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In this episode of Brains, Black Holes, and Beyond, Senna Aldoubosh and Noelle Kim sit down with Josh Leeman, a graduate student in the Electrical and Computer Engineering department. Leeman discusses his interest in applying technologies from condensed matter theory to quantum computing applications, how doing research remotely during the pandemic gave him insight on his research interests, and valuable advice for students when making their future plans.

This episode of Brains, Black Holes, and Beyond (B Cubed) was produced under the 147th board of the Prince in partnership with the Insights newsletter.

For more information about the Schoop Lab and Joshs research, feel free to visit the pages linked below.

RESOURCES

https://schoop.princeton.edu/https://jleeman.com/

CREDITS

Written and Hosted by Senna Aldoubosh and Noelle Kim

Edited and Sound Engineered by Noelle Kim

Transcript by Noelle Kim

Produced by Senna Aldoubosh

For more from The Daily Princetonian, visit dailyprincetonian.com. For more from Princeton Insights, visit insights.princeton.edu. Please direct all corrections to corrections@dailyprincetonian.com.

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Material Design and Quantum Computing Applications w/ Grad ... - The Daily Princetonian

KINGSTON, R.I. April 14, 2023 On World Quantum Day, April 14, the University of Rhode Island community gathered to celebrate a new quantum computing initiative, aimed at positioning URI students and the Rhode Island workforce at the forefront of the next great computing revolution.

The initiative includes a new research partnership with IBM that will provide URI faculty and students with access to IBMs cutting-edge quantum computing systems. The initiative will bring new visiting faculty, postdoctoral researchers, and graduate students to URI in support of the Universitys masters degree and graduate certificate programs in quantum computing. Additional outreach and summer research opportunities for high school students will help to spark interest in the next generation of students.

The initiative is supported by a $1 million directed federal earmark secured by U.S. Sen. Jack Reed, as well as funding from the URI College of Arts and Sciences and the Graduate School of Oceanography.

As Rhode Islands flagship university, its incumbent upon us to be in a leadership position when it comes to the technologies that will shape the future of our state and nation, said URI President Marc Parlange. Through this initiative, were harnessing our faculty expertise in guiding the development of quantum technologies, while giving our students opportunities to hit the ground running with a technology that promises to reshape our world.

Quantum information science promises to be the next paradigm-shifting idea.It will enable unparalleled scientific advancement that paves the way for ground-breaking discoveries, said Senator Reed. I am proud to deliver $1 million for the new Quantum Computing Initiative here at Rhode Islands flagship public research university. This initiative will help establish URI as a hub for quantum information science in the Northeast, helping the university expand its teaching capacity, bringing in experts to expand the universitys quantum degree programs, and training the next generation of students and researchers.

Reed and Parlange helped to kick off a World Quantum Day symposium at URI featuring prominent speakers from the quantum computing world. Participants included URI alumni Christopher Savoie, co-founder and chief executive officer of Zapata Computing, and Adele Merritt, intelligence community chief information officer at the Office of the Director of National Intelligence. Savoie earned his bachelors degree from URI and serves on the College of Arts and Sciences Advisory Council. Merritt earned her Ph.D. from URI in mathematics.

Other speakers included Christopher Lirakis, lead for quantum systems deployment at IBM; Charles Robinson, quantum computing public sector leader at IBM; Kurt Jacobs, deputy chief scientist at the Army Research Laboratory; Pedro Lopes, business developer at the computing firm QuEra; and Juan Rivera, senior engineer at Dell Computing.

Partnering with IBM

Quantum computing, which takes advantage of the fundamental laws governing the behavior of individual elementary particles, promises to revolutionize the way information is processed. Todays computers process data by manipulating digital bitsunits of information represented by zeros and ones. Quantum computers use quantum bits, or qubits, which can exist in a state of being a zero and a one simultaneously. By holding information in multiple states at once, quantum computers can perform calculations that even todays largest supercomputers cant handle.

