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A novel vortex phenomenon involving photon interactions was identified by scientists, potentially enhancing quantum computing. Through experiments with dense rubidium gas, they observed unique phase shifts that mimic other vortices but are distinct in their quantum implications. Credit: SciTechDaily.com

Researchers at the Weizmann Institute of Science discovered a new type of vortex formed by photon interactions, which could advance quantum computing.

Vortices are a widespread natural phenomenon, observable in the swirling formations of galaxies, tornadoes, and hurricanes, as well as in simpler settings like a stirring cup of tea or the water spiraling down a bathtub drain. Typically, vortices arise when a rapidly moving substance such as air or water meets a slower-moving area, creating a circular motion around a fixed axis. Essentially, vortices serve to reconcile the differences in flow speeds between adjoining regions.

A vortex ring and lines created by the influence of three photons on one another. The color describes the phase of the electric field, which completes a 360-degree rotation around the vortex core. Credit: Weizmann Institute of Science

A previously unknown type of vortex has now been discovered in a study, published in Science, conducted by Dr. Lee Drori, Dr. Bankim Chandra Das, Tomer Danino Zohar, and Dr. Gal Winer from Prof. Ofer Firstenbergs laboratory at the Weizmann Institute of Sciences Physics of Complex Systems Department. The researchers set out to look for an efficient way of using photons to process data in quantum computers and found something unexpected: They realized that in the rare event that two photons interact, they create vortices. Not only does this discovery add to the fundamental understanding of vortices, it may ultimately contribute to the studys original goal of improving data processing in quantum computing.

The interaction between photons light particles that also behave like waves is only possible in the presence of matter that serves as an intermediary. In their experiment, the researchers forced photons to interact by creating a unique environment: a 10-centimeter glass cell that was completely empty, save for rubidium atoms that were so tightly packed in the center of the container that they formed a small, dense gas cloud about 1 millimeter long. The researchers fired more and more photons through this cloud, examined their state after they had passed through it, and looked to see if they had influenced one another in any way.

When the gas cloud was at its densest and the photons were close to each other, they exerted the highest level of mutual influence.

When the photons pass through the dense gas cloud, they send a number of atoms into electronically excited states known as Rydberg states, Firstenberg explains. In these states, one of the electrons in the atom starts moving in an orbit that is 1,000 times wider than the diameter of an unexcited atom. This electron creates an electric field that influences a huge number of adjacent atoms, turning them into a kind of imaginary glass ball.

The image of a glass ball reflects the fact that the second photon present in the area cannot ignore the environment the first photon has created and, in response, it alters its speed as if it has passed through glass. So, when two photons pass relatively close to each other, they move at a different speed than they would have if each had been traveling alone. And when the speed of the photon changes, so does the position of the peaks and valleys of the wave it carries. In the optimal case for the use of photons in quantum computing, the positions of the peaks and valleys become completely inverted relative to one another, owing to the influence the photons have on each other a phenomenon known as a 180-degree phase shift.

From bottom left, clockwise: Dr. Lee Drori, Tomer Danino Zohar, Dr. Alexander Poddubny, Prof. Ofer Firstenberg, Dr. Gal Winer, Dr. Eilon Poem and Dr. Bankim Chandra Das. Credit: Weizmann Institute of Science

The direction that the research took was as unique and extraordinary as the paths of the photons in the gas cloud. The study, which also included Dr. Eilon Poem and Dr. Alexander Poddubny, began eight years ago and has seen two generations of doctoral students pass through Firstenbergs laboratory.

Over time, the Weizmann scientists managed to create a dense, ultracold gas cloud, packed with atoms. As a result, they achieved something unprecedented: photons that underwent a phase shift of 180-degrees and sometimes more. When the gas cloud was at its densest and the photons were close to each other, they exerted the highest level of mutual influence. But when the photons moved away from each other or the atomic density around them dropped, the phase shift weakened and disappeared.

The prevalent assumption was that this weakening would be a gradual process, but researchers were in for a surprise: A pair of vortices developed when two photons were a certain distance apart. In each of these vortices, the photons completed a 360-degree phase shift and, at their center there were almost no photons at all just as in the dark center we know from other vortices.

The scientists found that the presence of a single photon affected 50,000 atoms, which in turn influenced the motion of a second photon.

