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In their study reported in Nature, Ni and her team set out to identify all the possible energy state outcomes, from start to finish, of a reaction between two potassium and rubidium moleculesa more complex reaction than had been studied in the quantum realm. Thats no easy feat: At its most fundamental level, a reaction between four molecules has a massive number of dimensions (the electrons spinning around each atom, for example, could be in an almost-infinite number of locations simultaneously). That very high dimensionality makes calculating all the possible reaction trajectories impossible with current technology.

Calculating exactly how energy redistributes during a reaction between four atoms is beyond the power of todays best computers, Ni said. A quantum computer might be the only tool that could one day achieve such a complex calculation.

In the meantime, calculating the impossible requires a few well-reasoned assumptions and approximations (picking one location for one of those electrons, for example) and specialized techniques that grant Ni and her team ultimate control over their reaction.

One such technique was another recent Ni lab discovery: She and her team exploited a reliable feature of molecules their highly stable nuclear spin to control the quantum state of the reacting molecules all the way through to the product, work they chronicled in a recent study published in Nature Chemistry. They also discovered a way to detect products from a single collision reaction event, a difficult feat when 10,000 molecules could be reacting simultaneously. With these two novel methods, the team could identify the unique spectrum and quantum state of each product molecule, the kind of precise control necessary to measure all 57 pathways their potassium rubidium reaction could take.

Over several months during the COVID-19 pandemic, the team ran experiments to collect data on each of those 57 possible reaction channels, repeating each channel once every minute for several days before moving on to the next. Luckily, once the experiment was set up, it could be run remotely: Lab members could stay home, keeping the lab re-occupancy at COVID-19 standards, while the system churned on.

The test, said Matthew Nichols, a postdoctoral scholar in the Ni lab and an author on both papers, indicates good agreement between the measurement and the model for a subset containing 50 state-pairs but reveals significant deviations in several state-pairs.

In other words, their experimental data confirmed that previous predictions based on statistical theory (one far less complex than Schrdingers equation) are accurate mostly. Using their data, the team could measure the probability that their chemical reaction would take each of the 57 reaction channels. Then, they compared their percentages with the statistical model. Only seven of the 57 showed a significant enough divergence to challenge the theory.

We have data that pushes this frontier, Ni said. To explain the seven deviating channels, we need to calculate Schrdingers equation, which is still impossible. So now, the theory has to catch up and propose new ways to efficiently perform such exact quantum calculations.

Next, Ni and her team plan to scale back their experiment and analyze a reaction between only three atoms (one molecule is made of two atoms, which is then forced to react with a single atom). In theory, this reaction, which has far fewer dimensions than a four-atom reaction, should be easier to calculate and study in the quantum realm. Yet, already, the team has discovered something strange: The intermediate phase of the reaction lives on for many orders of magnitude longer than the theory predicts.

There is already mystery, Ni said. Its up to the theorists now.

This work was supported by the Department of Energy, the David and Lucile Packard Foundation, the Arnold O. Beckman Postdoctoral Fellowship in Chemical Sciences, and the National Natural Science Foundation of China.

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Researchers design new experiments to map and test the quantum realm - Harvard Gazette

CLEVELAND -- The Cleveland Clinics partnership with IBM to use quantum computing for medical research brings to mind the most unfortunate instance of bad timing in the history of Cleveland: the 1967 merger of Case Institute of Technology with Western Reserve University just when the computer age was coming to life.

The merger squelched Cases opportunity to be among the leaders in the most revolutionary technology ever (and to benefit Cleveland with computer-related jobs). Might the arrival of quantum computing mean fresh opportunity?

At the time of the merger, Cases Department of Computer Engineering and Science had a good chance to be at the forefront. But capitalizing on that required support from senior administrators of the new Case Western Reserve University administrators who could not be focused on technology to the degree that Case, on its own, had been. In the new world of CWRU, technology was one of many fields.

