Teleportation Is Indeed Possible At Least in the Quantum World – SciTechDaily

Quantum teleportation is an important step in improving quantum computing.

Beam me up is one of the most famous catchphrases from the Star Trek series. It is the command issued when a character wishes to teleport from a remote location back to the Starship Enterprise.

While human teleportation exists only in science fiction, teleportation is possible in the subatomic world of quantum mechanicsalbeit not in the way typically depicted on TV. In the quantum world, teleportation involves the transportation of information, rather than the transportation of matter.

Last year scientists confirmed that information could be passed between photons on computer chips even when the photons were not physically linked.

Now, according to new research from the University of Rochester and Purdue University, teleportation may also be possible between electrons.

A quantum processor semiconductor chip is connected to a circuit board in the lab of John Nichol, an assistant professor of physics at the University of Rochester. Nichol and Andrew Jordan, a professor of physics, are exploring new ways of creating quantum-mechanical interactions between distant electrons, promising major advances in quantum computing. Credit: University of Rochester photo / J. Adam Fenster

In a paper published in Nature Communications and one to appear in Physical Review X, the researchers, including John Nichol, an assistant professor of physics at Rochester, and Andrew Jordan, a professor of physics at Rochester, explore new ways of creating quantum-mechanical interactions between distant electrons. The research is an important step in improving quantum computing, which, in turn, has the potential to revolutionize technology, medicine, and science by providing faster and more efficient processors and sensors.

Quantum teleportation is a demonstration of what Albert Einstein famously called spooky action at a distancealso known as quantum entanglement. In entanglementone of the basic of concepts of quantum physicsthe properties of one particle affect the properties of another, even when the particles are separated by a large distance. Quantum teleportation involves two distant, entangled particles in which the state of a third particle instantly teleports its state to the two entangled particles.

Quantum teleportation is an important means for transmitting information in quantum computing. While a typical computer consists of billions of transistors, called bits, quantum computers encode information in quantum bits, or qubits. A bit has a single binary value, which can be either 0 or 1, but qubits can be both 0 and 1 at the same time. The ability for individual qubits to simultaneously occupy multiple states underlies the great potential power of quantum computers.

Scientists have recently demonstrated quantum teleportation by using electromagnetic photons to create remotely entangled pairs of qubits.

Qubits made from individual electrons, however, are also promising for transmitting information in semiconductors.

Individual electrons are promising qubits because they interact very easily with each other, and individual electron qubits in semiconductors are also scalable, Nichol says. Reliably creating long-distance interactions between electrons is essential for quantum computing.

Creating entangled pairs of electron qubits that span long distances, which is required for teleportation, has proved challenging, though: while photons naturally propagate over long distances, electrons usually are confined to one place.

In order to demonstrate quantum teleportation using electrons, the researchers harnessed a recently developed technique based on the principles of Heisenberg exchange coupling. An individual electron is like a bar magnet with a north pole and a south pole that can point either up or down. The direction of the polewhether the north pole is pointing up or down, for instanceis known as the electrons magnetic moment or quantum spin state. If certain kinds of particles have the same magnetic moment, they cannot be in the same place at the same time. That is, two electrons in the same quantum state cannot sit on top of each other. If they did, their states would swap back and forth in time.

The researchers used the technique to distribute entangled pairs of electrons and teleport their spin states.

We provide evidence for entanglement swapping, in which we create entanglement between two electrons even though the particles never interact, and quantum gate teleportation, a potentially useful technique for quantum computing using teleportation, Nichol says. Our work shows that this can be done even without photons.

The results pave the way for future research on quantum teleportation involving spin states of all matter, not just photons, and provide more evidence for the surprisingly useful capabilities of individual electrons in qubit semiconductors.


Conditional teleportation of quantum-dot spin states by Haifeng Qiao, Yadav P. Kandel, Sreenath K. Manikandan, Andrew N. Jordan, Saeed Fallahi, Geoffrey C. Gardner, Michael J. Manfra and John M. Nichol, 15 June 2020, Nature Communications.DOI: 10.1038/s41467-020-16745-0

Coherent multi-spin exchange in a quantum-dot spin chain by Haifeng Qiao, Yadav P. Kandel, Kuangyin Deng, Saeed Fallahi, Geoffrey C. Gardner, Michael J. Manfra, Edwin Barnes, John M. Nichol, Accepted 12 May 2020, Physical Review X.arXiv: 2001.02277

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Teleportation Is Indeed Possible At Least in the Quantum World - SciTechDaily

Better encryption for wireless privacy at the dawn of quantum computing – UC Riverside

For the widest possible and mobile Internet coverage, wireless communications are essential. But due to the open nature of wireless transmissions, information security is a unique issue of challenge. The widely deployed methods for information security are based on digital encryption, which in turn requires two or more legitimate parties to share a secret key.

The distribution of a secrecy key via zero-distance physical contact is inconvenient in general and impossible in situations where too little time is available. The conventional solution to this challenge is to use the public-key infrastructure, or PKI, for secret key distribution. Yet, PKI is based on computational hardness of factoring, for example, which is known to be increasingly threatened by quantum computing. Some predictions suggest that such a threat could become a reality within 15 years.

In order to provide Internet coverage for every possible spot on the planet, such as remote islands and mountains, a low-orbiting satellite communication network is rapidly being developed. A satellite can transmit or receive streams of digital information to or from terrestrial stations. But the geographical exposure of these streams is large and easily prone to eavesdropping. For applications such as satellite communications, how can we guarantee information security even if quantum computers become readily available in the near future?

Yingbo Huas Lab of Signals, Systems and Networks in the Department of Electrical and Computer Engineering, which has been supported in part by Army, has aimed to develop reliable and secure transmission, or RESET, schemes for future wireless networks. RESET guarantees that the secret information is not only received reliably by legitimate receiver but also secure from eavesdropper with any channel superiority.

In particular, Huas Lab has developed a physical layer encryption method that could be immune to the threat of quantum computing. They are actively engaged in further research of this and other related methods.

For the physical layer encryption proposed by Huas lab, only partial information is extracted from randomized matrices such as the principal singular vector of each matrix modulated by secret physical feature approximately shared by legitimate parties. The principal singular vector of a matrix is not a reversible function of the matrix. This seems to suggest that a quantum computer is unable to perform a task that is rather easy on a classical computer. If this is true, then the physical layer encryption should be immune from attacks via quantum computing. Unlike the number theory based encryption methods which are vulnerable to quantum attacks, Huas physical layer encryption is based on continuous encryption functions that are still yet to be developed.

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Better encryption for wireless privacy at the dawn of quantum computing - UC Riverside

Global Quantum Computing Market Expected to Reach Highest CAGR by 2025 Top Players: D-Wave Systems, Google, IBM, Intel, Microsoft, 1QB Information…

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Global Quantum Computing Market Expected to Reach Highest CAGR by 2025 Top Players: D-Wave Systems, Google, IBM, Intel, Microsoft, 1QB Information...

Quasiparticles Found to Have a Critical Role in Future Applications for Quantum Computing and Memory Storage – News – All About Circuits

Researchers at Rensselaer Polytechnic Institute (RPI)have announced their discovery ofintriguing new facts about a type of quasiparticle known as an exciton. The group's work serves to grasp the potential of transitional metal dichalcogenides (TMDCs). These atomically thin class of materials have attracted attention due to their electronic and optical properties.

The results of the work, published inNature Communications, focused on TMDCs, with an emphasis on the exciton, which is often produced through the energy of light and result when a negatively charged electron bonding with a hole particle carrying a positive charge.

The research team (headed by Rensselaer's Sufei Shi, an assistant professor of chemical and biological engineering), found that the interaction between electrons and holes within this atomically thin semiconductor material can be quite powerful. So much so that the electron and hole within the exciton can bond with a third particle, either an electron or a hole, to form a trion.

In the present study, Shi and his team succeeded in manipulating the TMDC material in a manner to cause the internal crystalline lattice to vibrate. This, in turn, served to create a phonon, which is another type of quasiparticle. The phonon was observed to interact strongly with a trion.

All solid crystals are built of atoms bound in repeatable three-dimensional lattices. The atoms themselves can be thought of as particles connected by springs. Phonons can be described as units of vibrational energy engendered by the atoms' oscillation within the crystalline structure.

The vibration generates mechanical waves that propagate through the material with specific momentum and energy. In terms of quantum mechanics, these waves can be treated as a particle, and that particle is our photon.

Just as a photon is a quantum of light or electromagnetic energy, the phonon is a quantum of mechanical, specifically vibrational energy.

