Cloud Hosting

Insight must precede application. ~ Max Planck, Father of Quantum Physics

Quantum computing is no ordinary technology. It has attracted huge interest at the national level with funding from governments. Today, some of the biggest technology giants are working on the technology, investing substantial sums into research and development and collaborating with state agencies and corporates for various projects across industries.

Heres an overview of quantum computing as well as the players exploring this revolutionary technology, and ways to invest in it.

Understanding Quantum Computing

Lets begin with understanding quantum computing. While standard computers are built on classical bits, every quantum computer has a qubit or quantum bit as its building block. Thus, unlike a classical computer where information is stored as binary 0 or 1 using bits, a quantum computer harnesses the unique ability of subatomic participles in the form of a qubit which can exist in superposition of 0 and 1 at the same time.As a result, quantum computers can achieve higher information density and handle very complex operations at speeds exponentially higher than conventional computers while consuming much lessenergy.

It is believed that quantum computing will have a huge impact on areas such as logistics, military affairs, pharmaceuticals (drug design and discovery), aerospace (designing), utilities (nuclear fusion), financial modeling, chemicals (polymer design), Artificial Intelligence (AI), cybersecurity, fault detection, Big Data, and capital goods, especially digital manufacturing. The productivity gains by end users of quantum computing, in the form of both cost savings and revenue opportunities, are expected to surpass $450 billion annually.

It will be a slow build for the next few years: we anticipate value for end users in these sectors to reach a relatively modest $2 billion to $5 billion by 2024. But value will then increase rapidly as the technology and its commercial viability mature,reportsBCG.

The market for quantum computing isprojectedto reach $64.98 billion by 2030 from just $507.1 million in 2019, growing at aCAGR of 56.0%during the forecast period (20202030).According to aCIRestimate, revenue from quantum computing is pegged at $8 billion by 2027.

Which Nations Are Investing In Quantum Computing?

To gain the quantum advantage, China has been at the forefront of the technology. The first quantum satellite was launched by China in 2016. Apaperby The Center for a New American Security (CNAS) highlights how, China is positioning itself as a powerhouse in quantum science.

Understanding the strategic potential that quantum science holds, U.S., Germany, Russia, India and European Union have intensified efforts towards quantum computing. In the U.S., President Trumpestablishedthe National Quantum Initiative Advisory Committee in 2019 in accordance with the National Quantum Initiative Act, signed into law in late 2018, which authorizes $1.2 billion to be spent on the quantum science over the next five years.

The Indian government in its 2020 budget has announced a National Mission on Quantum Technologies & Applications with a total budgetoutlayof INR 8000 crore ($1.12 billion) for a period of five years while Europe has a 1 billioninitiativeproviding funding for the entire quantum value chain over the next ten years. In October 2019, the first prototype of a quantum computer waslaunchedin Russia while in Germany, the Fraunhofer-Gesellschaft, Europes leading organization for applied research,partneredwith IBM for advance research in the field of quantum computing.

The Companies Leading the Way

IBM has been one of the pioneers in the field of quantum computing. In January 2019, IBM (IBM)unveiledthe IBM Q System One, the world's first integrated universal approximatequantum computing system designed for scientific and commercial use. In September itopenedthe IBM quantum computation center in New York to expand its quantum computing systems for commercial and research activity. It has also recentlyinvestedin Cambridge Quantum Computing, which was one of the first startups to become a part of IBMs Q Network in 2018.

In October 2019, Google (GOOG,GOOGL) made anannouncementclaiming the achievement of "quantum supremacy."It published the results of this quantum supremacy experiment in theNaturearticle, Quantum Supremacy Using a Programmable Superconducting Processor.The term "quantum supremacy" wascoinedin 2012 by John Preskill. He wrote, one way to achieve quantum supremacy would be to run an algorithm on a quantum computer which solves a problem with a super-polynomial speedup relative to classical computers. The claim wascounteredby IBM.

