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Dangerous legislation banning the teaching of critical race theory in Ohio schools advances in the state legislature. House Bills 322 and 327 are ill-conceived and dishonest displays of right-wing ideology. Imitating other states, they closely follow sample legislation from organized national campaigns by Heritage Action for America, 1776 Project, and Citizens for Renewing America.

The bills authors and their sources (handbooks and toolkits) are ignorant of critical race theory and American history. They create straw figures to criticize with biased ideology. For example, Christopher F. Rufo, a leading propagandist, falsely asserts that reputable scholars are Marxists calling for the overthrow of capitalism. Claiming to defend children, they promote ignorance. They fear that children will gain an accurate, shared knowledge of the complicated American experience. They are anti-democratic and un-American.

The partisan effort to ban teaching about race is an unconstitutional violation of the First Amendment free-speech rights of teachers and students. It is also unenforceable. There arent K-12 courses called critical race theory. They exist principally as required mainstream courses in law schools. More broadly, critical race theory is a general approach that views race and slavery as central to American history, an undeniable point.

We must oppose this attack.

Harvey J. Graff,

Columbus

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Assault on critical race theory is an attack on democracy itself - cleveland.com

Nippon Steel has concluded that, despite the current hardware limitations of quantum computers, the technology holds a lot of promise when it comes to optimizing complex problems.

From railways and ships all the way to knives and forks: the number of products that are made of steel is too high to list and to ensure a steady supply of the sought-after material, Japanese steel manufacturer Nippon Steel is now looking at how quantum computing might help.

The company, which produced a hefty 50 million tons of steel in 2019 (that is, 40% of the total production in Japan) has partnered with Cambridge Quantum Computing (CQC) and Honeywell to find out whether quantum computers have the potential to boost efficiencies in the supply chain.

And after over a year of testing and trying new algorithms, the company has concluded that,despite the current hardware limitations of quantum computers, the technology holds a lot of promise when it comes to optimizing complex problems.

"The results Nippon Steel and Cambridge Quantum Computing were able to achieve indicate that quantum computing will be a powerful tool for companies seeking a competitive advantage," said Tony Uttley, the president of Honeywell Quantum Solutions.

SEE: Building the bionic brain (free PDF) (TechRepublic)

The steel manufacturing process is a highly elaborate affair, involving many different steps and requiring various raw materials before the final product can be built.

Plants start by pre-treating and refining iron ore, coal and other minerals to process them into slabs of steel, which are then converted into products like rails, bars, pipes, tubes and wheels.

In the case of Nippon Steel, where millions of tons of material are at stake, finding the best equation to make sure that the right products are in the right place and at the right time is key to delivering orders as efficiently as possible.

Toss in strict deadlines, and it is easy to see why industry leaders are looking for the most advanced tools possible to model and optimize the whole system, and at the same time reduce operating costs.

For this reason, the use of pen and paper has long been replaced by sophisticated software services, and Nippon Steel has been a long-time investor in advanced computing but even today's most powerful supercomputers can struggle to come up with optimal solutions to such complex problems.

Classical computers can only offer simplifications and approximations. The Japanese company, therefore, decided to try its hand at quantum technologies, andannounced a partnership with quantum software firm CQC last year.

"Scheduling at our steel plants is one of the biggest logistical challenges we face, and we are always looking for ways to streamline and improve operations in this area," said Koji Hirano, chief researcher at Nippon Steel.

Quantum computers rely on qubits tiny particles that can take on a special, dual quantum state that enables them to carry out multiple calculations at once. This means, in principle, that the most complex problems that cannot be solved by classical computers in any realistic timeframe could one day be run on quantum computers in a matter of minutes.

The technology is still in its infancy: quantum computers can currently only support very few qubits and are not capable of carrying out computations that are useful at a business's scale. Scientists, rather, are interested in demonstrating the theoretical value of the technology, to be prepared to tap into the potential of quantum computers once their development matures.

In practice, for Nippon Steel, this meant using CQC's services and expertise to discover which quantum algorithms could most effectively model and optimize the company's supply chain.

To do so, the two companies' research teams focused on formulating a small-scale problem, which, although it does not bring significant value to Nippon Steel, can be resolved using today's nascent quantum hardware.