The researchers placed the material within a powerful magnetic field. This allowed them to analyze the light emitted from the TMDCs from the phonon interaction, thus determining the effective mass of the electron and hole individually.

The result was surprising. The investigators have assumed that there would be symmetry in mass, but as described by Shi, the team found that the measurement was "significantly different."

As described by Professor Shi, knowledge of effective mass is a significant step forward. "We have developed a lot of knowledge about TMDCs now," Shi said. "But to design an electronic or optoelectronic device, it is essential to know the effective mass of the electrons and holes. This work is one solid step toward that goal."

There is today an acceleration of building things smaller, lighter, and ever more energy efficient. While Professor Shi's work at Rensselaer may not lead to off the shelf components in the near term, they point in a direction.

The direction is unmistakable.

We recently reported usingphotonicsto transfer information internally and between chips and howquantum-mechanical spinsare being used to convey information. Moore's Law may or may not have been overturned, but it may be losing its relevance. Its the heat generated by moving electrons that is rapidly becoming the limiting factor in electrical engineering, maybe even more so than the number of bits that can be held in a device of a given physical size.

For this reason, the various forms of quantum computing, not reliant on wandering electrons and their cost in power and heat, may well define our industry's future.

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Quasiparticles Found to Have a Critical Role in Future Applications for Quantum Computing and Memory Storage - News - All About Circuits

Physicists Just Quantum Teleported Information Between Particles of Matter – ScienceAlert

By making use of the 'spooky' laws behind quantum entanglement, physicists think have found a way to make information leap between a pair of electrons separated by distance.

Teleporting fundamental states between photonsmassless particles of light is quickly becoming old news, a trick we are still learning to exploit in computing and encrypted communications technology.

But what the latest research has achieved is quantum teleportation between particles of matter electrons something that could help connect quantum computing with the more traditional electronic kind.

"We provide evidence for 'entanglement swapping,' in which we create entanglement between two electrons even though the particles never interact, and 'quantum gate teleportation,' a potentially useful technique for quantum computing using teleportation," says physicist John Nichol from the University of Rochester in New York.

"Our work shows that this can be done even without photons."

Entanglement is physics jargon for what seems like a pretty straightforward concept.

If you buy a pair of shoes from a shop and leave one behind, you'll automatically know which foot it belongs to the moment you get home. The shoes are in a manner of speaking entangled.

If the shopkeeper randomly pulls out its matching partner when you return, you'll think they either remembered your sale, made a lucky guess, or were perhaps a little 'spooky' in their prediction.

The real weirdness arises when we imagine your lonely shoe as being both left and right at the same time, at least until you look at it. At that very moment, the shoe's partner back at the shop also snaps into shape, as if your sneaky peek teleported across that distance.

It's a kind of serendipitous exchange that Einstein felt was a little too spooky for comfort. Nearly a century after physicists raised the possibility, we now know teleportation between entangled particles is how the Universe works on a fundamental level.

While it's not exactly a Star Trek-type teleportation that could beam whole objects across space, the mathematics describing this information jump are mighty useful in carrying out special kinds of calculations in computing.

Typical computer logic is made up of a binary language of bits, labelled either 1s and 0s. Quantum computing is built with qubits that can occupy both states at once providing far greater possibilities that classical technology can't touch.

The problem is the Universe is like a big jumble of shoes, all threatening to turn your delicate game of 'guess which foot' into a nightmare gamble the moment any qubit interacts with its environment.

Manipulating photons to transmit their entangled states is made easier thanks to the fact they can be quickly separated at light speed over huge distances through a vacuum or down an optical fibre.

But separating entangled masses such as pairs of electrons is more of a challenge, given their clunky interactions as they bounce along are almost certain to ruin their mathematically pure quantum state.

It's a challenge well worth the effort, though.

"Individual electrons are promising qubits because they interact very easily with each other, and individual electron qubits in semiconductors are also scalable," saysNichol.

"Reliably creating long-distance interactions between electrons is essential for quantum computing."

To achieve it, the team of physicists and engineers took advantage of some strange fine print in the laws that govern the ways the fundamental particles making up atoms and molecules hold their place.

Any two electrons that share the same quantum spin state can't occupy the same spot in space. But there is a bit of a loophole that says nearby electrons can swap their spins, almost as if your feet could swap shoes if you bring them close enough.

The researchers had previously shownthat this exchange can be manipulated without needing to move the electrons at all, presenting a potential method for teleportation.

This latest advance helps bring the process closer to technological reality, overcoming hurdles that would connect quantum weirdness with existing computing technology.

"We provide evidence for 'entanglement swapping,' in which we create entanglement between two electrons even though the particles never interact, and 'quantum gate teleportation,' a potentially useful technique for quantum computing using teleportation," says Nichol.

"Our work shows that this can be done even without photons."

Of course, we're still some way off replacing photons with electrons for this kind of quantum information transfer. The researchers haven't gone as far as measuring the states of electrons themselves, meaning there could still be all kinds of interference to iron out.

But having strong evidence of the possibility of teleportation between electrons is an encouraging sign of the possibilities open to future engineers.

This research was published in Nature Communications.


Physicists Just Quantum Teleported Information Between Particles of Matter - ScienceAlert

Is IT regulation in the DARQ? – IT PRO

This article originally appeared in May's edition of IT Pro 20/20,available here. To sign up to receive each new issue in your inbox, click here.

While the world grapples with the fallout of the COVID-19 coronavirus pandemic and the shift to mass remote working also dubbed the distributed workplace other trends are bubbling under the surface. The growing use of artificial intelligence (AI) in businesses of all stripes is no secret, but there are another three technologies distributed ledger, extended reality, and quantum computing that are becoming increasingly influential as well.

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While SMAC Social, Mobile, Analytics, and Cloud has already changed the relationships service providers have with their customers over the course of recent years, DARQ, as these newer technologies are collectively known, looks set to become even more transformative.

With all these technologies, and AI in particular, becoming mainstream, do we need a new form of regulation to ensure DARQ technologies are used legally, fairly and ethically?

The digital change is not wafting like a gentle summer breeze over the beaches of Malta, says Felix Hufeld, president of the Federal Financial Supervisory Authority. Its sweeping over the industry like a storm and is shaking up business models, companies and even entire markets.

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Regulators have already seen the rapid growth of FinTech, with new companies innovating outside of traditional banking and financial services. This has raised concerns that their regulatory regimes wont be able to keep up with the pace of development.

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Here, some form of automation could deliver a regulatory environment fit for a world dominated by DARQ technologies. A late-2019 survey carried out by the Bank of England and Financial Conduct Authority found 57% of regulated services use AI for risk management and compliance.

Susannah Hammond, senior regulatory intelligence expert at Thomson Reuters, tells IT Pro: Traditionally, regulators [of financial services and data protection technologies] have sought to be technology-neutral when it comes to their rules and requirements, and have focused on the outcomes of the use of any technologies.

The emphasis is on senior managers understanding the new technologies, their limitations, any new risks which may arise (e.g. bias in machine learning, etc.) and the checks and balances to ensure that the technology is, in practice, working as intended. Equally, there is a focus on the resilience of IT infrastructures both in terms of ensuring good customer outcomes and cyber hygiene.

Go digital to meet todays critical compliance and security requirements

Digital transformation helps companies meet critical compliance and security requirements

DARQ offers businesses the tools they need to develop new personalised experiences for their customers. Each element of DARQ will independently usher in new opportunities and ways of working, but it's the convergence of these technologies that really drives innovation what Accenture called the reimagining of entire industries. Indeed, according to Accenture 89% of businesses are already experimenting with one or more DARQ technologies. For example, Volkswagen is using quantum computers to develop intelligent traffic guidance systems.

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Using AI as a component of service automation for instance, opens up questions of accuracy and accountability. At the moment, the focus is on financial services as they expand and accelerate their use of technologies such as machine learning and biometric identification to combat fraud. When other DARQ technologies are added to the mix, this heady cocktail of data becomes difficult to police. Here, RegTech (Regulation Technology) could offer a solution.

The RegTech industry is expanding. According to KPMG, RegTechs predicted share of all regulatory spending by 2022 will reach 34%, with the management consultancy defining RegTech 3.0 as a move from know your customer to know your data. This shift is critical to understand as all of the DARQ technologies are developing to create highly personalised services all of which will need a degree of regulation.

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The initial focus has been on how technologies such as AI are being applied to financial services and the businesses that supply them. RegTech, though, is expected to increase in importance as regulators realise they need new platforms to ensure DARQ technologies remain compliant.

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With regards to AI or quantum, regulations will be crucial for the wider adoption of these technologies as they will provide protection to consumers. This will allow the public to trust that they can safely rely upon these services, explains Benot Sauvage, director of regulatory strategy at Deloitte.