A vision for the merged institutions prepared by a prominent commission gave only a brief mention of computing either as a current or potential strength of the new institution or as a challenge or opportunity to be addressed, according to Richard E. Baznik in Beyond the Fence: A Social History of Case Western Reserve University. The goose with golden innards wasnt even recognized, let alone encouraged to lay eggs.

Further, the merger created the worst possible institutional environment for computer advocates. Not only did administrators have to contend with issues of who might lose their job because of consolidation and who would have which power (particularly over budget), they also had to manage the challenge that all universities were facing as the post-World War II surge in enrollment and federal funding was ebbing.

Inescapably, the units that formed CWRU were locked in competition for shrinking resources, if not survival. And in that mix, dominated by heavyweights such as the School of Medicine and the main sciences, computers was a flyweight.

All of that was topped off by intense feelings among Case people of being severely violated by the Institutes loss of independence, which feelings were heightened by the substantial upgrading that had occurred under the longtime leadership of former Case president T. Keith Glennan (president from 1947 to 1966).

Thomas Bier is an associate of the university at Cleveland State University.

The combination of those potent forces upset CWRU institutional stability, which was not fully reestablished until the presidency of Barbara Snyder 40 years later.

Although in 1971, CWRUs computer engineering program would be the first of its type to be accredited in the nation, momentum sagged and the opportunity to be among the vanguard was lost. Today, the universitys programs in computer engineering and science are well-regarded but not top-tier.

But the arrival of quantum computing poses the challenge to identify new opportunity and exploit it.

Quantum computing, as IBM puts it, is tomorrows computing today. Its enormous processing power enables multiple computations to be performed simultaneously with unprecedented speed. And the Clinics installation will be first private-sector, on-premises system in the United States.

Clinic CEO and President Dr. Tomislav Mihaljevic said, These new computing technologies can help revolutionize discovery in the life sciences and help transform medicine, while training the workforce of the future and potentially growing our economy.

In terms of jobs, the economy of Northeast Ohio has been tepid for decades, reflecting, in part, its scant role in computer innovation. While our job growth has been nil, computer hot spots such as Seattle and Austin have been gaining an average of 25,000 jobs annually.

Cleveland cannot become a Seattle or an Austin. Various factors dictate that. But, hopefully, the arrival of quantum computing a short distance down Euclid Avenue from CWRU will trigger creative, promising initiatives. Maybe, as young technologists and researchers become involved in the Clinic-IBM venture, an innovative entrepreneur will emerge and lead the growth of a whole new industry. Maybe, the timing couldnt be better.

Quantum computing bring, it, on!

Thomas Bier is an associate of the university at Cleveland State University where, until he retired in 2003, he was director of the Housing Policy Research Program in the Maxine Goodman Levin College of Urban Affairs. Bier received both his masters in science degree, in 1963, and Ph.D., in 1968, from from Case/CWRU. Both degrees are in organizational behavior.

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* Email general questions about our editorial board or comments or corrections on this opinion column to Elizabeth Sullivan, director of opinion, at esullivan@cleveland.com.

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Quantum computings imminent arrival in Cleveland could be a back-to-the-future moment: Thomas Bier - cleveland.com

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Quantum Computing Market 2021-Industry Demands, Size & Share, Covid-19 Impact Analysis, Recent Developments, Global Growth, Trends, Top Operating...

Mapping the quantum frontier, one layer at a time. Artists concept.

Researchers design new experiments to map and test the mysterious quantum realm.

A heart surgeon doesnt need to grasp quantum mechanics to perform successful operations. Even chemists dont always need to know these fundamental principles to study chemical reactions. But for Kang-Kuen Ni, the Morris Kahn associate professor of chemistry and chemical biology and of physics, quantum spelunking is, like space exploration, a quest to discover a vast and mysterious new realm.

Today, much of quantum mechanics is explained by Schrdingers equation, a kind of master theory that governs the properties of everything on Earth. Even though we know that, in principle, quantum mechanics governs everything, Ni said, to actually see it is difficult and to actually calculate it is near-impossible.

