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ORLANDO, August 22, 2023 Quantum computing, which can enable advances in technologies including artificial intelligence and virtual reality, is coming in the near future, said a representative from Chattanooga, Tennessees smart city provider during a Fiber Connect address Tuesday.

Quantum computing refers to the technology that uses principles of physics to solve complex problems not solvable by computers. According to Jim Ingraham, representative for EPB, the provider of energy and connectivity for smart city in Chattanooga, Tennessee, quantum computing is the new future. Technology is evolving, is real and is well-invested, he said, claiming that it behooves the industry to be aware of coming demands on broadband networks because of it.

Networks need to be more resilient, reliable and flexible for coming adoptions, stated Ingraham. Networks have to be clean, affordable and implement advanced computing on a fiber system.

The rate of innovation and adoption is accelerating, there is no doubt about that, said Ingraham. It is happening more rapidly, rapidly, rapidly. Already, quantum computers are available, and innovators are continuing to improve their processes, he continued.

Right behind [quantum computers] is coming a quantum network, said Ingraham. It will take time. Quantum internet will evolve we will stop talking about kilobits, megabits, even gigabits. We will start talking about qubits. Qubits process data not in a linear way, but instantaneously, he explained.

Thus, quantum computing can make unimaginable applications possible for the future, he said. He predicted that virtual reality will evolve to become a 360-degree, holographic-based world in which virtual reality blends seamlessly with reality. it will not be an equipment based system, he said, referring to new virtual reality headsets released earlier this year by Apple.

Chattanooga, Tennessee is considered by some as the countrys best connected smart city when it became the first U.S. city to offer fiber internet through EPBs fiber network. EPB announced in November its partnership with Qubitekk, a provider of quantum optic-based cybersecurity solutions, to launch the nations first commercially available quantum network.

Quantum networks, like traditional networks, transmit information between nodes. Instead of sending classical bits, however, quantum networks send quantum bits or qubits each of which is comprised of a single photon. Unlike the classical binary bit, which is limited to a 1 or a 0, a qubit has unlimited values.

Today we have what we believe to be the countrys first quantum communications network that is commercial, said Ingraham. We believe that this can be an engine for innovation in this new quantum world.

He added that total annual quantum start-up investment hit the highest level of all time in 2022 at $2.4 billion, though it only grew one percent year over year.

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Artificial Intelligence-Enhancing Quantum Computing Coming in ... - BroadbandBreakfast.com

U.S (New York)-Europe Quantum Computing MarketReport gives evaluation and insights primarily based on authentic consultations with necessary gamers such as CEOs, Managers, Department Heads of Suppliers, Manufacturers, and Distributors etc.

Europe quantum computing market was valued at $257.5 million in 2021 and will grow by 27.2% annually over 2021-2031,driven by the need for secure communication and digitization, an emergence of advance applications and early adoption of quantum computers in some industries, increased investment in quantum computing technology, and the rise of numerous strategic partnerships and collaborations among key vendors. Highlighted with 36 tables and 67 figures, this 131-page report Europe Quantum Computing Market 2021-2031 by Component (Hardware, Software, Services), Technology (Superconducting Qubits, Trapped Ion, Quantum Cryptography, Quantum Annealing, Topological and Photonic), Deployment, Application (ML, Optimization, Simulation), Industry Vertical, and Country: Trend Forecast and Growth Opportunity is based on a comprehensive research of the entire Europe quantum computing market and all its sub-segments through extensively detailed classifications.

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Profound analysis and assessment are generated from premium primary and secondary information sources with inputs derived from industry professionals across the value chain. The report is based on studies on 2019-2021 and provides forecast from 2022 till 2031 with 2021 as the base year. (Please note: The report will be updated before delivery so that the latest historical year is the base year and the forecast covers at least 5 years over the base year.)

In-depth qualitative analyses include identification and investigation of the following aspects: Market Structure Growth Drivers Restraints and Challenges Emerging Product Trends & Market Opportunities Porters Fiver Forces

The trend and outlook of global market is forecast in optimistic, balanced, and conservative view by taking into account of COVID-19 and Russia-Ukraine conflict. The balanced (most likely) projection is used to quantify quantum computing market in every aspect of the classification from perspectives of Component, Technology, Deployment, Application, Industry Vertical, and Region.

Selected Key Players: 1QB Information Technologies Inc. Accenture Plc. Amazon Web Services, Inc. Anyon Systems, Inc. Atos SE Cambridge Quantum Computing Ltd. ColdQuanta, Inc. D-Wave Systems Inc. Google LLC by Alphabet Inc. Honeywell International Inc. IBM Corporation Intel Corporation IonQ Inc. ISARA Corporation Microsoft Corporation QC Ware Corp. Quantum Circuits, Inc. Rigetti & Co, Inc. River Lane Research Xanadu Quantum Technologies Inc. Zapata Computing, Inc.