The main issue is that regulations do not yet fully comprehend these technologies. For instance, for AI, it is expected that regulations demand to explain the algorithms and show how results can be overridden or stopped. For quantum there might be a need to adapt cybersecurity rules and data protection rules, he adds.

Businesses and regulators alike are considering how automated systems could help them keep pace with the technological change that will only accelerate when DARQ is considered.

Removing human compliance officers from the decision-making processes is risky, as many of the DARQ technologies are often a black box. RegTech will evolve and become an essential tool. Compliance officers will have little choice than to use these systems if they are to understand the avalanche of regulation that DARQ will attract and how these regulations impact their businesses.

Businesses are striving to implement more automation and DARQ will help them achieve those goals. However, these technologies can seem opaque to the uninitiated and how machine language systems arrive at a conclusion must be explainable. Here, ensuring bias isnt present in the system is vital and must contain some form of oversight.

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However, as Franois-Kim Hug, a partner at Deloitte tells IT Pro, its important not to forget the importance of human input.

The advent of RegTech does not mean the end of the compliance officer, Hug explains. We are still far from a global compliance solution that can anticipate, understand, interpret and implement the ongoing avalanche of regulations impacting all businesses. This means the profile of compliance officers will need to adjust to this new digital reality where new solutions and new ways of working are created daily.

All of the DARQ technologies are on an accelerating upward trajectory, although not all of them will develop at the same pace. Already we see the first widespread applications of AI particularly machine learning whereas other components of the DARQ collective, such as quantum computing, are still in their infancy.

As such, regulators will move forward with defining the compliance regime DARQ must be used within as each component becomes more mainstream and begins to impact consumers.

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For businesses, while most recognise the massive impact SMAC has had, they may not be aware of DARQ or know that its impact could be even more disruptive. Once they wake up to this reality, their development roadmap should come into focus as soon as possible and they can start taking their first steps in using these technologies.

Regulators will, as always, be watching and RegTech could deliver a helpful dose of automated compliance. But that doesnt mean its time to say goodbye to your human compliance officers they will have a vital role to play as we start to more confidently explore the DARQ.

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Is IT regulation in the DARQ? - IT PRO

Quantum entanglement demonstrated on orbiting CubeSat – University of Strathclyde

25 June 2020

In a critical step toward creating a global quantum communications network, researchers have generated and detected quantum entanglement onboard a CubeSat nanosatellite weighing less than 2.6 kg and orbiting the Earth.

The University of Strathclyde is involved in an international team which has demonstrated that their miniaturised source of quantum entanglement can operate successfully in space aboard a low-resource, cost-effective CubeSat that is smaller than a shoebox. CubeSats are a standard type of nanosatellite made of multiples of 10 cm 10 cm 10 cm cubic units.

The quantum mechanical phenomenon known as entanglement is essential to many quantum communications applications. However, creating a global network for entanglement distribution is not possible with optical fibers because of the optical losses that occur over long distances. Equipping small, standardised satellites in space with quantum instrumentation is one way to tackle this challenge in a cost-effective manner.

The research, led by the National University of Singapore, has been published in the journal Optica.

Dr Daniel Oi, a Senior Lecturer in Strathclydes Department of Physics, is the Universitys lead on the research. He said: This research has tested next generation quantum communication technologies for use in space. With the results confirmed, its success bodes well for forthcoming missions, for which we are developing the next enhanced version of these instruments.

As a first step, the researchers needed to demonstrate that a miniaturised photon source for quantum entanglement could stay intact through the stresses of launch and operate successfully in the harsh environment of space within a satellite that can provide minimal power. To accomplish this, they exhaustively examined every component of the photon-pair source used to generate quantum entanglement to see if it could be made smaller or more rugged.

The new miniaturised photon-pair source consists of a blue laser diode that shines on nonlinear crystals to create pairs of photons. Achieving high-quality entanglement required a complete redesign of the mounts that align the nonlinear crystals with high precision and stability.

The researchers qualified their new instrument for space by testing its ability to withstand the vibration and thermal changes experienced during a rocket launch and in-space operation. The photon-pair source maintained very high-quality entanglement throughout the testing and crystal alignment was preserved, even after repeated temperature cycling from -10 C to 40 C.

The researchers incorporated their new instrument into SpooQy-1, a CubeSat that was deployed into orbit from the International Space Station on 17 June 2019. The instrument successfully generated entangled photon-pairs over temperatures from 16 C to 21.5 C.

The researchers are now working with RAL Space in the UK to design and build a quantum nanosatellite similar to SpooQy-1 with the capabilities needed to beam entangled photons from space to a ground receiver. This is slated for demonstration aboard a 2022 mission. They are also collaborating with other teams to improve the ability of CubeSats to support quantum networks.

Strathclyde is the only academic institution that has been a partner in all four EPSRC funded Quantum Technology Hubs in both phases of funding. The Hubs are in Sensing and Timing, Quantum Enhanced Imaging, Quantum Computing and Simulation and Quantum Communications Technologies. Dr Oi is Strathclydes lead on a forthcoming CubeSat mission being developed by the Quantum Communications Technologies Hub.

Dr Oi is also Chief Scientific Officer with Craft Prospect, a space engineering practice that delivers mission-enabling products and develops novel mission applications for small space missions. The company is based in the Tontine Building in the Glasgow City Innovation District, which is transforming the way academia, business and industry collaborate to bring competitive advantage to Scotland.

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Quantum entanglement demonstrated on orbiting CubeSat - University of Strathclyde

Docuseries takes viewers into the lives and labs of scientists – UChicago News

The camera crew was given full access to Earnest-Nobles research. In several scenes, Earnest-Noble is suited up in white PPE in the Pritzker Nanofabrication Facility in the Eckhardt Research Center. His scientific process and the breakthrough he seeks are depicted with animations and close-up footage of the state-of-the-art facilities. The filmmakers capture Earnest-Noble in the midst of a failed attempt or among his graveyard of failed quantum devices. As he embraces his doubts and is propelled by tenacity, viewers witness an emotional depiction of real science.

Earnest-Nobles lively interviews focus on the experience versus the result of his labors, providing a realistic portrayal of graduate studies and enabling viewers to follow him to his goal of identifying the ideal qubit for superpositiona phenomenon in quantum mechanics in which a particle can exist in several states at once.

When we were filming, I was trying to explain a qubit or something, and how much I was using jargon words was eye-opening to me. It helped me appreciate the challenge of making science understandable, said Earnest-Noble, who is now a quantum computing researcher at IBM. Science is a process far more than a series of facts. That became clear to me from working on this project.

Science communications typically takes a very long struggle of discovery and wraps it up into a pretty package, said Schuster. But something I found very special in this story is that you got to follow Nate for a couple of years. It accurately captured what Nates experience was like. And it focused on his experience, and not on the result, which is pretty amazing."

STAGEs director of science Sunanda Prabhu-Gaunkar originally joined the STAGE lab as a postdoc, and taught herself filmmaking in order to create the series. The scientific process inspires our filmmaking, she said. The workflow embraces failure, remains receptive to discoveries through iteration, and allows for risk-taking, all within a highly collaborative process.

Ellen Askey, the pilot episodes co-director, joined the project as a first-year student at UChicago with prior filmmaking experience. She worked on the series across her college career, graduating in June with a degree in cinema and media studies. Showing a story develop over time can be powerful, she said. We hope to get it out there to a lot of people who are and who are not yet interested in science.

Interested attendees can register through Eventbrite.

Adapted from an article by Maureen McMahon posted on the Physical Sciences Division website.

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Docuseries takes viewers into the lives and labs of scientists - UChicago News

Kudos: Read about faculty, staff and student awards, appointments and achievements – Vanderbilt University News


Kelsea Best, a Ph.D. student in Earth and Environmental Sciences, has been awarded a graduate student pursuit grant from the National Socio-Environmental Synthesis Center to study the human impacts of climate change. Best is leading a team of graduate students fromseveral universities across the U.S. to study connections between climate change and displacement of people in coastal areas of the United States, with financial support for travel, high-performance computational resources and stipends provided by SESYNC.

David Curie, a third-year physics Ph.D. student, has received anOffice of Science Graduate Student Research Fellowshipto conduct part of his dissertation research in a Department of Energy laboratory. Curies work focuses on single-photon sources, which can be used inquantum communicationsand possibly quantum computing.

E. Bronson Ingram College was named the Best Higher Education/Research project for 2019 by Engineering News-Record magazine.