With a few well-reasoned assumptions and some innovative techniques, Ni and her team can achieve the near-impossible. In their lab, they test current quantum theories about chemical reactions against actual experimental data to edge closer to a verifiable map of the laws that govern the mysterious quantum realm. And now, with ultracold chemistry in which atoms and molecules are cooled to temperatures just above absolute zero where they become highly-controllable Ni and her lab members have collected real experimental data from a previously unexplored quantum frontier, providing strong evidence of what the theoretical model got right (and wrong), and a roadmap for further exploration into the next shadowy layers of quantum space.

We know the underlying laws that govern everything, said Ni. But because almost everything on Earth is made of at least three or more atoms, those laws quickly become far too complex to solve.

Kang-Kuen Ni, right, and post-doc fellow Matthew A. Nichols do a hands-on consult in their lab. Ni and her team use ultra-cold chemistry to test quantum theory against actual experimental data and create a verifiable map of the quantum laws that govern everything on earth. Credit: Jon Chase/Harvard Staff Photographer

In their study reported in Nature, Ni and her team set out to identify all the possible energy state outcomes, from start to finish, of a reaction between two potassium and rubidium molecules a more complex reaction than had been previously studied in the quantum realm. Thats no easy feat: At its most fundamental level, a reaction between four molecules has a massive number of dimensions (the electrons spinning around each atom, for example, could be in an almost-infinite number of locations simultaneously). That very high dimensionality makes calculating all the possible reaction trajectories impossible with current technology.

Calculating exactly how energy redistributes during a reaction between four atoms is beyond the power of todays best computers, Ni said. A quantum computer might be the only tool that could one day achieve such a complex calculation.

In the meantime, calculating the impossible requires a few well-reasoned assumptions and approximations (picking one location for one of those electrons, for example) and specialized techniques that grant Ni and her team ultimate control over their reaction.

One such technique was another recent Ni lab discovery: In a study published in Nature Chemistry, she and her team exploited a reliable feature of molecules their highly stable nuclear spin to control the quantum state of the reacting molecules all the way through to the products. They also discovered a way to detect products from a single collision reaction event, a difficult feat when 10,000 molecules could be reacting simultaneously. With these two novel methods, the team could identify the unique spectrum and quantum state of each product molecule, the kind of precise control necessary to measure all 57 pathways their potassium rubidium reaction could take.

Over several months during the COVID-19 pandemic, the team ran experiments to collect data on each of those 57 possible reaction channels, repeating each channel once every minute for several days before moving on to the next. Luckily, once the experiment is set up, it can be run remotely: Lab members could stay home, keeping the lab re-occupancy at COVID-19 standards, while the system churned on.

The test, said Matthew Nichols, a postdoctoral scholar in the Ni lab and an author on both papers, indicates good agreement between the measurement and the model for a subset containing 50 state-pairs but reveals significant deviations in several state-pairs.

In other words, their experimental data confirmed that previous predictions based on statistical theory (one far less complex than Schrdingers equation) are accurate mostly. Using their data, the team could measure the probability that their chemical reaction would take each of the 57 reaction channels. Then, they compared their percentages with the statistical model. Only seven of the 57 showed a significant enough divergence to challenge the theory.

We have data that pushes this frontier, Ni said. To explain the seven deviating channels, we need to calculate Schrdingers equation, which is still impossible. So now, the theory has to catch up and propose new ways to efficiently perform such exact quantum calculations.

Next, Ni and her team plan to scale back their experiment and analyze a reaction between only three atoms (one molecule and an atom). In theory, this reaction, which has far fewer dimensions than a four-atom reaction, should be easier to calculate and study in the quantum realm. And yet, already, the team discovered something strange: the intermediate phase of the reaction lives on for many orders of magnitude longer than the theory predicts.

There is already mystery, Ni said. Its up to the theorists now.