Quantum computers will be able to do calculations in minutes that would take classical computers centuries to perform, said Leonard Kahn, chair of the URI Department of Physics. Thats going to enable us to tackle problems that we simply cannot do today.

The technology remains in its infancy, however. There are only a limited number of working quantum computers in the world today, and scientists are working to scale these systems up. Giving URI students and faculty access to IBMs quantum systems will be a boon for student education and faculty research, Kahn says.

In 2021, URI launched a five-year program that graduates students with a bachelors degree in physics and a masters in quantum computing. This year, the University added an online graduate certificate program.

Our students are going to graduate having actually worked on a quantum computer, Kahn said. Thats not something many programs can say right now, and it gives our students a tremendous advantage.

First-hand access to quantum systems will also be useful for faculty like physics professors Vanita Srinivasa and Wenchao Ge, who are working on making quantum computers scalable and more robust. For other researchers on campus, this will be a chance to familiarize themselves with a technology that promises to revolutionize fields from business to environmental science.

This isnt just about computational speed, said Paula Bontempi, dean of the Graduate School of Oceanography. Its about having the ability to model complex systems like Narragansett Bay, or the North Atlantic Ocean. If we want to understand the impacts of climate change, we have to take in all of the observational data that we collect and do the calculations that allow us to predict what the future ocean looks like. Thats where quantum computing comes into play.

Access to the IBM system will also enable a new research partnership between URI and the Naval Undersea Warfare Center. That project will support research into the use of quantum systems in the operation of autonomous underwater vehicles.

Educating the quantum workforce

The initiative will also help URI to expand its research and teaching capacity. The University plans to add four new visiting faculty, four postdoctoral researchers and four graduate teaching assistants in the coming years. The new faculty and students will help manage the expansion of URIs quantum degree programs.

The expansion comes at a critical time, Kahn says.

The capacity of quantum computers is doubling roughly every six months, Kahn said. That means that students who are in high school now are likely to be graduating from college when quantum computers begin to have wider applicability. Now is the time to start educating the workforce that will be using this technology.

URI faculty will also work with a nonprofit group called Qubit by Qubit to provide outreach to high school students around Rhode Island. The outreach will include scholarships for high school students to participate in summer workshops and research internships with URI faculty on the Kingston Campus.

Jen Riley, dean of the College of Arts and Sciences, said that the initiative helps to bolster both the research and educational missions of the college.

One of our goals in the College of Arts and Sciences is to prepare students not only for todays job market, but also for jobs that are sure to exist in the future, Riley said. This initiative is an example of how we do that. Were making sure our students already have experience with quantum systems the day they come online, and helps position URI as a leader in this emerging technology.

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URI announces new quantum computing initiative on World ... - University of Rhode Island

Quantum computing is a coming technology thats likely to revolutionize what we can do, and even what we can imagine doing with computers. And the keys to the power of quantum computing are qubits.

But what exactly are qubits, and how do they power the quantum computing revolution?

In classical computers, the units of encoding are bits the binary 0s and 1s with which were familiar. A collection of 8 bits can render you any single number between 0-255.

That in itself is pretty impressive, and its always been the way we measure computer encoding in the modern era, so weve grown up, generation after generation, understanding that it was the way things were done, even as speeds increased and processing power doubled and redoubled, as chips grew faster and more effective.

The cloud changed the way we thought about computing, particularly in storage space and speed, but even there, there has been no fundamental change in the way that data is encoded.

Strap in the next bit is necessarily complicated, because it brings quantum physics to the party of data encoding.

Quantum scientists study the world of the infinitesimally small particles of matter, and the forces that operate on them. The thing to understand about that is that in the world of very small objects, forces often work in very different ways than they do in the macro-universe of comparatively large objects the things we can see, feel, and touch in what we (bless our naivety) think of as the real world.

In the world of quantum physics, things get unexpectedly freaky. Objects at that scale behave in strange ways, and two of those ways are key to understanding qubits in quantum computing.