Brandt Eichman, William R. Kenan, Jr. Chair in Biological Sciences and professor of biochemistry, will receive the 2021 International Award from the Biochemical Society, the United Kingdoms leading organization of biochemists. The award, whichrecognizes outstanding and independent research that demonstrates the importance of the molecular biosciences, is given annually to an early- to mid-career scientist who has conducted research outside the U.K. and Ireland.

Mary Jo Gilmer, professor of nursing, has been selected for induction into the International Nurse Researcher Hall of Fame by Sigma Theta Tau International Honor Society of Nursing. The honor, which recognizes significant, sustained international achievement, is considered one of the highest honors in nursing research.

Kathryn Humphreys, assistant professor of psychology and human development, has received a 2020 Janet Taylor Spence Award from the Association for Psychological Science. The award recognizes early-career researchers who have made transformative contributions to the field of psychological science, such as establishing new paradigms within a subject area or advancing research that cuts across fields of study.

Karan Jani, a postdoctoral scholar in the Department of Physics and Astronomy, has been recognized as an All-Star Alumnus by Forbes for his research on black holes. Jani was named to Forbes30 Under 30Science list in 2017.

Jonathan Metzl, Frederick B. Rentschler II Professor of Sociology and Medicine, Health and Society, has received the 2020 Benjamin Rush Award from the American Psychiatric Association. The award recognizes an individual who has made significant contributions to the literature on the history of psychiatry.

Dawool (Lauren) Nam, a senior majoring in chemistry, has received the 2019-20 Girls in STEM Scholarship Award from Girls Who STEM, the mission of which is to increase access and participation of girls in STEM fields and to promote and support girls and women in STEM projects, areas of study and professions.

Roberta Nelson, assistant director of the Office of LGBTQI Life, has received the Promising New Professional Award from the Consortium of LGBT Resource Professionals. The award recognizes a professional with less than five years of experience for outstanding service, innovative or creative effort within the profession, and demonstration of significant promise for leadership in the field.

Laura Nichols, a first-year physics Ph.D. student, has received a Computational Science Graduate Fellowship in overall support of her dissertation research in computational physics. TheCSGF fellowship, awarded to only about 30 individuals nationally per year, supports Ph.D. candidates in the computational sciencesthose who use computer programming to solve problems in scientific disciplines such as physics, biology and chemistry.

Sokrates Pantelides, William A. and Nancy F. McMinn Professor of Physics and professor of electrical engineering, was one of three international scientists honored with the 2019 Award for International Scientific Cooperation by the Chinese Academy of Sciences. A pioneer in the field of semiconductor physics, Pantelides has carried out substantive cooperation with the CAS in developing new low-dimensional materials over the past two decades. In addition, Pantelides was named an honorary professor by Galgotias University in Greater Noida, Uttar Pradesh, India, in conjunction with a talk he gave at an Institute of Electrical and Electronics Engineers conference in nearby Lucknow.

Cleo Rucker, director of human resources consulting, employee and labor relations, has been appointed to the Metro Nashville Employee Benefits Study and Formulating Committee by Mayor John Cooper. The committees charge is to study and formulate a plan for employee benefits, including disability and retirement benefits, for Metro Nashville employees.

Keivan Stassun, Stevenson Chair in Physics and professor of astronomy and computer science, has been named an inaugural fellow of the American Astronomical Society, the major organization of professional astronomers in North America. The designation recognizes AAS members for extraordinary achievement and service, such as original research and publication, innovative contributions to astronomical techniques or instrumentation, significant contributions to education and public outreach, and noteworthy service to astronomy and to the society itself.

Steven Townsend, assistant professor of chemistry, has been named a Camille Dreyfus Teacher-Scholar for 2020. These faculty are within the first five years of their academic careers, have created an outstanding independent body of scholarship, and are deeply committed to education.

Kip Viscusi, University Distinguished Professor of Law, Economics and Management, has received the American Risk and Insurance Associations 2020 Kulp-Wright Book Award for Pricing Lives: Guideposts for a Safer Society. The award recognizes a risk management and insurance book or monograph that advances the body of knowledge toward new frontiers.

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Kudos: Read about faculty, staff and student awards, appointments and achievements - Vanderbilt University News

The Role of Quantum Computing in Online Education – MarketScale

On this episode of the MarketScale Online Learning Minute, host Brian Runo dives into how quantum computing, the next revolutionary leap forward in computing, could apply to online education.

In particular, it can be used to epitomize the connectivism theory and provide personalized learning for each individual, as its not restricted by the capacity of an individual instructor.

In this way, each learner can be empowered to learn at their own pace and be presented with materials more tailored to them in real-time.

In fact, quantum computing is so revolutionary that the education world likely cant even currently dream up the innovations it will enable.

For the latest news, videos, and podcasts in theEducation Technology Industry, be sure to subscribe to our industry publication.

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The University of New Mexico Becomes IBM Q Hub’s First University Member – Quantaneo, the Quantum Computing Source

The NC State IBM Q Hub is a cloud-based quantum computing hub, one of six worldwide and the first in North America to be part of the global IBM Q Network. This global network links national laboratories, tech startups, Fortune 500 companies, and research universities, providing access to IBMs largest quantum computing systems.

Mainstream computer processors inside our laptops, desktops, and smartphones manipulate bits, information that can only exist as either a 1 or a 0. In other words, the computers we are used to function through programming, which dictates a series of commands with choices restricted to yes/no or if this, then that. Quantum computers, on the other hand, process quantum bits or qubits, that are not restricted to a binary choice. Quantum computers can choose if this, then that or both through complex physics concepts such as quantum entanglement. This allows quantum computers to process information more quickly, and in unique ways compared to conventional computers.

Access to systems such as IBMs newly announced 53 qubit processor (as well as several 20 qubit machines) is just one of the many benefits to UNMs participation in the IBM Q Hub when it comes to data analysis and algorithm development for quantum hardware. Quantum knowledge will only grow with time, and the IBM Q Hub will provide unique training and research opportunities for UNM faculty and student researchers for years to come.

How did this partnership come to be? Two years ago, a sort of call to arms was sent out among UNM quantum experts, saying now was the time for big ideas because federal support for quantum research was gaining traction. Devetsikiotis vision was to create a quantum ecosystem, one that could unite the foundational quantum research in physics at UNMs Center for Quantum Information and Control (CQuIC) with new quantum computing and engineering initiatives for solving big real-world mathematical problems.

At first, I thought [quantum] was something for physicists, explains Devetsikiotis. But I realized its a great opportunity for the ECE department to develop real engineering solutions to these real-world problems.

CQuIC is the foundation of UNMs long-standing involvement in quantum research, resulting in participation in the National Quantum Initiative (NQI) passed by Congress in 2018 to support multidisciplinary research and training in quantum information science. UNM has been a pioneer in quantum information science since the field emerged 25 years ago, as CQuIC Director Ivan Deutsch knows first-hand.

This is a very vibrant time in our field, moving from physics to broader activities, says Deutsch, and [Devetsikiotis] has seen this as a real growth area, connecting engineering with the existing strengths we have in the CQuIC.

With strategic support from the Office of the Vice President for Research, Devetsikiotis secured National Science Foundation funding to support a Quantum Computing & Information Science (QCIS) faculty fellow. The faculty member will join the Department of Electrical and Computer Engineering with the goal to unite well-established quantum research in physics with new quantum education and research initiatives in engineering. This includes membership in CQuIC and implementation of the IBM Q Hub program, as well as a partnership with Los Alamos National Lab for a Quantum Computing Summer School to develop new curricula, educational materials, and mentorship of next-generation quantum computing and information scientists.As part of the Q Hub at NC State, UNM gains access to IBMs largest quantum computing systems for commercial use cases and fundamental research. It also allows for the restructuring of existing quantum courses to be more hands-on and interdisciplinary than they have in the past, as well as the creation of new courses, a new masters degree program in QCIS, and a new university-wide Ph.D. concentration in QCIS that can be added to several departments including ECE, Computer Science, Physics and Astronomy, and Chemistry.

Theres been a lot of challenges, Devetsikiotis says, but there has also been a lot of good timing, and thankfully The University has provided support for us. UNM has solidified our seat at the quantum table and can now bring in the industrial side.

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The University of New Mexico Becomes IBM Q Hub's First University Member - Quantaneo, the Quantum Computing Source

Riverlane partner with bio-tech company Astex – Quantaneo, the Quantum Computing Source

Riverlane builds ground-breaking software to unleash the power of quantum computers. Chemistry is a key application in which quantum computing can be of significant value, as high-level quantum chemistry calculations can be solved far faster than using classical methods.