Vancouver, Canada headquartered D-Wave is the worlds first commercial supplier of quantum computers and its systems are being used by organizations such as NEC, Volkswagen, DENSO, Lockheed Martin, USRA, USC, Los Alamos National Laboratory and Oak Ridge National Laboratory.In February 2019, D-Waveannounceda preview of its next-generation quantum computing platform incorporating hardware, software and tools to accelerate and ease the delivery of quantum computing applications. In September 2019, itnamedits next-generation quantum system as Advantage, which will be available in the Leap quantum cloud service in mid-2020.In December 2019, the companysignedan agreement with NEC to accelerate commercial quantum computing.

Amazon (AMZN)introducedits service Amazon basket in late 2019, which is designed to let its users get some hands-on experience with qubits and quantum circuits. It allows to build and test circuits in a simulated environment and then run them on an actual quantum computer.

Around the same time, Intel (INTC)unveileda first-of-its-kind cryogenic control chip code-named Horse Ridgethat will speed up development of full-stack quantum computing systems.

In addition, companies such as Microsoft (MSFT), Alibaba (BABA), Tencent (TCEHY), Nokia (NOK), Airbus, HP (HPQ), AT&T (T) Toshiba, Mitsubishi, SK Telecom, Raytheon, Lockheed Martin, Righetti, Biogen, Volkswagen and Amgen are researching and working on applications of quantum computing.

Final Word

Investors looking to invest in the technology can either look at individual stocks or consider Defiance Quantum ETF (QTUM) to take exposure to companies developing and applying quantum computing and other advanced technologies. Launched in April 2018, QTUM is a liquid, low-cost and efficient way to invest in the technology. The ETF tracks the BlueStar Quantum and Machine Learning Index, which tracks approximately 60 globally listed stocks across all market capitalizations.

While quantum computing is not mainstream yet, the quest to harness its potential is on, and the constant progress made is shrinking the gap between research labs and real-world applications.

Disclaimer: The author has no position in any stocks mentioned. Investors shouldconsider the above information not as a de facto recommendation, but as an idea for further consideration. The report has been carefully prepared, and any exclusions or errors in reporting are unintentional.

The views and opinions expressed herein are the views and opinions of the author and do not necessarily reflect those of Nasdaq, Inc.

See original here:
Quantum Computing: How To Invest In It, And Which Companies Are Leading the Way? - Nasdaq

The concept of time crystals comes from the realm of counterintuitive mind-melding physics ideas that may actually turn out to have real-world applications. Now comes news that a paper proposes merging time crystals with topological superconductors for applications in error-free quantum computing, extremely precise timekeeping and more.

Time crystals were first proposed as hypothetical structures by the Nobel-Prize winning theoretical physicist Frank Wilczek and MIT physicists in 2012. The remarkable feature of time crystals is that they would would move without using energy. As such they would appear to break the fundamental physics law of time-translation symmetry. They would move while staying in their ground states, when they are at their lowest energy, appearing to be in a kind of perpetual motion. Wilczek offered mathematical proof that showed how atoms of crystallizing matter could regularly form repeating lattices in time, while not consuming or producing any energy.

Time crystals have since been experimentally created in various labs.

Now researchers at the California Institute of Technology (Caltech) and the Weizmann Institute in Israel found that theoretically you can create a system that combines time crystals with so-called topological superconductors.

The field of topology looks at the properties of objects that are unchangeable (or "invariant') despite deformations like stretching, twisting, or bending. In a topological insulator, the properties linked to the electron wave function would be considered topologically invariant.

As the scientists themselves explain, "Time crystals form when arbitrary physical states of a periodically driven system spontaneously break discrete time-translation symmetry." What the researchers noticed is that when they introduced "one-dimensional time-crystalline topological superconductors" they found a fascinating interaction where "time-translation symmetry breaking and topological physics intertwineyielding anomalous Floquet Majorana modes that are not possible in free-fermion systems."

Majorana fermions are particles that have their own anti-particles.

"Physicists Gil Refael and Jason Alicea explain the unique properties of electrons constrained to a 2 Dimensional world, and how they can be used to make noise-proof Quantum Computers."

The research was led by Jason Alicea and Aaron Chew from CalTech, as well as David Mross from the Weizmann Institute in Israel.

While studying Majorana fermions, the team observed that it is possible to enhance topological superconductors by coupling them to magnetic degrees of freedom that could be controlled. "Then we realized that by turning those magnetic degrees of freedom into a time crystal, topological superconductivity responds in remarkable ways," shared Alicea.