Quantum superposition is the kind of thing that makes no sense in the macro-universe. It occurs where a quantum element, whether its the spin of an electron or the orientation of a proton, can be in two quantum states simultaneously.

In quantum physics, for instance, an electron can be both a particle and a wave at the same time. In the macro-universe of course, that would normally be absurd a fact pointed out by quantum physicist Erwin Schrdinger when he invented the thought experiment known as Schrdingers Cat. Schrdingers Cat puts forward the idea that you put a cat in a sealed box with a flask of poison, a source of radioactivity and a Geiger counter. If a single atom in the radioactive source decays, the flask of poison shatters, and the cat dies. If theres no decay, no flask shatters, and the cat lives to claw your face off when you finally release it.

Until you open the box, the cat is theoretically both alive and dead simultaneously.

So far, so fun, so reportable to the ASPCA. But what does any of that have to do with qubits in quantum computing right?

Qubits are what are also known as quantum bits. Unless you want to learn about orthogonal x and y-basis states, lets say that qubits in quantum computing act like electrons in quantum physics, and can have multiple values at the same time.

Take a moment with that, were about to hit you with the second way in which qubits harness the principles of quantum physics.

Quantum entanglement is a phenomenon in quantum physics, where groups of particles are generated and interact in such a way that they can only be described with reference to one another.

Add the two phenomena together in a qubit (which is ultimately a storage medium that represents a two-basis quantum state seriously, dont get us started on x and y-basis orthogonals, youll never sleep again), and what you have is a unit of storage that is faster than a quantum bullet.

For instance, remember that with the 0s and 1s of traditional binary-based computers, 8 bits could get you any number between 0-255?

With a qubit, you can get every number between 0-255 at the same time.

That means, for instance, that if were looking at bits and qubits as equals, single units of storage on different systems, that a qubit gets you 255 times as much data per second as a bit can deliver.

Multiply that effect by the kind of numbers of bits in a modern computer, and what you have is an insanely fast, insanely powerful machine, the like of which weve never seen before.

Thats going to be important, because just as were about to enter the age of quantum computing, powered by qubits, we have other transformational technologies coming to fruition that happen to need insanely fast, insanely powerful machines to make the most of them.

Everybodys heard of AI (Artificial Intelligence) and machine learning is an integral technology that powers the algorithms on which it depends. Those technologies are already making staggering differences to the world medical breakthroughs, the digital transformation of the business world, enhanced imaging for everything from self-driving cars to long-range telescopes, and much, much more.

Theyre managing that with standard, bit-based computing technology. Imagine those technologies on a never-ending shot of ultra-espresso, and youre not even halfway to understanding how transformational the power of quantum computing will be to AI and machine learning capabilities.

Theres a potential dark side to the power of quantum computing it will be able to crack most of the cryptography on which our cybersecurity is built in the blink of an electronic eye. But there are already efforts in play to establish standards of post-quantum cryptography, that will render it safe to use and free its users to maximize the potential of the qubits that will drive quantum computing forever forward until the next quantum leap dares to overtake it.

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Quantum computing qubits and why they matter - TechHQ

Anta Lamas Linares in Austin, Texas where Amazon Web Services has a technology complex.AWS

Anta Lamas Linares, 47, was born in Santiago de Compostela, in northwestern Spain. There she studied physics before going on to study at Oxford University and in California. Later she ended up in Singapore, leading the Amazon Web Services (AWS) Center for Quantum Networking.

In recent years she has dedicated herself to quantum computing, a field of study that is still in its infancy but promises to deliver unimaginable computational power (see box below).

Question. What is Amazon Web Services (AWS) doing in the race for quantum computing?

Answer. Since 2019, weve had a service called Amazon Braket. It allows anyone to submit a program and run it on a quantum computer in the cloud. Were also building a quantum computer at the Caltech (California Institute of Technology) campus. The latest initiative we have in the area of quantum information is the Boston-based center for quantum networks (the AWS Center for Quantum Networking).