World leaders in drug discovery and development, Astex Pharmaceuticals apply innovative solutions to treat cancer and diseases of the central nervous system.The two companies will join forces to combine their expertise in quantum computing software and quantum chemistry applications to speed up drug development and move us closer to quantum advantage.

As part of the collaboration, Astex are funding a post-doctoral research scientist at Riverlane. They will apply very high levels of quantum theory to study the properties of covalent drugs, in which protein function is blocked by the formation of a specific chemical bond.So far in this field of research, only empirical methods and relatively low levels of quantum theory have been applied. Riverlane will provide access to specialised quantum software to enable simulations of the target drug-protein complexes.

Dave Plant, Principal Research Scientist at Riverlane, said: This collaboration will produce newly enhanced quantum chemical calculations to drive efficiencies in the drug discovery process. It will hopefully lead to the next generation of quantum inspired pharmaceutical products.

Chris Murray, SVP of Discovery Technology at Astex said: "We are excited about the prospect of exploring quantum computing in drug discovery applications. It offers the opportunity to deliver much more accurate calculations of the energetics associated with the interaction of drugs with biological molecules, leading to potential improvements in drug discovery productivity."

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Riverlane partner with bio-tech company Astex - Quantaneo, the Quantum Computing Source

The impact of spycraft on how we secure our data – ComputerWeekly.com

The cyber security industry has come a long way since its inception. The ancestors of cyber were the men and women working at Bletchley Park during the Second World War, long before the introduction of what we would consider modern cyber security practices but even before then, humans used codes and ciphers to keep information safe for millennia. Even Julius Caesar popularised a cipher which was named after him.

More recently, developments have been driven by the intelligence and defence sectors, which have a real need to uncover as well as keep sensitive intelligence safe. Some of these innovations were showcased recently at the Science Museums Top Secret exhibition, which ran from July 2019 to February 2020 to coincide with the 100th anniversary of GCHQ, the UKs intelligence, security and cyber agency.

It also gives us the context as to where developments have originated, and the ways in which they will subsequently impact how businesses keep their data safe from cyber criminals in the future.

The threats organisations face today are varied from organised crime groups to nation-state hackers, as well as individual hackers. One of the ways organisations try to defend themselves is through encryption.

Ciphers have been around for centuries in one form or another from non-standard hieroglyphs in the walls of tombs built in ancient Egypt almost 4,000 years ago, to substitution ciphers developed 1,200 years ago by Arab mathematician Al-Kindi. The rise of electronic communications during the Cold War led to monumental developments in ciphers and encryption technology, which were used to keep phone conversations secure.

Today, the focus for many organisations and businesses is the use of encryption on mobile devices, enterprise networks and cloud services. Given the impact of mobile devices and digital communication on how organisations conduct their business with partners and customers globally, this has been a key development ensuring conversations remain private while enabling fast and secure communication.

Today, encryption is used in all sectors for medical data in healthcare, customer information in banking, and much more. This highlights the importance of all areas of industry, outside of tech and IT, learning from the intelligence communitys experience developing advanced solutions to secure communications and data.

Many technologies initially developed by the intelligence community have become commonplace in keeping our everyday communications secure, according to Elizabeth Bruton, curator of the Science Museums Top Secret exhibition.

Randomness has always been used to disguise messages, she said. Though the technology today is radically different, the basic principles of encryption using long strings of random characters letters and numbers have changed very little over the past 100 years. The Top Secret exhibition features letter tiles used by the Government Code and Cypher School staff at Mansfield College, Oxford, during the Second World War.

GC&CS staff pulled these tiles out of a bag to create long strings of random numbers or letters, she said. They were used to make encryption keys and one-time pads to keep British wartime messages secure. Today, randomness underpins some of the encryption systems we use to keep our communications secure.

Also featured in the Top Secret exhibition is a chaotic pendulum used by the internet security company Cloudflare to help keep online messages secret. Cloudflare uses readings from devices such as this pendulum and a wall of lava lamps to make long strings of random numbers, said Bruton. These random numbers help create keys that encrypt the traffic that flows through Cloudflares network.

Although its interesting to see how todays cyber security solutions have been influenced by the past, emerging technologies can also help us gaze into the future. One of the exhibits in the Top Secret exhibition consists of parts from a quantum computer. This new computing paradigm has the potential to rewrite how we use technology.

Quantum computers could significantly weaken our cyber defences by processing information in a manner completely different to that of traditional computers. Work is already underway to develop quantum-resistant encryption that is likely to become a common business practice in the next decade.

Breakthroughs such as quantum computing are a reminder that organisations should constantly be thinking about how the threats they face evolve. After all, cyber crime is set to cost businesses over $2tn this year alone. Todays new tech could be tomorrows threat, and bad actors such as organised cybercriminals and nation-state attackers will always look to exploit the latest and greatest tech.

Cyber criminals are often quick to use new technologies. Since they dont operate in regulated industries or need to consider customers and users, they can be more efficient at harnessing these technologies for harm than organisations are at harnessing them for good.

The cyber security sector is experiencing tremendous growth, driven by our dependence on technology. Global cyber security spending is expected to reach $248bn by 2026.

As such, its prudent for all organisations to look at both the past and the future if they want to remain safe from cyber criminals and invest wisely. The crossover between what technologies the intelligence sector has developed and how these have been adopted into mainstream cyber security solutions highlights the many years of research it takes to keep data safe.

As organisations face ever more threats, they should look to learn as much as they can from every sector and be open to sharing best practices to ensure robust defences.

Subject to the anticipated reopening of the UKs museums as Covid-19 pandemic restrictions ease, the Top Secret exhibition is scheduled to open at Manchesters Science and Industry Museum in October 2020.

Mark Hughes is senior vice-president of security at DXC Technology

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The impact of spycraft on how we secure our data - ComputerWeekly.com

Bipartisan push for US$100 billion investment in science – University World News


The Endless Frontier Act was introduced by Senate Minority Leader Chuck Schumer (Democrat, New York), Senator Todd Young (Republican, Indiana), Representative Ro Khanna (Democrat, California) and Representative Mike Gallagher (Republican, Wisconsin).

The preamble to the act warns that although the United States has been the unequivocal global leader in scientific and technological innovation since the end of World War II, and as a result the American people have benefited through good-paying jobs, economic prosperity and a higher quality of life, today this leadership position is being eroded.

Far too many of our communities have tremendous innovation potential but lack the critical public investment to build the nations strength in new technologies, while our foreign competitors, some of whom are stealing American intellectual property, are aggressively investing in fundamental research and commercialisation to dominate the key technology fields of the future.

It says: Without a significant increase in investment in fundamental scientific research, education and training, technology transfer and entrepreneurship, and the broader US innovation ecosystem across the nation, it is only a matter of time before Americas global competitors catch-up and overtake the US in terms of technological primacy: whichever country wins the race in key technologies such as artificial intelligence, quantum computing, advanced communications, and advanced manufacturing will be the superpower of the future.

The bill argues that the US government needs to catalyse US innovation by boosting investments in the discovery, creation and commercialisation of new technologies that ensure American leadership in the industries of the future.

The bill would rename the National Science Foundation (NSF) the National Science and Technology Foundation (NSTF) and task a new deputy director with executing the new funding of fundamental research related to specific recognised global technology challenges with geostrategic implications for the United States and create within it a Technology Directorate.

The authorisation for the new directorate would be US$100 billion over five years to reinvigorate American leadership in the discovery and application of key technologies that will define global competitiveness.

Connecting disadvantaged populations

An additional US$10 billion would be authorised over five years for the Department of Commerce to designate at least 10 regional technology hubs, awarding funds for comprehensive investment initiatives that position regions across the country to be global centres for the research, development and manufacturing of key technologies.

There would be a drive to connect disadvantaged populations and places to new job and business opportunities developing key technologies.

Peter McPherson, president of the Association of Public and Land-grant Universities which comprises 239 public research universities, land-grant institutions, state university systems, and affiliated organisations said: Public research universities applaud Senators Schumer and Young and Representatives Khanna and Gallagher for their work across the aisle to bolster US discovery and innovation.

The Endless Frontier Act, whose name is taken from a 1945 report that issued a clarion call for what would become the National Science Foundation, serves as a key step in driving US global scientific leadership in the 21st century.

Now more than ever, we need a national commitment to science and research on a grand level. Research and innovation can create new sectors of the global economy, drive economic recovery from the COVID-19 pandemic, and ultimately deliver long-term economic growth.

The Science Coalition, which represents more than 50 leading public and private research universities, issued a statement saying: In recent years, America has fallen behind its global counterparts in overall support and funding for fundamental scientific research, and this imbalance jeopardises our global economic competitiveness and our national security.