To understand photon vortices, think of what happens when you drag a vertically held plate through the water. The rapid movement of the water pushed by the plate meets the slower movement around it. This creates two vortices that, when viewed from above, appear to be moving together along the waters surface, but in fact, they are part of a three-dimensional configuration known as a vortex ring: The submerged part of the plate creates half a ring, which connects the two vortices visible on the surface, forcing them to move together.

Another familiar instance of vortex rings is smoke rings. In the last stages of the study, the researchers observed this phenomenon when they introduced a third photon, which added an extra dimension to the findings: The scientists discovered that the two vortices observed when measuring two photons are part of a three-dimensional vortex ring generated by the mutual influence of the three photons. These findings demonstrate just how similar the newly discovered vortices are to those known from other environments.

The vortices may have stolen the show in this study, but the researchers are continuing to work toward their goal of quantum data processing. The next stage of the study will be to fire the photons into each other and measure the phase shift of each photon separately. Depending on the strength of the phase shifts, the photons could be used as qubits the basic units of information in quantum computing. Unlike the units of regular computer memory, which can either be 0 or 1, quantum bits can represent a range of values between 0 and 1 simultaneously.

Reference: Quantum vortices of strongly interacting photons by Lee Drori, Bankim Chandra Das, Tomer Danino Zohar, Gal Winer, Eilon Poem, Alexander Poddubny and Ofer Firstenberg, 13 July 2023,Science. DOI: 10.1126/science.adh5315

Prof. Ofer Firstenbergs research is supported by the Leona M. and Harry B. Helmsley Charitable Trust, the Shimon and Golde Picker Weizmann Annual Grant and the Laboratory in Memory of Leon and Blacky Broder, Switzerland.

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Vortex Power: The Swirl of Light Revolutionizing Quantum Computing - SciTechDaily

The Nasdaq Composite, which holds a number of big-name tech stocks, experienced a bit of selling pressure last week. In particular, the index fell nearly 2%. This potentially creates an opening for savvy investors to buy up shares of stocks that appear undervalued. One growth sector worth looking into would be quantum computing. Most people by now are familiar with generative artificial intelligence (AI) technologies, such as OpenAIs ChatGPT. This led us to creating this list of undervalued quantum computing stocks.

Generative AI has already begun to change the way people work and consumer information. In a similar vein, quantum computing could very well usher in a similar era of technological innovation. This kind of computing technology relies on quantum mechanics that is, properties of subatomic to particles to calculate complex problems that classical computers have a hard time solving. Some of these problems include weather prediction and optimization problems. While quantum computing remains in its nascent phases, there are a number of public companies that have made significant contributions to field and are also trading at attractive valuations.

Below are three of them.

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International Business Machines (NYSE:IBM) is a legacy technology behemoth that started working on quantum computers in the early 2000s. The company has continued to innovate in the field since then. In 2019, IBM released the Q System One, which was a fully-integrated quantum computing system that the company had said was ready for both commercial and scientific use. Though the commercial use of the quantum computing system may had been an overstatement, the Q System One definitely served as a stepping-stone for the entire sector.

Towards the end of 2023, IBM unveiled the Q System Two, the firms first modular quantum computer that operate with three IBM Heron processors. Each of these processors are innovations in their own right, relying on 133 qubits. Outside of the hardware realm of quantum computing, IBM has also contributed to the software side of the space. The software stack Qiskit Patterns will allow quantum developers to easily create code for quantum computing purposes, while watsonx will leverage generative AI to facilitate the writing of quantum computer programs.

IBMs stock trades at 16.9x forward earnings, making it cheaper than a lot of the tech giants out there. More achievements in the field of quantum computing could create opportunities for multiple expansion for investors who decide to buy in now.

Source: Sundry Photography / Shutterstock.com

Intel (NASDAQ:INTC) has received much scrutiny over the years. Once a crown-jewel of the American semiconductor industry, the chipmaker has fallen behind rivals Nvidia (NASDAQ:NVDA) and Advanced Micro Devices (NASDAQ:AMD) in both the CPU and GPU computing chip verticals. Intel does, however, appear to have an innovative edge in terms of quantum computing. At the beginning of May, Intel unveiled cutting-edge research that could lead to the scaling of silicon-based quantum processors, which would be a major step in developing fault-tolerant quantum computers. These computational systems would be able to perform calculations with very low error rates.

Intels Tunnel Falls chip is also an important achievement in the broader space. Released to the research community, Tunnel Falls and its advanced silicon features will help edge the chipmaker further to developing a viable and commercial quantum computer.