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Based on Component Hardware o Quantum Computers o Programmed Infrastructure Software o Simulation o Optimization o Machine Learning o Sampling and Others Services o Professional Services ? Deployment and Installation ? Infrastructure Maintenance ? Consulting and Education o Managed Services

Based on Technology Superconducting Qubits Trapped Ion Quantum Cryptography Quantum Annealing Topological and Photonic

By Deployment On-premises Deployment Cloud-based Deployment

By Application Machine Learning (ML) Quantum Optimization Quantum Simulation Quantum Finance Quantum Chemistry Other Applications

By Industry Vertical Pharmaceutical and Healthcare BFSI Government and Public Services Aerospace and Defense Energy & Utilities Automotive and Transportation Chemical Industry IT and Telecom Manufacturing Industry Cybersecurity Media and Entertainment Other Industry Verticals

Geographically Germany UK France Spain Italy Netherlands Rest of Europe (further segmented into Russia, Switzerland, Poland, Sweden, Belgium, Austria, Ireland, Norway, Denmark, and Finland))

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Europe Quantum Computing Market Size and Overview Analysis ... - The Knox Student

The Enchilada Trap, manufactured in Sandia National Laboratories Microsystems Engineering, Science and Applications fabrication facility. Credit: Craig Fritz, Sandia National Laboratories

Sandia National Laboratories has produced its first lot of a new world-class ion trap, a central component for certain quantum computers. This innovative device, termed the Enchilada Trap, enables researchers to construct more powerful machines, propelling the experimental yet groundbreaking realm of quantum computing forward.

In addition to traps operated at Sandia, several traps will be used at Duke University for performing quantum algorithms. Duke and Sandia are research partners through the Quantum Systems Accelerator, one of five U.S. National Quantum Information Science Research Centers funded by the Department of Energys Office of Science.

An ion trap is a type of microchip that holds electrically charged atoms, or ions. With more trapped ions, or qubits, a quantum computer can run more complex algorithms.

Jonathan Sterk points to the section of an ion trap trapped ion qubits travel in a close-up view of the trap inside a vacuum chamber at Sandia National Laboratories. Credit: Craig Fritz, Sandia National Laboratories

With sufficient control hardware, the Enchilada Trap could store and transport up to 200 qubits using a network of five trapping zones inspired by its predecessor, the Roadrunner Trap. Both versions are produced at Sandias Microsystems Engineering, Science, and Applications fabrication facility.

According to Daniel Stick, a Sandia scientist and leading researcher with the Quantum Systems Accelerator, a quantum computer with up to 200 qubits and current error rates will not outperform a conventional computer for solving useful problems. However, it will enable researchers to test an architecture with many qubits that in the future will support more sophisticated quantum algorithms for physics, chemistry, data science, materials science, and other areas.

We are providing the field of quantum computing room to grow and explore larger machines and more complicated programming, Stick said.

Sandia National Laboratories electrical engineer Ray Haltli optimizes parameters before placing gold wire bonds on an ion trap. When ready, the machine runs automatically, placing up to seven wires per second. Credit: Craig Fritz, Sandia National Laboratories

Sandia has researched, built, and tested ion traps for 20 years. To overcome a series of design challenges, the team combined institutional knowledge with new innovations.

For one, they needed space to hold more ions and a way to rearrange them for complex calculations. The solution was a network of electrodes that branches out similar to a family tree or tournament bracket. Each narrow branch serves as a place to store and shuttle ions.

Sandia had experimented with similar junctions in previous traps. The Enchilada Trap uses the same design in a tiled way so it can explore scaling properties of a smaller trap. Stick believes the branching architecture is currently the best solution for rearranging trapped ion qubits and anticipates that future, even larger versions of the trap will feature a similar design.

Another concern was the dissipation of electrical power on the Enchilada Trap, which could generate significant heat, leading to increased outgassing from surfaces, a higher risk of electrical breakdown, and elevated levels of electrical field noise. To address this issue, production specialists designed new microscopic features to reduce the capacitance of certain electrodes.

Our team is always looking ahead, said Sandias Zach Meinelt, the lead integrator on the project. We collaborate with scientists and engineers to learn about the kind of technology, features, and performance improvements they will need in the coming years. We then design and fabricate traps to meet those requirements and constantly seek ways to further improve.

The research was funded by the US Department of Energy.

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The Enchilada Trap: New Device Paves the Way for Bigger and ... - SciTechDaily

As society becomes increasingly data driven, theres a growing need for computers that can keep pace with the swelling tide of information as well as computers that can explore topics that arent answerable with traditional computers, such as problems that cant be reduced to yes or no.