These lawmakers are right to prioritise funding for NSF and a new generation of cutting-edge research and technology. We commend their commitment to our researchers and STEM workforce pipeline that would chart a new course for American science and innovation.

According to the bill, the new directorate would fund research in the following areas:

Artificial intelligence and machine learning; High performance computing, semiconductors and advanced computer hardware; Quantum computing and information systems; Robotics, automation and advanced manufacturing; Natural or anthropogenic disaster prevention; Advanced communications technology; biotechnology, genomics and synthetic biology; Advanced energy technology; Cybersecurity, data storage and data management technologies; and Materials science, engineering and exploration relevant to the other focus areas.

The authorised activities would include:

Increases in research spending at universities, which can form consortia that include private industry, to advance US progress in key technology areas, including the creation of focused research centres.

New undergraduate scholarships, industry training programmes, graduate fellowships and traineeships and post-doctoral support in the targeted research areas to develop the US workforce.

The development of test-bed and fabrication facilities.

Programmes to facilitate and accelerate the transfer of new technologies from the lab to the marketplace, including expanding access to investment capital.

Planning and coordination with state and local economic development stakeholders and the private sector to build regional innovation ecosystems.

Increases in research spending for collaboration with US allies, partners and international organisations.

McPherson said the bill was needed to enable the US to compete with global rivals.

Federal investment in R&D has languished in recent decades. As a share of the economy, its a third of what it was at its peak. China, and other countries, meanwhile, have vastly expanded their investments in research and development, he said.

The current pandemic has underscored the critical need to redouble public investment in research and development. We must ensure more of these innovations and advancements take place in the US rather than elsewhere around the globe, he added.

This bill would not only advance US innovation, but also would help ensure the fruits of innovation are broadly shared. Investing in research across the country and in critical sectors such as quantum computing, biotechnology and robotics will help secure our place as home to the worlds most dynamic and advanced economy, McPherson said.

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Bipartisan push for US$100 billion investment in science - University World News

IIT Mumbai alumnus Rajiv Joshi, an IBM scientist, bags inventor of the year award – Livemint

Indian-American inventor Rajiv Joshi has bagged the prestigious Inventor of the Year award in recognition of his pioneering work in advancing the electronic industry and improving artificial intelligence capabilities.

Dr Joshi has more than 250 patented inventions in the US and works at the IBM Thomson Watson Research Center in New York.

He was presented with the prestigious annual award by the New York Intellectual Property Law Association early this month during a virtual awards ceremony.

An IIT Mumbai alumnus, Joshi has an MS degree from the Massachusetts Institute of Technology (MIT) and a PhD in mechanical/electrical engineering from Columbia University, New York.

His inventions span from novel interconnect structures and processes for more scaling, machine learning techniques for predictive failure analytics, high bandwidth, high performance and low power integrated circuits and memories and their usage in hardware accelerators, meant for artificial intelligence applications.

Many of these structures exist in processors, supercomputers, laptops, smartphones, handheld and variable gadgets and many other electronic items. His innovations have helped advance day-to-day life, global communication, health sciences and medical fields.

Necessity and curiosity inspire me," Dr Joshi told PTI in a recent interview, adding that the identification of a problem and providing out of the box solution as well as observe and think help him immensely to generate ideas.

Joshi claimed that stories about great, renowned inventors like Guglielmo Marconi, Madame Curie, Wright Brothers, James Watt, Alexander Bell, Thomas Edison inspired him.

In his acceptance speech, Dr Joshi said that cloud, artificial intelligence and quantum computing not only remain the buzzwords, but their utility, widespread usage is advancing with leaps and bounds.

All these areas are very exciting and I have been dabbling further in Artificial Intelligence (AI) and quantum computing," he said.

Quantum computing, which has offered tremendous opportunities, also faces challenges, he noted, adding that he is involved in advancing technology, improving memory structures and solutions and their usage in AI and contributing to quantum computing to advance the science. (With Agency Inputs)

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IIT Mumbai alumnus Rajiv Joshi, an IBM scientist, bags inventor of the year award - Livemint

Is the ‘endless frontier’ at an end? | TheHill – The Hill

The COVID-19 pandemic is intensifying U.S. concerns about Chinas technological strength. Unfortunately, much of the resulting policy debate has centered on ways to limit Chinas capacities when what we need most is a systematic approach to strengthening our own. In any race, success comes from training harder and running faster not from hoping that your challenger will trip. To guarantee our nations future economic health and national security, we need a comprehensive, forward-looking national strategy to keep the U.S. at the forefront of science and technology.

Fortunately, a bipartisan bill has emerged that offers the blueprint the moment demands. Introduced by Sens. Chuck SchumerCharles (Chuck) Ellis SchumerJudd Gregg: Biden a path to the presidency, or not Montana barrels toward blockbuster Senate fight Federal judges should be allowed to be Federalist Society members MORE (D-N.Y.) and Todd YoungTodd Christopher YoungHillicon Valley: House FISA bill in jeopardy | Democrats drop controversial surveillance measure | GOP working on legislation to strip Twitter of federal liability protections GOP senators urge Trump not to restrict guest worker visas Lawmakers introduce bill to invest 0 billion in science, tech research MORE (R-Ind.) and Reps. Ro KhannaRohit (Ro) KhannaHillicon Valley: Twitter flags Trump tweet for 'glorifying violence' | Cruz calls for criminal investigation into Twitter over alleged sanctions violations | Senators urge FTC to investigate TikTok child privacy issues Khanna calls for internet 'fairness doctrine' in response to controversial Trump tweets Khanna: Coronavirus has 'accelerated' the need for rural broadband MORE (D-Calif.) and Mike GallagherMichael (Mike) John GallagherRep. Banks launches bid for RSC chairman Hillicon Valley: House FISA bill in jeopardy | Democrats drop controversial surveillance measure | GOP working on legislation to strip Twitter of federal liability protections Lawmakers introduce bill to invest 0 billion in science, tech research MORE (R-Wis.), the Endless Frontier Act would provide a visible, focused and sustained commitment to U.S. research, education and technology transfer, as well as to economic development precisely the combination of remedies that will secure the nations future.

The bill recognizes that since World War II, federal research funding has been a central contributor to U.S. economic dominance. Its no accident that sectors like aircraft and information technology that have benefited most from decades of federal research support have been the leading U.S. exporters and emblems of U.S. leadership. The legislation would authorize $100 billion in new funding over five years for research and related activities.

But the bill also reflects the fact that, to counter Chinas very different model for economic growth, we not only need to invest more in science and technology now, we also need to invest differently than in the past. We simply must move more effectively from scientific success to market impact. With that in mind, the bill would establish a new technology directorate at the National Science Foundation that would fund fundamental research with an eye toward advancing 10 pivotal technologies, including artificial intelligence and quantum computing. To complement this research, the bill also calls for supporting more students pursuing undergraduate and advanced studies in relevant fields and for developing new ways to move ideas more effectively from lab to market, including by creating test beds for new developments.

The aim of the new directorate is to support fundamental scientific research with specific goals in mind. This is not about solving incremental technical problems. As one example, in artificial intelligence, the focus would not be on further refining current algorithms, but rather on developing profoundly new approaches that would enable machines to learn using much smaller data sets a fundamental advance that would eliminate the need to access immense data sets, an area where China holds an immense advantage. Success in this work would have a double benefit: seeding economic benefits for the U.S. while reducing the pressure to weaken privacy and civil liberties in pursuit of more training data.

Supporting fundamental research with an eye to real-world challenges is the kind of thinking that drove the Defense Advanced Research Projects Agency (DARPA) to develop what became the internet. Such use-inspired basic research, funded by NSF a trusted and experienced civilian agency that understands research and researchers is whats needed to retain U.S. leadership in both science and technology, to keep us prosperous and secure.

The bill would also encourage universities to experiment with new ways to help accelerate the process of bringing innovative ideas to the marketplace, either via established companies or startups. At MIT we started The Engine, an independent entity that provides private-sector funding, work space and technical assistance to start-ups that are developing technologies with enormous potential but that require more extensive technical development than typical VCs will fund, from fusion energy to a fast, inexpensive test for COVID-19. Other models may suit other institutions but the nation needs to encourage many more such efforts, across the country, to reap the full benefits of our federal investment in science.

Some may worry that this new approach could impair NSFs vital mission, but I believe it is a natural complement, in keeping with the agencys impressive record of adapting to the nations needs. The U.S. has the top universities in the world because we have combined the best strategies of the past with the flexibility to respond to new challenges; this legislation is designed to protect and maintain support for curiosity-driven basic research across scientific fields the mainstay of NSFs work that serves the nation so well even as it furthers NSFs mission and gives it additional tools.