Intels share price trades at around 24.4x forward earnings, which makes it relatively cheaper to its chip competitors, Nvidia and AMD. As Intel ramps up its manufacturing capabilities, it will definitely be a stock to watch in terms of AI and quantum computing innovations. This is easily one of the most undervalued quantum computing stocks.

Source: josefkubes / Shutterstock.com

Honeywell (NASDAQ:HON) is an industrial conglomerate that operates in the aerospace and defense industry. The firms Aerospace division, for example, develops power units, propulsion engines, electric power systems as well as engine controls, flight safety and navigation hardware. What is lesser known is Honeywells investments into the quantum computing space. As I have written in a previous article, Honeywells serious entry into the quantum computing space came through the formation of Quantinuum , which had been a merger between Honeywell Quantum Solutions and Cambridge Quantum in 2021.

Honeywell maintains majority ownership of Quantinuum and through this new business, Honeywell has been able to continue innovating in the space. Quantinuums System Model H1 is the startups first-generation quantum computing system. Leveraging Honeywells proprietary technology and research, the quantum system features 20 qubits. Similar to other quantum computing systems, researchers can harness its power via a cloud environment like Azure Quantum.

Honeywells share price trades at 20.0x forward earnings. As quantum computing becomes commercially viable, theres not much doubt in my mind that Honeywell will be able to reap the benefits. If you are looking for undervalued quantum computing stocks, start here.

On the date of publication, Tyrik Torresdid 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.

Tyrik Torres has been studying and participating in financial markets since he was in college, and he has particular passion for helping people understand complex systems. His areas of expertise are semiconductor and enterprise software equities. He has work experience in both investing (public and private markets) and investment banking.

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The 3 Most Undervalued Quantum Computing Stocks to Buy in June 2024 - InvestorPlace

BROOMFIELD, Colo. and LONDON, June 5, 2024 Quantinuumtoday announced the development of the industrys first quantum computer featuring 56 trapped-ion qubits. The H2-1 model has improved its already leading fidelity.

In collaboration with JPMorgan Chase, Quantinuum ran a Random Circuit Sampling (RCS) algorithm, achieving a significant 100-fold improvement over previous industry results from Google in 2019 and setting a new benchmark for the cross entropy metric. H2-1s combination of scale and hardware fidelity presents a challenge for todays most powerful supercomputers and other quantum computing architectures to match this achievement.

Were extending our lead in the race towards fault tolerant quantum computing, accelerating research for customers like JPMorgan Chase in ways that arent possible with any other technology, said Rajeeb Hazra, CEO of Quantinuum. Our focus on quality of qubits versus quantity of qubits is changing whats possible, and bringing us closer to the long-awaited commercialization of quantums applications across industries like finance, logistics, transportation and chemistry.

Quantinuums analysis also indicates that the H2-1 executes RCS at 56 qubits with an estimated 30,000x reduction in power consumption compared to classical supercomputers, reinforcing it as the preferred solution for a wide array of computational challenges.

The fidelity achieved in our random circuit sampling experiment shows unprecedented system-level performance of the Quantinuum quantum computer. We are excited to leverage this high fidelity to advance the field of quantum algorithms for industrial use cases broadly, and financial use cases in particular, said Marco Pistoia, Head of Global Technology Applied Research at JPMorgan Chase.

Todays announcement is the latest in a string of breakthroughs made by Quantinuum in 2024:

Microsoft looks forward to a continued collaboration with Quantinuum as they release their high fidelity 56-qubit machine, said Dennis Tom, General Manager Microsoft Azure Quantum. Recently, the teams created four highly reliable logical qubits by applying Azure Quantums qubit-virtualization system to Quantinuums 32-qubit machine. With the additional physical qubits available on Quantinuums new machine, we anticipate creating more logical qubits with even lower error rates. As we reach these milestones, we will continue to increase the resiliency of quantum operations as well as the utility of quantum computing.

Learn more here.

To read the scientific paper, please visit: https://arxiv.org/abs/2406.02501

About Quantinuum

Quantinuum, the worlds largest integrated quantum company, pioneers powerful quantum computers and advanced software solutions. Quantinuums technology drives breakthroughs in materials discovery, cybersecurity, and next-gen quantum AI. With almost 500 employees, including 370+ scientists and engineers, Quantinuum leads the quantum computing revolution across continents. Since its formation by Honeywell and Cambridge Quantum in 2021, Quantinuum has raised approximately $625 million to further the development and commercialization of quantum computing.

