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Congratulations to Prof. Zvika Brakerski, who is among the Israeli scientists awarded the Blavatnik 2023 Award for Young Scientists!

The Blavatnik Family Foundation, the Israel Academy of Sciences and Humanities, and the New York Academy of Sciences, announced today the Laureates of the 2023 Blavatnik Awards for Young Scientists in Israel: read the full press release here

Prof. Zvika Brakerski from Weizmann Institute of Science is "recognized for developing the first efficient encryption algorithm that allows cloud computers to perform computations on encrypted data without the need to first decrypt them. His algorithm has enormous potential to improve the security of cloud computing. In addition, he has also developed new cryptography algorithms to verify the output of quantum computations."

The Quantum Twisting Microscope: A New Lens on Quantum Materials

One of the striking aspects of the quantum world is that a particle, say, an electron, is also a wave, meaning that it exists in many places at the same time. In a new study, researchers from the Weizmann Institute of Science make use of this property to develop a new type of tool – the quantum twisting microscope (QTM) – that can create novel quantum materials while simultaneously gazing into the most fundamental quantum nature of their electrons. Read more here

Prof. Thomas Vidick is the winner of the 2023 NAS Michael and Sheila Held Prize for his innovative work in quantum computing theory

Prof. Thomas Vidick will receive the 2023 Michael and Sheila Held Prize. The Prize is presented annually to honor outstanding, innovative, creative, and influential research in the areas of combinatorial and discrete optimization, or related parts of computer science, such as the design and analysis of algorithms and complexity theory. Prof. Vidick is receiving the prize for his breakthroughs in quantum complexity and quantum cryptography that led to the proof that the class of languages in which membership may be established by quantum multi-prover interactive proof systems is equal to the class of recursively enumerable languages. 
Read more here. 

Cross-institutional partnership between Weizmann Institute of Science and the University of Chicago propels global research in quantum science

The University of Chicago and the Weizmann Institute of Science in Israel will support collaborative research in quantum information sciences and artificial intelligence, in a partnership that also includes the Toyota Technological Institute at Chicago. “The Weizmann Institute has a long history of international collaborations that have inspired scientists to make a collective impact on global challenges,” said Alon Chen, president of the Weizmann Institute. “We look forward to continue to partner with the University of Chicago to combine our strengths in this new era of artificial intelligence and quantum science.”
Read more here

Weizmann's online course on Topological States of Matter

An online course on Topological Quantum Matter, prepared by members of the Department of Condensed Matter Physics of the Weizmann Institute, was launched in mid April 2022. This advanced course covers the fundamentals of the thriving field of Topological States of Matter. It discusses both theoretical and experimental aspects, and emphasizes the physical picture. Watch the trailer:

 

 

New scientist: Prof. Thomas Vidick

The exponential complexity that gives quantum computing its vast potential, however, also presents some fundamental challenges, chief among them the issue of whether results that are achieved can be trusted. Can these computations be verified, or is reliable testing restricted to classical systems? These are some of the questions that drive the research of Prof. Thomas Vidick, from the Department of Computer Science and Applied Mathematics.

Using interactive proofs and complexity theory to study these problems, Prof. Vidick aims to develop scalable, noise-resistant, and trustworthy protocols for verifying quantum devices. If successful, his work could go a long way toward realizing the potential of quantum computing for scientific discovery, security, and technology, and would lay the groundwork for future applications, such as a quantum internet. Read more here

In the Media: The Israeli Firm Creating the Chips the Quantum Computing Revolution Needs

“Dan, we have to talk.” These were the words Prof. Barak Dayan had for his old army buddy, high-tech entrepreneur Dan Harash, when they met at a class reunion three years ago. Dayan, head of the quantum optics laboratory at the Weizmann Institute of Science in Rehovot, was excited. He had recently realized that a breakthrough achieved in his lab may remove key physical obstacles facing researchers and companies seeking to develop a quantum computer. Continue reading here. 

The science of secrecy

Passwords, puzzles, encryptions, and keys—such have been the weapons used in battle between code makers and breakers for millennia. How do quantum physics and quantum computers change the world of cryptography? Read more here

Building the machines of the future

Read here how Weizmann alumni are leading the quantum revolution, qubit by qubit.

Weizmann researchers develop Israel’s first quantum computer

Building a working quantum computer is such a daunting venture that many believe it’s only for tech giants and superpowers, something on a scale beyond Israel’s reach. Prof. Roee Ozeri of the Department of Physics of Complex Systems, and the Weizmann Institute’s Vice President for Development and Communications, begs to differ: “One of the world’s first computers, WEIZAC, was built here in the 1950s. Today Israel is a technological empire; there’s no reason we shouldn’t be front-runners in the quantum computing race.” In a project reported in March in PRX Quantum, Prof. Ozeri’s team succeeded in building Israel’s first quantum computer—one of about 30 such machines in the world, and one of less than 10 to rely on an advanced technology known as ion traps. An even larger computer is now in the works and already has a name: In a tribute to WEIZAC, the scientists plan to call it WeizQC.

 

Read more here and here

New scientist: Dr. Osip Schwartz

Electron microscopes are indispensable in many branches of research. Using a beam of electrons to capture the image of an object, rather than a beam of light like their optical counterparts, these microscopes are able to reach atomic-scale resolutions, some 500,000 times smaller than what the human eye can see. But while the field of electron microscopy has advanced drastically in recent years, scientists still have to contend with many stubborn constraints that hinder their ability to image many biological specimens. Dr. Osip Schwartz, who is joining the Department of Physics of Complex Systems, is trying to solve these problems by using lasers to control the electron beams on a quantum level. Read more here.

New scientist: Dr. Ziv Meir

Working in the field of quantum technology requires the ability to use tiny spinning electrons to encode information—quantum bits, also known as qubits. Now, there may be a new way to do it: creating qubits based on the vibrations of whole molecules. Molecules offer an exciting and novel platform to study how quantum mechanics—the physics governing the atomic-scale world—applies to larger-than-atomic systems. Dr. Ziv Meir, who is joining the Department of Physics of Complex Systems, plans to use these novel molecular qubits to explore scientific avenues and to develop technologies not possible with ‘ordinary’ qubits. Read more here.

New scientist: Dr. Yuval Ronen

To overcome the need for quantum error correcting codes,  Dr. Yuval Ronen, who has joined the Department of Condensed Matter Physics, is investigating the emerging field of topological superconductivity. It is based on the idea that topology, a branch of mathematics now being applied to physics that focuses on special properties of the surface of objects, may offer new species of particles that could eliminate the need for quantum error correcting codes altogether, and produce a highly effective, stable, and secure quantum code. The topological quality of a qubit allows it to retain information regardless of what is happening in its environment, and, therefore be error-free. Read more here.

Spinning the Threads of Quantum Memory

A new study by Dr. Or Katz and Roy Shaham from Dr. Ofer Firstenberg’s group in the Physics of Complex System’s Department at the Weizmann Institute of Science, in collaboration with Rafael Advanced Defense Systems Ltd., offers an innovative way to store data in qubits for much longer periods of time than was previously possible.

Read more

New scientist: Dr. Rotem Arnon-Friedman

As soon as quantum computers become available, encryption needs to move up to the quantum level too. Dr. Rotem Arnon-Friedman believes that the theoretical and practical foundations for security must be developed even faster than the qubits and software needed to run quantum computers. Quantum computing holds tremendous promise for faster and more powerful computers that can quickly give answers to unsolvable problems, but there are many challenges to overcome. Read more here