The researchers developed a quantum algorithm for this "representative" problem and ran it on Honeywell's System Model H1 the latest iteration of the company's trapped-ion quantum computing hardware, which has 10 available qubits and a record-breaking quantum volume of 512. After only a few steps, say the scientists, the System Model H1 was able to find an optimal solution.

"The results are encouraging for scaling up this problem to larger instances," said Mehdi Bozzo Rey, the head of business development at CQC. "This experiment showcases the capabilities of the System Model H1 paired with modern quantum algorithms and how promising this emerging technology really is."

What's more: an optimization algorithm such as the one developed by CQC and Nippon Steel can be applied to many other scenarios in manufacturing, transport and distribution.

Earlier this year, for example, IBM and energy giant ExxonMobil revealed that they had been working together tobuild quantum algorithms that could one day optimize the routing of tens of thousands of merchant shipscrossing the oceans to deliver everyday goods a $14 trillion industry that could hugely benefit from operational efficiencies.

The results from Nippon Steel are the first to emerge followingthe announcement of a partnership between Honeywell and CQC earlier this month. CQC's quantum software capabilities are planned to merge with Honeywell's quantum hardware services in a deal that is expected to make waves in the industry.

By joining forces, the two companies are effectively set to become leaders in the quantum ecosystem. The early results from the trials with Nippon Steel, therefore, are likely to be only the start of many new projects to come, as the two firms apply their complementary expertise to global issues affecting various different industries.

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Quantum computing just took on another big challenge, one that could be as tough as steel - ZDNet

Research from the McKelvey School of Engineering at Washington University in St. Louis has found a missing piece in the puzzle of optical quantum computing.

Jung-Tsung Shen, associate professor in the Department of Electrical & Systems Engineering, has developed a deterministic, high-fidelity two-bit quantum logic gate that takes advantage of a new form of light. This new logic gate is orders of magnitude more efficient than the current technology.

In the ideal case, the fidelity can be as high as 97%, Shen said.

His research was published in May 2021 in the journal Physical Review A.

The potential of quantum computers is bound to the unusual properties of superposition the ability of a quantum system to contain many distinct properties, or states, at the same time and entanglement two particles acting as if they are correlated in a non-classical manner, despite being physically removed from each other.

Where voltage determines the value of a bit (a 1 or a 0) in a classical computer, researchers often use individual electrons as qubits, the quantum equivalent. Electrons have several traits that suit them well to the task: they are easily manipulated by an electric or magnetic field and they interact with each other. Interaction is a benefit when you need two bits to be entangled letting the wilderness of quantum mechanics manifest.

But their propensity to interact is also a problem. Everything from stray magnetic fields to power lines can influence electrons, making them hard to truly control.

For the past two decades, however, some scientists have been trying to use photons as qubits instead of electrons. If computers are going to have a true impact, we need to look into creating the platform using light, Shen said.

Photons have no charge, which can lead to the opposite problems: they do not interact with the environment like electrons, but they also do not interact with each other. It has also been challenging to engineer and to create ad hoc (effective) inter-photon interactions. Or so traditional thinking went.

Less than a decade ago, scientists working on this problem discovered that, even if they werent entangled as they entered a logic gate, the act of measuring the two photons when they exited led them to behave as if they had been.The unique features of measurement are another wild manifestation of quantum mechanics.

Quantum mechanics is not difficult, but its full of surprises, Shen said.

The measurement discovery was groundbreaking, but not quite game-changing. Thats because for every 1,000,000 photons, only one pair became entangled. Researchers have since been more successful, but, Shen said, Its still not good enough for a computer, which has to carry out millions to billions of operations per second.

Shen was able to build a two-bit quantum logic gate with such efficiency because of the discovery of a new class of quantum photonic states photonic dimers, photons entangled in both space and frequency. His prediction of their existence was experimentally validated in 2013, and he has since been finding applications for this new form of light.

When a single photon enters a logic gate, nothing notable happens it goes in and comes out. But when there are two photons, Thats when we predicted the two can make a new state, photonic dimers. It turns out this new state is crucial.