Source: Quantinuum

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Quantinuum Unveils Quantum Computer Featuring 56 Trapped-Ion Qubits, Setting New Performance Benchmarks - HPCwire

LONDON, June 5, 2024 Q-CTRL today announced newly published results that demonstrate a boost of more than 4X in the size of an optimization problem that can be accurately solved, and show for the first time that a utility-scale IBM quantum computer can outperform competitive annealer and trapped ion technologies. The recent results solidify Q-CTRLs position at the forefront of the industry and reset expectations for when and how quantum advantage may arrive.

Quantum optimization is one of the most promising quantum computing applications with the potential to deliver major enhancements to critical problems in transport, logistics, machine learning, and financial fraud detection. McKinsey suggests that quantum applications in logistics alone are worth over $200-500B/y by 2035 if the quantum sector can successfully solve them.

Previous third-party benchmark quantum optimization experiments have indicated that, despite their promise, gate-based quantum computers have struggled to live up to their potential because of hardware errors. In previous tests of optimization algorithms, the outputs of the gate-based quantum computers were little different than random outputs or provided modest benefits under limited circumstances.

As a result, an alternative architecture known as a quantum annealer was believed and shown in experiments to be the preferred choice for exploring industrially relevant optimization problems. Todays quantum computers were thought to be far away from being able to solve quantum optimization problems that matter to industry.

Q-CTRLs recent results upend this broadly accepted industry narrative by addressing the error challenge. Their methods combine innovations in the problems hardware execution with the companys performance-management infrastructure software run on IBMs utility-scale quantum computers. This combination delivered improved performance previously limited by errors with no changes to the hardware.

Q-CTRLs results on IBMs hardware enable quantum optimization algorithms to more consistently find the correct solution to a range of challenging optimization problems at larger scales than ever before. The results show that this combination could practically outperform published results from both trapped-ion devices and annealers by large margins for some problems. Not only can users now solve important problems that were previously out of reach, the dramatic boost in the likelihood of finding the correct solution translates directly into cost savings for users as fewer attempts are required to return the correct solution.

To bring useful quantum computing to the world we need to both solve the problem of building a quantum computer and discover more practical algorithms, said Jay Gambetta, IBM Fellow and VP of IBM Quantum. At IBM we are committed to the first, with our development roadmap. For the second, I am excited to see Q-CTRL taking an important step to deliver practical solutions to industry-relevant optimization problems. Their software solution with an improved QAOA algorithm combined with our utility-scale quantum computers shows that quantum advantage for optimization problems is much closer than we originally thought.

It has traditionally been difficult for anyone, even specialists, to take full advantage of whats possible with utility-scale machines, said Q-CTRL CEO and Founder Prof. Michael J. Biercuk. These new results reset expectations of whats achievable with todays machines, unambiguously demonstrating that we can now correctly solve industrially relevant optimization problems that have previously been out of reach for quantum computers. Theres a new line of sight to potential quantum advantage in quantum optimization, and best of all, this capability is accessible to anyone without the need to be a quantum expert.

This result will be welcome news for those seeking early quantum advantage were finally working with a potentially useful number of qubits, said David Shaw, Chief Quantum Analyst at Global Quantum Intelligence. We can expect IBM and others to push further on underlying hardware fidelity, but crucially midstack infrastructure software is also making a bigger than expected contribution for algorithm-specific error suppression and mitigation.

Performance management tools like those provided by Q-CTRL on IBM hardware are essential to hardware, algorithm, and application developers to address the noise challenge collaboratively and unlock the potential of quantum computing, said Julian van Velzen, CTIO & Head of Capgeminis Quantum Lab. As demonstrated by this work, effectively utilising such tools can elevate the performance of the hardware to a whole new level and bring a potential quantum advantage years closer.

The achievements are detailed in thetechnical paperpublished ahead of The Economists Commercialising Quantum Global event on June 5th and 6th, 2024, where these breakthroughs will be showcased publicly for the first time. Any user can get started with Q-CTRLs performance-enhancementsoftwareand an account on IBM Quantums cloud platform to validate the results and achieve true value at utility scale.