Reference: Precision test of statistical dynamics with state-to-state ultracold chemistry by Yu Liu, Ming-Guang Hu, Matthew A. Nichols, Dongzheng Yang, Daiqian Xie, Hua Guo and Kang-Kuen Ni, 19 May 2021, Nature.DOI: 10.1038/s41586-021-03459-6

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Mapping the Quantum Frontier: New Experiments Designed to Test the Mysterious Quantum Realm - SciTechDaily

Basking in warm sunshine and an atmosphere of optimism, the Terp community came together today at Maryland Stadium to honor the Class of 2021s achievements in the face of COVID-19s unprecedented challenges.

We really are Terrapin Strong, University of Maryland President Darryll J. Pines told the crowd at the 11 a.m. commencement ceremony. Seeing your faces in person is a sign. Its a sign that we are beginning to win this fight against this virus. Its a sign that your collective resilience and strength and grit is stronger than any challenge you will face.

The 8,500 members of the Spring 2021 graduating class are being honored today with two in-person, outdoor ceremonies at the stadium, divided by school and collegethe first open-air graduations in 66 years. Graduates could bring two guests, sat in distanced households of three for safety reasons and were sent off with an appearance from Testudo and a fireworks display. Spring 2020 and Winter 2020 graduates, who had only virtual ceremonies due to the pandemic, were invited to attend as well.

We were reminded that each day is precious and many of us vow to never again take for granted the everyday parts of life, Maryland Gov. Larry Hogan said in a recorded message. I hope that as you graduate today, you remember that each of us can make the days ahead count that much more.

Hannah Rhee 21, the student speaker and computer science major, said the pandemic and recent social justice challenges facing the entire nation are reminders that asking for help and relying on friends and family are proof of strength, not weakness.

Through these relationships I learned about the world, made lasting friendships and developed my character, she said. I believe we are emerging as fearless Terps, more thoughtful and more kind because of our experiences.

The main, recorded address was delivered by Peter Chapman, president and CEO of IonQ, a leading quantum computing company spun off from UMD research and headquartered in the nearby Discovery District. The son of a NASA scientist-astronaut and formerly director of engineering for Amazon Prime, Chapman urged graduates to meet the future with optimism and look to the promise of technology in answering challenges ranging from disease to climate change.

I know that for some of you, this day is bittersweet, he said. But for all that youve lost, for all that we have all lost, youve gained a lot, too: memories and friendships, new strengths and new skills. And today, a degree from the University of Maryland.

More than 8,500 students were granted degrees at the Spring 2021 ceremonies at Maryland Stadium. Graduates from Spring and Winter 2020 were also invited to celebrate in-person after having virtual ceremonies due to COVID-19.Photo by Stephanie S. Cordle

UMD President Darryll J. Pines praised graduates for their resiliency over the past year as the COVID-19 pandemic necessitated changes inside and out of the classroom.Photo by John T. Consoli

Senior marshal Alyssa Conway represented the College of Education at Fridays ceremonies. Senior marshals are chosen for academic excellence, service, extracurriculars and personal growth to assist at commencement.Photo by Stephanie S. Cordle

Peter Chapman, president and CEO of quantum computing company IonQ, delivered the main commencement address via recording. He urged graduates to be optimistic about the future and the promise that technology holds for issues ranging from disease to climate change.Photo by John T. Consoli

Graduates were able to invite two guests to join them at morning and afternoon commencement ceremonies in Maryland Stadium separated by school and college. The socially distanced events marked the first in-person graduation festivities since the beginning of the COVID-19 pandemic in Spring 2020.Photo by Stephanie S. Cordle

Student speaker Hannah Rhee, a computer science major, emphasized the importance of relationships to support students studying through the twin pandemics of COVID-19 and social unrest brought on by racism and inequality.Photo by Stephanie S. Cordle

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Maryland Today | 'We Really Are Terrapin Strong' - Maryland Today