Q. What network are you responsible for at AWS?

A. Were building the elements that allow quantum computers to be connected, kind of like a repeater to connect them over a long distance, or the quantum memories that are needed in the intermediate components. We develop the necessary hardware and software for when quantum computers will be up and running.

Q. Why is AWS entering this sector?

A. We believe theres a lot of potential in quantum technology. Amazon always thinks about whats going to be useful for its customers, even if its in the long-term. Computing, networking and other types of quantum technologies are expected to be very important in the future. Its basically an extension of the processors that do high performance computing, but in certain areas, its even more powerful. Quantum networks have immediate security implications and will eventually allow quantum computers to be connected to expand their capacity. Quantum networks will allow us to implement amazing capabilities

Q. Is a quantum internet possible?

A. Thats what were hoping for. It will be [possible] when all the capabilities of the quantum network are available. But there are several intermediate stages. The first [consists of] security and cryptography. Later, these networks will allow us to implement amazing capabilities, such as blind quantum computing, which basically [ensures that] no one can see what program youre running or see the results. In this way, if youre connected to the quantum computer with a quantum network, youre able to do the whole operation in a completely private way. But all this has many intermediate steps: we must have a quantum computer capable of doing these computations. At the moment, this doesnt exist. The [computers] that exist now are very basic; that is, they dont have many qubits and have a number of errors that dont allow several operations to be carried out in a row.

Q. What are the [quantum computers] available on AWS being used for?

A. There are several categories of users: a large part are academic researchers testing programs and comparing how they run on an ion-based quantum computer, or on a superconductor-based quantum computer. Then theres another group made up of researchers in the industry. For example, BMW uses [the computers] to optimize processes for a problem they could solve with supercomputers, but they reduce that problem to a simpler version and explore and learn.

Q. When will there be a robust and error-tolerant quantum computer?

A. We believe that, in 10 years, there will be quantum computers with interesting capabilities, but the possibility of error in that prediction is enormous. We may have a discovery tomorrow and speed it up by five years, or run into a roadblock that slows it down. In parallel, were developing the infrastructure to connect [the quantum computers] to each other and to the user. When we have that quantum network, all those capabilities that are now purely theoretical will be enabled.

Q. Will quantum computing ever be accessible without quantum knowledge?

A. Almost certainly, yes. If you think about how classical computing developed, early on, programmers had to understand circuitry. Now, in quantum computing, were still in that period the programmers are often physicists who know whats behind it. But in a few years, all of that will be just another programming language. Its still unknown what exactly the impact of quantum computing will be. Not all the possibilities are understood, nor is the effect of the intersection with artificial intelligence. In 1943, the president of IBM, Thomas J. Watson, said that he believed there was a market for five computers in the world. And now, as you can see, we all have a computer in our pocket. Companies like Amazon and others see the quantum potential, although we all recognize that this will be in the long-term.

Q. The technology world is suffering a wave of job cuts. Will this affect the development of quantum computing?

A. Investments in quantum technology are very long-term. Thats not to say that were immune to the general macroeconomic situation.

In conventional computing, a bit is the basic unit of information. A bit is binary in that it can only have one of two values: 0 or 1. Combinations of bits can provide computers with extraordinary capabilities, but in quantum computing, the basic unit is the quantum bit, or qubit. Its a quantum system that can have one of two states (0 and 1), or any superposition of these states. Superposition is the ability of a quantum system to be in multiple states at the same time until it is measured. The use of qubits allows trillions of bit combinations and therefore infinite computing possibilities. According to CSIC researcher Alberto Casas, A quantum computer of 273 qubits will have more memory than there are atoms in the observable universe.