Nations, like individuals, do not succeed by sitting still and hoping that others will fail. Success comes to those that build on their own strengths, learning from what has worked in the past but not being constrained by it.

This year marks the 75th anniversary of the report that launched the postwar U.S. research enterprise, Science: The Endless Frontier. That enterprise has helped give Americans decades of unparalleled prosperity, a rising quality of life and military confidence. The Endless Frontier Act would enable us to capitalize on what has worked and retool it for todays world, with its new challenges and challengers.

Dr. L. Rafael Reif is president of MIT.

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Is the 'endless frontier' at an end? | TheHill - The Hill

What’s New in HPC Research: Astronomy, Weather, Security & More – HPCwire

In this bimonthly feature,HPCwirehighlights newly published research in the high-performance computing community and related domains. From parallel programming to exascale to quantum computing, the details are here.

Developing the HPC system for the ASKAP telescope

The Australian Square Kilometre Array Pathfinder (ASKAP) telescope (itself a pilot project for the record-setting Square Kilometre Array planned for construction in the coming years) will enable highly sensitive radio astronomy that produces a tremendous amount of data. In this paper, researchers from the Commonwealth Scientific and Industrial Research Organisation (CSIRO) highlight how they are preparing a dedicated HPC platform, called ASKAPsoft, to handle the expected 5 PB/year of data produced by ASKAP.

Authors: Juan C. Guzman, Eric Bastholm, Wasim raja, Matthew Whiting, Daniel Mitchell, Stephen Ord and Max Voronkov.

Creating an open infrastructure for sharing and reusing HPC knowledge

In an expert field like HPC, institutional memory and information-sharing is crucial for maintaining and building on expertise but institutions often lack cohesive infrastructures to perpetuate that knowledge. These authors, a team from North Carolina State University and Lawrence Livermore National Laboratory, introduce OpenK, an open, ontology-based infrastructure aimed at facilitating the accumulation, sharing and reuse of HPC knowledge.

Authors: Yue Zhao, Xipeng Shen and Chunhua Liao.

Using high-performance data analysis to facilitate HPC-powered astrophysics

High-performance data analysis (HPDA) is an emerging tool for scientific disciplines like bioscience, climate science and security and now, its being used to prepare astrophysics research for exascale. In this paper, written by a team from the Astronomical Observatory of Trieste, Italy, the authors discuss the ExaNeSt and EuroExa projects, which built a prototype of a low-power exascale facility for HPDA and astrophysics.

Authors: Giuliano Taffoni, David Goz, Luca Tornatore, Marco Frailis, Gianmarco Maggio and Fabio Pasian.

Using power analysis to identify HPC activity

Monitoring users on large computing platforms such as [HPC] and cloud computing systems, these authors a duo from Lawrence Berkeley National Laboratory write, is non-trivial. Users can (and have) abused access to HPC systems, they say, but process viewers and other monitoring tools can impose substantial overhead. To that end, they introduce a technique for identifying running programs with 97% accuracy using just the systems power consumption.

Authors: Bogdan Copos and Sein Peisert.

Building resilience and fault tolerance in HPC for numerical weather and climate prediction

In numerical weather and climate prediction (NWP), accuracy depends strongly on available computing power but the increasing number of cores in top systems is leading to a higher frequency of hardware and software failures for NWP simulations. This report (from researchers at eight different institutions) examines approaches for fault tolerance in numerical algorithms and system resilience in parallel simulations for those NWP tools.

Authors: Tommaso Benacchio, Luca Bonaventura, Mirco Altenbernd, Chris D. Cantwell, Peter D. Dben, Mike Gillard, Luc Giraud, Dominik Gddeke, Erwan Raffin, Keita Teranishi and Nils Wedi.

Pioneering the exascale era with astronomy

Another team this time, from SURF, a collaborative organization for Dutch research also investigated the intersection of astronomy and the exascale era. This paper, written by three researchers from SURF, highlights a new, OpenStack-based cloud infrastructure layer and Spider, a new addition to SURFs high-throughput data processing platform. The authors explore how these additions help to prepare the astronomical research community for the exascale era, in particular with regard to data-intensive experiments like the Square Kilometre Array.

Authors: J. B. R. Oonk, C. Schrijvers and Y. van den Berg.

Enabling EASEY deployment of containerized applications for future HPC systems

As the exascale era approaches, HPC systems are growing in complexity, improving performance but making the systems less accessible for new users. These authors a duo from the Ludwig Maximilian University of Munich propose a support framework for these future HPC architectures called EASEY (for Enable exAScale for EverYone) that can automatically deploy optimized container computations with negligible overhead[.]

Authors: Maximilian Hb and Dieter Kranzlmller.

Do you know about research that should be included in next months list? If so, send us an email at[emailprotected]. We look forward to hearing from you.

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What's New in HPC Research: Astronomy, Weather, Security & More - HPCwire

Quantum computing analytics: Put this on your IT roadmap – TechRepublic

Quantum is the next step toward the future of analytics and computing. Is your organization ready for it?

Quantum computing can solve challenges that modern computers can't--or it might take them a billion years to do so. It can crack any encryption and make your data completely safe. Google reports that it has seen a quantum computer that performed at least 100 million times faster than any classical computer in its lab.

Quantum blows away the processing of data and algorithms on conventional computers because of its ability to operate on electrical circuits that can be in more than one state at once. A quantum computer operates on Qubits (quantum bits) instead of on the standard bits that are used in conventional computing.

SEE: Managing AI and ML in the enterprise 2020: Tech leaders increase project development and implementation (TechRepublic Premium)

Quantum results can quickly make an impact on life science and pharmaceutical companies, for financial institutions evaluating portfolio risks, and for other organizations that want to expedite time-to-results for processing that on conventional computing platforms would take days to complete.

Few corporate CEOs are comfortable trying to explain to their boards what quantum computing is and why it is important to invest in it.

"There are three major areas where we see immediate corporate engagement with quantum computing," said Christopher Savoie, CEO and co-founder of Zapata Quantum Computing Software Company, a quantum computing solutions provider backed by Honeywell. "These areas are machine learning, optimization problems, and molecular simulation."

Savoie said quantum computing can bring better results in machine learning than conventional computing because of its speed. This rapid processing of data enables a machine learning application to consume large amounts of multi-dimensional data that can generate more sophisticated models of a particular problem or phenomenon under study.

SEE: Forget quantum supremacy: This quantum-computing milestone could be just as important (TechRepublic)

Quantum computing is also well suited for solving problems in optimization. "The mathematics of optimization in supply and distribution chains is highly complex," Savoie said. "You can optimize five nodes of a supply chain with conventional computing, but what about 15 nodes with over 85 million different routes? Add to this the optimization of work processes and people, and you have a very complex problem that can be overwhelming for a conventional computing approach."

A third application area is molecular simulation in chemistry and pharmaceuticals, which can be quite complex.

In each of these cases, models of circumstances, events, and problems can be rapidly developed and evaluated from a variety of dimensions that collate data from many diverse sources into a model.

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"The current COVID-19 crisis is a prime example," Savoie said. "Bill Gates knew in 2015 that handling such a pandemic would present enormous challengesbut until recently, we didn't have the models to understand the complexities of those challenges."

For those engaging in quantum computing and analytics today, the relative newness of the technology presents its own share of glitches. This makes it important to have quantum computing experts on board. For this reason, most early adopter companies elect to go to the cloud for their quantum computing, partnering with a vendor that has the specialized expertise needed to run and maintain quantum analytics.

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"These companies typically use a Kubernetes cluster and management stack on premises," Savoie said. "They code a quantum circuit that contains information on how operations are to be performed on quantum qubits. From there, the circuit and the prepared data are sent to the cloud, which performs the quantum operations on the data. The data is processed in the cloud and sent back to the on-prem stack, and the process repeats itself until processing is complete."

Savoie estimated that broad adoption of quantum computing for analytics will occur within a three- to five-year timeframe, with early innovators in sectors like oil and gas, and chemistry, that already understand the value of the technology and are adopting sooner.

"Whether or not you adopt quantum analytics now, you should minimally have it on your IT roadmap," Savoie said. "Quantum computing is a bit like the COVID-19 crisis. At first, there were only two deaths; then two weeks later, there were ten thousand. Quantum computing and analytics is a highly disruptive technology that can exponentially advance some companies over others."