Mathematically, there are many ways to design a logic gate for two-bit operations. These different designs are called equivalent. The specific logic gate that Shen and his research group designed is the controlled-phase gate (or controlled-Z gate). The principal function of the controlled-phase gate is that the two photons that come out are in the negative state of the two photons that went in.

In classical circuits, there is no minus sign, Shen said. But in quantum computing, it turns out the minus sign exists and is crucial.

Quantum mechanics is not difficult, but its full of surprises.

When two independent photons (representing two optical qubits) enter the logic gate, The design of the logic gate is such that the two photons can form a photonic dimer, Shen said. It turns out the new quantum photonic state is crucial as it enables the output state to have the correct sign that is essential to the optical logic operations.

Shen has been working with the University of Michigan to test his design, which is a solid-state logic gate one that can operate under moderate conditions. So far, he says, results seem positive.

Shen says this result, while baffling to most, is clear as day to those in the know.

Its like a puzzle, he said. It may be complicated to do, but once its done, just by glancing at it, you will know its correct.

The McKelvey School of Engineering at Washington University in St. Louis promotes independent inquiry and education with an emphasis on scientific excellence, innovation and collaboration without boundaries. McKelvey Engineering has top-ranked research and graduate programs across departments, particularly in biomedical engineering, environmental engineering and computing, and has one of the most selective undergraduate programs in the country. With 140 full-time faculty, 1,387 undergraduate students, 1,448 graduate students and 21,000 living alumni, we are working to solve some of societys greatest challenges; to prepare students to become leaders and innovate throughout their careers; and to be a catalyst of economic development for the St. Louis region and beyond.

This research was supported by the National Science Foundation, ECCS grants nos. 1608049 and 1838996. It was also supported by the 2018 NSF Quantum Leap (RAISE) Award.

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A new piece of the quantum computing puzzle - Washington University in St. Louis Newsroom

Polaris Quantum Biotech is reinventing drug discovery, reducing the time it takes to find candidate molecules for drug development from the typical three years to just four months. As with other successful efforts to redesign established processes, Polaris is betting on scalability and automation. The startup, co-founded by Shahar Keinan and Bill Shipman, came out of stealth a year ago, revealing the first-ever drug discovery platform using a quantum computer, cost-efficiently scanning billions of molecules from a large chemical space.

Dr. Shahar Keinan, CEO, Polaris Quantum Biotech

Having worked in the drug development industry for years, Polaris founders decided to try and address the two major challenges they identified: The technology used and the business model. We wanted to solve both of these problems together, says Polaris CEO, Shahar Keinan.

The technology-related part of their solution was to use quantum computing, rather than classical computers, to speed-up the process. In terms of the business model, in contrast to the research labs (or Contract Research Organizations) that provide molecular discovery as a service to large pharmaceutical companies, Polaris is licensing their discoveries. With this business model, says Keinan, you need a diverse portfolio in order to diversify your risk. Diversity here is defined as the target disease, the specific protein targeted, and even the delivery mechanism.

Based on industry benchmarks, out of 100 assets (i.e., drug blueprints, lead compounds), between 1 to 5 will be used in a drug that will be sold commercially. Between 75 to 80 may reach clinical testing but typically this number could be reduced to no more than 25 over subsequent testing phases. Polaris is paid at each stage in the drugs journey to the market, and increasingly more as each hurdle is passed successfully.

The lead compounds Polaris develops target specific biological processes that are known to be the cause of a specific disease and are designed to get involved in the process in a way that arrests its further development or eliminates it altogether. We take this big biological machine and put a wrench into it, says Keinan. The trick is to find a molecule that will do exactly what it is expected to do but will not do other, not useful or potentially harmful, things to other biological processes in the human body.

Polaris is developing an ecosystem around its drug discovery platform, enlisting various hardware and software resources to assist it. Last year, it partnered with Fujitsus quantum-inspired Digital Annealer technology, initially targeting dengue fever, a mosquito-borne condition that is present in over 100 countries worldwide, killing as many as 22,000 people each year. Another quantum computing provider Polaris is working with is D-Wave Systems, accessing its quantum annealing technology through the AWS cloud service.