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Anta Lamas, physicist: In a few years, quantum computing will simply be another programming language - EL PAS USA

The EY organization and IBM (NYSE: IBM) today announced that EY Global Services Limited will be joining the IBM Quantum Network, further enabling EY teams to explore solutions with IBM that could help resolve some of today's most complex business challenges. The EY organization will gain access to IBM's fleet of quantum computers over the cloud, and will become part of the IBM Quantum Network's community of organizations working to advance quantum computing.

Quantum computing is a rapidly emerging technology that harnesses the laws of quantum mechanics to solve problems that today's most powerful supercomputers cannot practically solve. EY teams will leverage their access to the world's largest fleet of quantum computers to explore solutions to enterprise challenges across finance, oil and gas, healthcare, and government.

The EY organization established its own Global Quantum Lab last year with a mission to harness quantum value in the domains of trust, transformation and sustainability. Using IBM quantum technology, EY teams plan to conduct leading-class practice research to uncover transformative use cases, including: the reduction of CO2 emissions from classical computing, the improvement of safety and accuracy of self-driving cars, and most critically, integrate quantum benefits into organizations' mainstream systems for data processing and enterprise decision making.

Andy Baldwin , EY Global Managing Partner Client Service, says:

"Quantum, in terms of importance to business, society and the EY organization, is akin to what AI represented years ago. This alliance puts the EY organization at the forefront of technology. As we invest in this level of quantum computing access, we accelerate our own position and depth of knowledge and capabilities in this space and deepen the rich relationship with our IBM alliance teams."

Jeff Wong , EY Global Chief Innovation Officer, says:

"As we navigate this period of technology-led change, which is accelerating at unprecedented speed, companies must have a full understanding of how to maximize breakthrough innovations in order to keep pace. Through this collaboration with IBM, the EY organization will now have the ability to take advantage of quantum computing to propel its innovation journey."

Jay Gambetta , Vice President IBM Quantum, says:

"IBM's vision is to deliver useful quantum computing to the world. We value partners like the EY organization that can introduce the emerging technology to a wide ecosystem of public and private industry. This will help EY facilitate the exploration of quantum computing's potential for use cases that matter in its industry."

Membership in the IBM Quantum Network is part of a broader effort by the EY organization to invest and develop robust capabilities in emerging technologies, which already include artificial intelligence, blockchain, and metaverse development. Beyond the increased investment of the EY-IBM Alliance, the EY organization is investing $10 billion in technology initiatives over three years, including investment in the organization's own quantum function.

More information on the EY-IBM Alliance, here .

About EY

EY exists to build a better working world, helping to create long-term value for clients, people and society and build trust in the capital markets.

Enabled by data and technology, diverse EY teams in over 150 countries provide trust through assurance and help clients grow, transform and operate.

Working across assurance, consulting, law, strategy, tax and transactions, EY teams ask better questions to find new answers for the complex issues facing our world today.

EY refers to the global organization, and may refer to one or more, of the member firms of Ernst & Young Global Limited, each of which is a separate legal entity. Ernst & Young Global Limited, a UK company limited by guarantee, does not provide services to clients. Information about how EY collects and uses personal data and a description of the rights individuals have under data protection legislation are available via ey.com/privacy. EY member firms do not practice law where prohibited by local laws. For more information about our organization, please visit ey.com.

This news release has been issued by EYGM Limited, a member of the global EY organization that also does not provide any services to clients.

About IBM

IBM is a leading global hybrid cloud and AI, and business services provider, helping clients in more than 175 countries capitalize on insights from their data, streamline business processes, reduce costs and gain the competitive edge in their industries. Nearly 3,800 government and corporate entities in critical infrastructure areas such as financial services, telecommunications and healthcare rely on IBM's hybrid cloud platform and Red Hat OpenShift to affect their digital transformations quickly, efficiently, and securely. IBM's breakthrough innovations in AI, quantum computing, industry-specific cloud solutions and business services deliver open and flexible options to our clients. All of this is backed by IBM's legendary commitment to trust, transparency, responsibility, inclusivity, and service. For more information, visit https://www.ibm.com/quantum

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