accumulating as the square of the number of qubits in the system rather than linearly. I will characterize the types of channels that can exhibit such behavior and present a simple pr

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Apr

2021

16:30

Prof. Frank Pollmann: "Exploring Topological Phases on Quantum Processors"

Weekly seminar

29 Apr 2021

16:30

17:30

Universal quantum computers are potentially an ideal setting for simulating emergent quantum many-body phenomena that are out of reach for classical computers. Here we discuss two applications to the study of topologically ordered systems: First, we represent the ground states of Hamiltonians using

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Apr

2021

16:30

Prof. Mikhail Lukin: "Exploring new scientific frontiers with programmable quantum systems"

Weekly seminar

22 Apr 2021

16:30

Abstract: I will discuss recent developments at a new scientific interface between quantum optics, quantum many-body physics, information science, and engineering. Specifically, I will focus on two examples at this interface involving realization of programmable quantum systems and their first sci

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Mar

2021

16:00

Prof. Ish Dhand: "Xanadu's Blueprint for a scalable photonic fault-tolerant quantum computer"

Weekly seminar

04 Mar 2021

16:00

Photonics is the platform of choice to build a modular, easy-to-network quantum computer operating at room temperature. However, no concrete architecture has been presented so far that exploits both the advantages of qubits encoded into states of light and the modern tools for their generation.

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Feb

2021

16:30

Prof. David Schuster: "Building materials from microwave photons"

Weekly seminar

18 Feb 2021

16:30

The study of condensed matter systems in electronic systems within solid-state materials has a long history.
More recently, it has become possible to realize synthetic systems out of controllable components in ultracold atom or photonic systems.

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Feb

2021

16:30

Prof. Ian B. Spielman: "Coherence and decoherence in the Harper-Hofstadter model"

Weekly seminar

11 Feb 2021

16:30

We experimentally realized the Harper-Hofstadter (HH) model describing charged particles in a two-dimensional lattice with a transverse magnetic field using an atomic Bose-Einstein condensate in a highly elongated tube geometry, three sites in circumference.

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Feb

2021

16:30

Prof. Morten Kjaergaard: "Programming a quantum computer with quantum instructions"

Weekly seminar

04 Feb 2021

16:30

The use of qubits to construct computers opens the door to dramatic computational speed ups for certain problems.

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Jan

2021

16:30

Prof. Martin Plenio: "Quantum Technologies for the Lifesciences"

Weekly seminar

28 Jan 2021

16:30

Starting with the development of microscopes which enabled
the discovery of bacteria time and again, physicists have discovered and
then harnessed natural phenomena and the proceeded to use them to
open new windows of observation into the life sciences. Examples include

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Jan

2021

16:30

Prof. Lukasz Fidkowski: "How Dynamical Quantum Memories Forget"

Weekly seminar

21 Jan 2021

16:30

Making local measurements on an entangled quantum many-body state is expected to reduce quantum entanglement. However, recently it was found that in the thermodynamic limit it is possible to robustly protect quantum entanglement from continuous local measurements.

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Jan

2021

16:30

Prof. Peter Zoller: "Programming Quantum Simulators"

Weekly seminar

07 Jan 2021

16:30

Cold atoms and ions provide one of the best ways to build controllable quantum many-body systems as quantum computers and quantum simulators. Here we report on recent developments in programming quantum simulators with focus on hybrid classical-quantum scenarios.

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International Calendar of Events

Research

How does light propagate in integrated circuits on chips?

Researchers at the Technion are answering this question and paving the way to new applications in communication, imaging, and quantum computing. The field of photonic integrated circuits focuses on the miniaturization of photonic elements and their integration in photonic chips – circuits that carry out a range of calculations using..

Yuval Shagam won an ERC grant

Assistant Professor Yuval Shagam from the Schulich Faculty of Chemistry is a member of the Helen Diller Quantum Center. He focuses on understanding molecular chirality: a molecule or ion that cannot be superposed on its mirror image. Such molecules are often distinguished as either “right-handed” or “left-handed.” Molecular chirality plays a central role in many fields, ranging from reaction dynamics to drug development. Molecules of opposite-handedness, known as enantiomers, can have different smells and different medicinal properties among other things.

Toward the discovery of new quantum phenomena that have yet to be observed: Prof. Ido Kaminer of the Technion won an ERC Consolidator grant

Prof. Ido Kaminer of the Viterbi Faculty of Electrical and Computer Engineering won an ERC Consolidator grant from the European Research Council.ERC Consolidator grants support select scientists who propose pioneering, ground-breaking research ideas. The grant will be used by Prof. Kaminer’s research team to develop a theory and innovative experimental platform for a new field in electron microscopy: Q-in-PINEM. The research will focus on creating new quantum states and identifying unique quantum properties for materials.

Atomic-scale spin-optical laser: new horizon for optoelectronics

Researchers from the Technion have pushed the limits of the possible in the field of atomic-scale spin-optics, creating a spin-optical laser from monolayer-integrated spin-valley microcavities without requiring magnetic fields or cryogenic temperatures

The physical world through the lens of computational complexity

“Computers are physical systems, and so are our brains. Therefore, they are subject to physical laws that determine what they can and cannot calculate,” points out Prof. Itai Arad, a theoretical physicist who researches the field of quantum information. He is determined to better understand physical systems by drawing on tools and insights from a variety of disciplines – including condensed matter physics, information theory, computer science and statistical mechanics. Specifically, Prof.