Aaron Chew (left) and David Mross (right).

Credit: Jason Alicea

One way the phenomen noticed by the scientists could be potentially exploited is to create more stable qubits - the bit of quantum information in quantum computing. The race to create qubits is at the threshold of bringing on a true quantum technology revolution, as writes Popular Mechanics.

"It's tempting to imagine generating some useful quantum operations by controlling the magnetic degrees of freedom that intertwine with the topological physics. Or perhaps certain noise channels can be suppressed by exploiting time crystals," said Alicea.

Check out their new paper in Physical Review Letters.

From Your Site Articles

Related Articles Around the Web

The rest is here:
Scientists discover how to use time crystals to power superconductors - Big Think

Moscow-Tokyo Nissan and the Quantum Machine LearningProject of the Russian Quantum Center (RQC) have announced the launch of ajoint scientific and technological project in the field of quantum computingfor chemical compound modeling solutions. In the context of partnership,Project is going to create new methods of quantum systems modeling and to testthem with the use of existing quantum processors. This project is one of thefirst commercial projects in the field of quantum computing in Russia. Theamount and terms of the contract are not disclosed by the parties.

Modeling ofcomplex systems such as materials, batteries, and medicines is extremelydifficult for existing computers. The next generation of computing devices,which are quantum computers, will be able to solve such problems moreefficiently. As a result, the business will be able to find practical solutionssuch as modeling of new materials, production of devices of a new class fromsuch materials, and selection of optimal characteristics or reactions insidethese materials, which are necessary for increasing the subsequent efficiency.One of the real challenges for the industry and business is the modeling ofchemical compounds used in the batteries manufacturing process.

As part ofthe project, we are developing quantum chemistry methods using machine learningand quantum optimization. We plan to integrate the developed methods into thematerial design system, which is used today in Nissan. This will allow Nissanto unlock the huge potential of quantum computing for its tasks, and in thefuture, to achieve technological leadership, said Alexey Fedorov, Head of the Group Quantum Information Technologies RQC,Ph.D. in Theoretical Physics.

Quantumtechnologies are promising for solving many industrial challenges. Thematerials that can be created with quantum chemistry will significantlyincrease the power and capacity of batteries. As a result, we will get theopportunity to create highly efficient and environmentally-friendly transport,as well as new solutions. The future is behind these technologies and, togetherwith our partner, Russian Quantum Center, we are striving to become a pioneerin this industry, said ShigeoIbuka, Head of Nissan R&D center in Russia, Ph.D. in Physics.

In the long term,the use of quantum technologies will significantly reduce the time for thedevelopment of new materials, as well as predict their compliance with therequirements of industry and business. The RQC team will conduct research usingboth existing quantum computers and their own-developed quantum-inspiredalgorithms.

AboutRussian Quantum Center (RQC)

The RussianQuantum Center (RQC) is a non-governmental organization specializing infundamental research in the field of quantum physics and the development ofdevices and technologies based on quantum effects. The Center was founded inDecember 2010 and became one of the first residents of the Skolkovo InnovationCenter. RQC is one of the authors of the roadmap for the development of quantumtechnologies in Russia until 2024.

At the moment,RQC has more than 150 employees, 14 laboratories, and 7 spin-offs aimed at thecommercialization of the developments. In 2017, RQC developed the worlds firstquantum blockchain. RQC technologies are being actively introduced intogovernment and business structures around the world.

RQCsQuantum Machine Learning Project

RQCs Quantum Machine Learning Project is engaged in research and business-oriented projects in the field of quantum computing. The work is carried out in several directions: development of the strategy of quantum computing application and development of the QBoard quantum computing cloud platform, SimCIM simulator based on quantum-inspired algorithms, and other solutions. Some software products are already available for commercial use.

Manager at Research Snipers, RS-NEWS, Digital marketing enthusiast and industry professional in Digital Marketing, Social Media, Business News, and Technology News, with vast experience in the media industry, I have a keen interest in business technology, News breaking.

More:
Russian Quantum Center and Nissan have launched a project in the field of quantum chemistry - Research Snipers