Yet another Polaris partnership was announced recently, collaborating with Auransa to discover treatments for neglected diseases disproportionately affecting women.An example is endometriosis, an incurable condition affecting millions of women caused when tissue that lines the womb grows elsewhere in the abdomen. Auransa is using AI to develop precision medicine solutions in areas of unmet medical needs, and in this partnership, Auransa finds the biological target and Polaris finds the arrow (the lead compound) that will hit the targets bullseye.

Over the last decade, there has been a growing application of AI (or machine/deep learning) to drug discovery and pharmaceutical company executives expect it to be the emerging technology that will have the greatest impact on their industry in 2021. Last year, a survey of life science organizations found that 31% were set to begin quantum computing evaluation in 2020 and a further 39% were planning to evaluate it in 2021 or have quantum computing on their radar. Polaris Quantum Biotech could well be at the center of a perfect storm that will accelerate the pace of drug discovery.

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This Startup Is Using Quantum Computing And AI To Cut Drug Discovery Time From 3 Years To 4 Months - Forbes

LOS ALAMITOS, Calif., June 24, 2021 The IEEE International Conference on Quantum Computing and Engineering (QCE21), a multidisciplinary event bridging the gap between the science of quantum computing and the development of an industry surrounding it, reveals its full keynote lineup. Taking place 18-22 October 2021 virtually, QCE21 will deliver a series of world-class keynote presentations, as well as workforce-building tutorials, community-building workshops, technical paper presentations, stimulating panels, and innovative posters. Register here.

Also known as IEEE Quantum Week, QCE21 is unique by integrating dimensions from academic and business conferences and will reveal cutting edge research and developments featuring quantum research, practice, applications, education, and training.

QCE21s Keynote Speakers include the following quantum groundbreakers and leaders:

Alan Baratz D-Wave Systems, President & CEOJames S. Clarke Intel Labs, Director of Quantum HardwareDavid J. Dean Oak Ridge National Laboratory, Director Quantum Science CenterJay Gambetta IBM Quantum, IBM Fellow & VP Quantum ComputingSonika Johri IonQ, Senior Quantum Applications Research ScientistAnthony Megrant Google Quantum AI, Lead Research ScientistPrineha Narang Harvard University & Aliro Quantum, Professor & CTOBrian Neyenhuis Honeywell Quantum Solutions, Commercial Operations LeaderUrbasi Sinha Raman Research Institute, Bangalore, ProfessorKrista Svore Microsoft, General Manager Quantum Systems

Through participation from the international quantum community, QCE21 has developed an extensive conference program with world-class keynote speakers, technical paper presentations, innovative posters, exciting exhibits, technical briefings, workforce-building tutorials, community-building workshops, stimulating panels, and Birds-of-Feather sessions.

Papers accepted by QCE21 will be submitted to the IEEE Xplore Digital Library, and the best papers will be invited to the journals IEEE Transactions on Quantum Engineering (TQE) and ACM Transactions on Quantum Computing (TQC).

QCE21 is co-sponsored by IEEE Computer Society, IEEE Communications Society, IEEE Council of Superconductivity, IEEE Future Directions Committee, IEEE Photonics Society, IEEE Technology and Engineering Management Society, IEEE Electronics Packaging Society, IEEE Signal Processing Society (SP), and IEEE Electron Device Society (EDS).

The inaugural 2020 IEEE Quantum Week built a solid foundation and was highly successful over 800 people from 45 countries and 225 companies attended the premier event that delivered 270+ hours of programming on quantum computing and engineering.

The second annual 2021 Quantum Week will virtually connect a wide range of leading quantum professionals, researchers, educators, entrepreneurs, champions, and enthusiasts to exchange and share their experiences, challenges, research results, innovations, applications, and enthusiasm, on all aspects of quantum computing, engineering and technologies. The IEEE Quantum Week schedule will take place during Mountain Daylight Time (MDT).

Visit IEEE QCE21 for all event news including sponsorship and exhibitor opportunities.

QCE21 Registration Package provides Virtual Access to IEEE Quantum Week Oct 18-22, 2021 as well as On-Demand Access to all recorded events until the end of December 2021 featuring over 270 hours of programming in the realm of quantum computing and engineering.

About the IEEE Computer Society

TheIEEE Computer Societyis 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.

Source: IEEE

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Keynotes Announced for IEEE International Conference on Quantum Computing and Engineering - HPCwire