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Quantum computing analytics: Put this on your IT roadmap - TechRepublic

Seeqc UK Awarded 1.8M in Grants to Advance Quantum Computing Initiatives – HPCwire

LONDON Seeqc, the Digital Quantum Computing company, announced its UK team has been selected to receive two British grants totaling 1.8 million (~$2.1 million) from Innovate UKs Industrial Challenge Strategy Fund.

Quantum Foundry

The first 800,000 grant from Innovate UK is part of a 7M project dedicated to advancing the commercialization of superconducting technology. Its goal is to bring quantum computing closer to business-applicable solutions, cost-efficiently and at scale.

Seeqc UK is joining six UK-based companies and universities in a consortium to collaborate on the initiative. This is the first concerted effort to bring all leading experts across industry and academia together to advance the development of quantum technologies in the UK.

Othergrant recipientsinclude Oxford Quantum Circuits, Oxford Instruments, Kelvin Nanotechnology, University of Glasgow and the Royal Holloway University of London.

Quantum Operating System

The second 1 million grant is part of a 7.6 million seven-organization consortium dedicated to advancing the commercialization of quantum computers in the UK by building a highly innovative quantum operating system. A quantum operating system, Deltaflow.OS, will be installed on all quantum computers in the UK in order to accelerate the commercialization and collaboration of the British quantum computing community. The universal operating system promises to greatly increase the performance and accessibility of quantum computers in the UK.

Seeqc UK is joined by othergrant recipients, Riverlane, Hitachi Europe, Universal Quantum, Duality Quantum Photonics, Oxford Ionics, and Oxford Quantum Circuits, along with UK-based chip designer, ARM, and the National Physical Laboratory.

Advancing Digital Quantum Computing

Seeqc owns and operates a multi-layer superconductive electronics chip fabrication facility, which is among the most advanced in the world. The foundry serves as a testing and benchmarking facility for Seeqc and the global quantum community to deliver quantum technologies for specific use cases. This foundry and expertise will be critical to the success of the grants. Seeqcs Digital Quantum Computing solution is designed to manage and control qubits in quantum computers in a way that is cost-efficient and scalable for real-world business applications in industries such as pharmaceuticals, logistics and chemical manufacturing.

Seeqcs participation in these new industry-leading British grants accelerates our work in making quantum computing useful, commercially and at scale, said Dr. Matthew Hutchings, chief product officer and co-founder at Seeqc, Inc. We are looking forward to applying our deep expertise in design, testing and manufacturing of quantum-ready superconductors, along with our resource-efficient approach to qubit control and readout to this collaborative development of quantum circuits.

We strongly support the Deltaflow.OS initiative and believe Seeqc can provide a strong contribution to both consortiums work and advance quantum technologies from the lab and into the hands of businesses via ultra-focused and problem-specific quantum computers, continued Hutchings.

Seeqcs solution combines classical and quantum computing to form an all-digital architecture through a system-on-a-chip design that utilizes 10-40 GHz superconductive classical co-processing to address the efficiency, stability and cost issues endemic to quantum computing systems.

Seeqc is receiving the nearly $2.3 million in grant funding weeks after closing its $6.8 million seed round from investors including BlueYard Capital, Cambium, NewLab and the Partnership Fund for New York City. The recent funding round is in addition to a $5 million investment from M Ventures, the strategic corporate venture capital arm of Merck KGaA, Darmstadt, Germany.

About Seeqc

Seeqc is developing the first fully digital quantum computing platform for global businesses. Seeqc combines classical and quantum technologies to address the efficiency, stability and cost issues endemic to quantum computing systems. The company applies classical and quantum technology through digital readout and control technology and a unique chip-scale architecture. Seeqcs quantum system provides the energy- and cost-efficiency, speed and digital control required to make quantum computing useful and bring the first commercially-scalable, problem-specific quantum computing applications to market.

Source: Seeqc

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Seeqc UK Awarded 1.8M in Grants to Advance Quantum Computing Initiatives - HPCwire

Registration Open for Inaugural IEEE International Conference on Quantum Computing and Engineering – HPCwire

LOS ALAMITOS, Calif.,May 14, 2020 Registration is now open for the inauguralIEEE International Conference on Quantum Computing and Engineering (QCE20), a multidisciplinary event focusing on quantum technology, research, development, and training. QCE20, also known as IEEE Quantum Week, will deliver a series ofworld-class keynotes,workforce-building tutorials,community-building workshops, andtechnical paper presentations and postersonOctober 12-16inDenver, Colorado.

Were thrilled to open registration for the inaugural IEEE Quantum Week, founded by the IEEE Future Directions Initiative and supported by multiple IEEE Societies and organizational units, said Hausi Mller, QCE20 general chair and co-chair of the IEEE Quantum Initiative.Our initial goal is to address the current landscape of quantum technologies, identify challenges and opportunities, and engage the quantum community. With our current Quantum Week program, were well on track to deliver a first-rate quantum computing and engineering event.

QCE20skeynote speakersinclude the following quantum groundbreakers and leaders:

The week-longQCE20 tutorials programfeatures 15 tutorials by leading experts aimed squarely at workforce development and training considerations. The tutorials are ideally suited to develop quantum champions for industry, academia, and government and to build expertise for emerging quantum ecosystems.

Throughout the week, 19QCE20 workshopsprovide forums for group discussions on topics in quantum research, practice, education, and applications. The exciting workshops provide unique opportunities to share and discuss quantum computing and engineering ideas, research agendas, roadmaps, and applications.

The deadline for submittingtechnical papersto the eight technical paper tracks isMay 22. Papers accepted by QCE20 will be submitted to the IEEE Xplore Digital Library. The best papers will be invited to the journalsIEEE Transactions on Quantum Engineering(TQE)andACM Transactions on Quantum Computing(TQC).

QCE20 provides attendees a unique opportunity to discuss challenges and opportunities with quantum researchers, scientists, engineers, entrepreneurs, developers, students, practitioners, educators, programmers, and newcomers. QCE20 is co-sponsored by the IEEE Computer Society, IEEE Communications Society, IEEE Council on Superconductivity,IEEE Electronics Packaging Society (EPS), IEEE Future Directions Quantum Initiative, IEEE Photonics Society, and IEEETechnology and Engineering Management Society (TEMS).

Registerto be a part of the highly anticipated inaugural IEEE Quantum Week 2020. Visitqce.quantum.ieee.orgfor event news and all program details, including sponsorship and exhibitor opportunities.

About the IEEE Computer Society

The IEEE Computer Society is the worlds home for computer science, engineering, and technology. A global leader in providing access to computer science research, analysis, and information, the IEEE Computer Society offers a comprehensive array of unmatched products, services, and opportunities for individuals at all stages of their professional career. Known as the premier organization that empowers the people who drive technology, the IEEE Computer Society offers international conferences, peer-reviewed publications, a unique digital library, and training programs. Visitwww.computer.orgfor more information.

About the IEEE Communications Society

TheIEEE Communications Societypromotes technological innovation and fosters creation and sharing of information among the global technical community. The Society provides services to members for their technical and professional advancement and forums for technical exchanges among professionals in academia, industry, and public institutions.

About the IEEE Council on Superconductivity

TheIEEE Council on Superconductivityand its activities and programs cover the science and technology of superconductors and their applications, including materials and their applications for electronics, magnetics, and power systems, where the superconductor properties are central to the application.

About the IEEE Electronics Packaging Society

TheIEEE Electronics Packaging Societyis the leading international forum for scientists and engineers engaged in the research, design, and development of revolutionary advances in microsystems packaging and manufacturing.

About the IEEE Future Directions Quantum Initiative

IEEE Quantumis an IEEE Future Directions initiative launched in 2019 that serves as IEEEs leading community for all projects and activities on quantum technologies. IEEE Quantum is supported by leadership and representation across IEEE Societies and OUs. The initiative addresses the current landscape of quantum technologies, identifies challenges and opportunities, leverages and collaborates with existing initiatives, and engages the quantum community at large.

About the IEEE Photonics Society

TheIEEE Photonics Societyforms the hub of a vibrant technical community of more than 100,000 professionals dedicated to transforming breakthroughs in quantum physics into the devices, systems, and products to revolutionize our daily lives. From ubiquitous and inexpensive global communications via fiber optics, to lasers for medical and other applications, to flat-screen displays, to photovoltaic devices for solar energy, to LEDs for energy-efficient illumination, there are myriad examples of the Societys impact on the world around us.

About the IEEE Technology and Engineering Management Society

IEEE TEMSencompasses the management sciences and practices required for defining, implementing, and managing engineering and technology.

Source: IEEE Computer Society

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Registration Open for Inaugural IEEE International Conference on Quantum Computing and Engineering - HPCwire