With their ability to process large amounts of data at rapid speeds, as well as handle greater levels of ambiguity, quantum computers are seen as a solution. But a quantum computer is only as good as its quantum bits or qubits the individual, short-lived particles that store information for processing. A qubit that lasts longer provides greater computational capacity.

Ph.D. student Joseph Soruco examines part of the ultra-high vacuum chamber in the lab of Ruihua Cheng at the School of Science at IUPUI. Photo by Justin Casterline, Indiana University

This quest to build a better qubit is central to the research of Ruihua Cheng, an associate professor in the Department of Physics in the School of Science at IUPUI. Her work is supported by the Center for Quantum Technologies, a National Science Foundation-supported collaboration between IU, Purdue and Notre Dame. As a part of the center, she and her students are working to understand a special type of molecule known as a spin crossover molecule that could hold significant advantages over other candidates currently used as qubits.

Announced in 2021, the Center for Quantum Technologies is supported by the NSFs Industry-University Cooperative Research program, in which public and private organizations cooperate to advance the work of scientists in a wide range of areas. There are over 80 of these programs in the United States, but the Center for Quantum Technologies is the only center specifically focused on quantum science and technology, according to Ricardo Decca, professor and chair of the Department of Physics at the School of Science at IUPUI, who helped lead the centers establishment in Indiana.

Other members of the Center for Quantum Technologies include the Air Force Research Laboratory, Cummins Inc, Eli Lilly and Co., Hewlett Packard, IBM, Intel, Northrup Grumman and Naval Surface Warfare Center-Crane. Non-academic members who sponsor research projects under the program are granted early access to findings applicable to their organizations.

Corporations are interested in quantum computers due to their potential for complex tasks that arent suited to traditional computers, Cheng said, including modeling complex systems such as human cells; powering artificial intelligence; and protecting personal data with cryptographic algorithms.

Ph.D. student Ashley Dale opens the ultra-high vacuum chamber in the lab. Photo by Justin Casterline, Indiana University

For example, she said, a pharmaceutical company might want to rapidly explore the effect of hundreds of thousands of chemical compounds on a molecular pathway related to a specific disease. A quantum computer could not only provide the computational power to quickly simulate the effect of all of these molecules in a cell, but also be better equipped to handle gray areas in the simulation where a programmer cant provide the exact result of every possible chemical interaction.

A quantum computer has the ability to model ambiguity because quantum bits can be understood to exist in multiple states simultaneously. Scientists can exploit this property to represent more than one outcome at the same time, with different probabilities assigned to each state. The result is a computer that can quickly explore a wide range of potential outcomes.

In February, the Center for Quantum Technologies convened its first meeting of all participating partners to review project proposals. Cheng is a part of two of the seven selected first-round projects, with both leveraging her work on spin crossover molecules, supported under several NSF grants.

Spin is one of the properties of an electron that can be controlled or manipulated in different ways for the purposes of quantum computing, she said. Our work focuses on using electric voltage or electric fields to manipulate the spin in these molecules, which is a novel approach that suggests several potential advantages in quantum computing, including low power consumption and long coherence time.

Coherence refers to the amount of time spin crossover molecules are useful as qubits.

The longer the coherence time, the longer you can preserve information for manipulation, Cheng said.

These times are on the scale of microseconds, milliseconds or longer, she added. Thats 100 to 1,000 times longer than some other materials currently used as qubits. The fact that these time differences are significant despite their relatively short length is a testament to these qubits power compared to semiconductor-based qubits, she said.

The ultra-high vacuum chamber is used as part of experiments that use electric voltages or electric fields to manipulate spin-crossover molecules. Photo by Justin Casterline, Indiana University

To run their experiments, Chengs lab uses spin crossover molecules produced at the Lawrence Berkeley National Laboratory in California, which are synthesized in powder form for safe transport. To manipulate and study the spin in the molecules, Chengs students use a variety of highly specialized machines, including equipment at IUPUIs Integrated Nanosystems Development Institute. She also sends students to Berkeley to conduct experiments on site.

Jared Phillips, a Ph.D. student in Chengs lab, has twice traveled to the facility at Berkeley, as well as collected data remotely. Based on the significance of his research, Phillips was honored for the best students research poster at the American Vacuum Society 68th International Symposium in November.

As a part of the Center for Quantum Technologies, Chengs research does not occur in isolation; she is working with other center colleagues to gain a more comprehensive understanding of these molecules. Collaborating researchers include Jing Liu at the School of Science at IUPUI, who will study the optical properties of the molecules behavior, and Babak Anasori at the School of Engineering and Technology at IUPUI, who provides special 2D materials used as a foundation for the molecules. IU Bloomington, Purdue and Notre Dame researchers are also a part of the projects.

As a collaboration across academia and industry, Decca said the Center for Quantum Technologies is designed to not only facilitate this type of cross-institutional collaboration a strength of academia but also leverage the private sectors focus on rapid innovation. Each month the lead researcher on each project meets with the centers industry partners to incorporate their feedback into the teams work.

Theres also a workforce development aspect to the CQT, Decca said, noting that students who participate in research projects funded through the center graduate with high-tech skills tailored to the interest of the participating partners. Theres high potential for students to jump straight into these industries upon graduation.

In addition to monthly meetings, a full meeting of the centers partners occurs twice a year. The next of these meetings, which are open to the public, will take place on the IUPUI campus in October.

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Improving quantum computing through quest to 'build a better qubit' - IU Newsroom

Quantum computing and generativeAI stockshave investors very interested at the moment due to their innovation and being on the cutting edge of technological capabilities; investors see the massive growth potential with all these reasonably new technology companies. Some of the largest companies have dedicated quantum computing segments to their business, including Microsoft (NASDAQ:MSFT), Amazon (NASDAQ:AMZN), and Alphabet (NASDAQ:GOOGL). This has led to the rise of cheap quantum computing stocks.

Quantum computing helps to develop much more efficient methods of problem-solving than normal computing using quantum mechanics. Below I will discuss three companies that focus heavily on quantum computing that provide upside potential for investors looking for cheap companies to get into before its too late.

Source: Amin Van / Shutterstock.com

IonQ (NYSE:IONQ), headquartered in College Park, Maryland, is a company that produces quantum computing systems. They are the only company to provide quantum computing technology through the cloud on Amazon Web Services, Google Cloud, and Microsoft Azure. Their product list includes the IONQ Harmony, created in 2020; IONQ Aria, created in 2022; and IONQ Forte, predicted to be released later this year. They all offer a wide range of quantum computing capabilities through the cloud. All in all, its one of those cheap quantum computing stocks to consider.

IONQ has been one of the most famousquantum computing stockslately. The companys share price is up 474% year-to-date. This is due to a number of factors, one being that they recently signed a contract with the South Korean Ministry of Science to help promote their quantum computing ecosystem.

The company also stated in June that bookings for the year 2023 are projected to double from the year before, within a range of $45-55 million.All eyes will be on their following earnings report, which is expected to be released on August 10.

Source: Shutterstock

Quantum Computing(NASDAQ:QUBT), located in Leesburg, Virginia, is a company that provides quantum computing processing units such as the Entropy Quantum Computer and software called Qatalyst, which is a cloud-based service that helps optimize quantum computing. Their services are used by other quantum computing companies, such as IONQ,Rigetti Computing (NASDAQ:RGTI), and government agencies. This means its one of those cheap quantum computing stocks that you should buy today.

In the last month, the companys share price has increased by 2% year-to-date and is up 20% over the previous month.On July 13, Quantum Computing was given a subcontract through the Bay Area Environmental Research Institute (BAERI) to help support NASA Ames. This photonic sensor instrument measures atmospheric particles. This is their third NASA subcontract.

Last month the company also launched its new Quantum Photonic Vibrometer, an instrument that helps detect remote vibrations and allows inspecting objects from great distances. The company stated in its most recent earnings release that total revenue nearly quadrupled to $121 thousand, and its net loss expanded to $8.5 million compared to the year before.

Source: Gorodenkoff/Shutterstock.com

D-Wave Quantum(NYSE:QBTS) is a Canadian-based company that provides quantum computing software and services. They offer multiple different products such as Advantage, which is their flagship quantum computer, Leap, which is a cloud computing software; and Ocean which uses open-source Python tools.

D-Wave released a preliminary report for second-quarter revenue and bookings on July 20. with revenue expected to come in anywhere between $1.65 million to $1.8 million, and total booking for the company rose by over 146% compared to the year before.

Year-to-date, the companys share price has risen by 88%. On July 27, D-Wave Systems announced a collaboration with the Institute of Quantum Computing (IQC) in Waterloo, Ontario, to establish a more robust quantum computing research program.And on August 1, the company announced a time change to its second-quarter earnings report release, which was moved from after market close on August 10 to before market open on August 10.Following this news, its stock price surged by 29% by the end of the day.

On the date of publication, Noah Boltondid not have (either directly or indirectly) any positions in the securities mentioned in this article.The opinions expressed in this article are those of the writer, subject to the InvestorPlace.comPublishing Guidelines.

Noah has about a year of freelance writing experience. Hes worked with Investopedia dealing with topics such as the stock market and financial news.

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3 Cheap Quantum Computing Stocks That Smart Investors Will Snap Up Now - InvestorPlace