About Q-CTRL

Q-CTRLs quantum control infrastructure software for R&D professionals and quantum computing end users delivers the highest performance error-correcting and suppressing techniques globally and provides a unique capability accelerating the pathway to the first useful quantum computers and quantum sensors. Q-CTRL operates a globally leading quantum sensing division focused on software-level innovation for strategic capability. Q-CTRL also has developed Black Opal, an edtech platform that enables users to quickly learn quantum computing. Founded by Michael J. Biercuk in 2017, Q-CTRL has pioneered the quantum infrastructure software segment and has become the leading product-focused software company in the broader quantum sector. Q-CTRL has been an inaugural member of the IBM Quantum Network startup program since 2018, and its performance management software now runs natively on IBM quantum computers. The company has international headquarters in Sydney, Los Angeles, Berlin, and Oxford.

Source: Q-CTRL

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Q-CTRL's New Results with IBM Hardware Mark Progress in Quantum Optimization - HPCwire

IBM (US), Microsoft (US), Google (US), AWS (US), Baidu (China), Rigetti Computing (US), Xanadu (Canada), Oxford Quantum Circuits (UK), IonQ (US), and Zapata Computing (US).

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By vertical, research, and academia to account for the largest market size during the forecast period.

Quantum computing is a research area combing quantum physics and computer science. Researchers from academia and the quantum computing field are expected to work together in the coming years to speed up fundamental research. Additionally, several use cases of cloud-based quantum computing exist in research and academia. Teachers can use cloud-based quantum computing to help students better understand quantum mechanics and test quantum algorithms. Scientists and researchers can use cloud-based quantum resources to test quantum information theories and compare architectures. Various partnerships took place in the cloud-based quantum computing market. In May 2021, IBM announced that it partnered with 11 top-tier academic institutions, including the IISc and IIT Kharagpur, to allow over-the-cloud access to its systems to accelerate advanced training and research in quantum computing.

By service, professional services to grow at a higher CAGR during the forecast period.

Professional services are typically offered on-demand or are project-based. They provide various services, including digital transformation, business strategy, management consulting, data architecture and visualization, UX/UI design, and more. An organization might choose professional services in consulting, cloud migration, deployment, and advanced troubleshooting. Consulting services are provided by consultants and industry experts that assist clients in recognizing new business values by implementing cloud-based quantum computing technology. They also offer customized roadmaps to help clients in adopting the solutions. For instance, IBM offers consulting services, along with quantum computers and QCaaS. 1QBit provides consulting services to customers to solve large-scale and complicated computational problems using complex algorithms and software development tools. These complex algorithms and software development tools use classical methods, quantum computers, and quantum annealing hardware.

By region, North America accounts for the largest market size during the forecast period.

North America is one of the most advanced regions regarding security technology adoption and infrastructure. It is experiencing a rise in the use of technologies such as artificial intelligence(AI) and cloud-based applications. This region is a key market for cloud-based quantum computing software & services as it is home to several key players, such as IBM, Microsoft, Google, and AWS. Several standards and regulations also govern the cloud-based quantum computing market in the North American region, specially in countries like US and Canada. The implementation of such privacy laws has prompted organizations to adopt cloud-based quantum computing solutions. Additionally, in recent years, the region witnessed several partnerships and initiatives between organizations and governments concerning cloud-based quantum computing offerings.

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Unique Features in the Cloud-based Quantum Computing Market

Platforms hosted in the cloud make quantum computing resources more accessible to anyone. Users are spared from managing intricate infrastructure or making costly hardware investments. This makes it possible for a larger spectrum of businesses, including startups and research institutes, to test and utilize the capabilities of quantum computing.

Quantum computing resources are accessible on demand through cloud platforms. The ability to scale consumption up or down to suit individual needs frees users from having to make a fixed hardware investment. This adaptability is especially useful for jobs with different processing requirements.

The initial expenses associated with buying and maintaining quantum gear are removed with cloud-based access. Quantum computing is more affordable because users only pay for the resources they really utilize, particularly for sporadic or experimental use cases.

Teams that are located in different places can work together on quantum computing projects thanks to cloud platforms. The seamless sharing of data and access to the same quantum resources by researchers and developers promotes creativity and quickens advancement.

Cloud platforms frequently interface with current classical computing frameworks and technologies. This enables users to create quantum algorithms and applications by utilizing their current workflows and skill sets.

Major Highlights of the Cloud-based Quantum Computing Market

Although the technology is still in its early phases of development, there are a wide range of possible applications. There are a ton of opportunities for creativity and discovery in a variety of fields during this "nascent" stage.

To make quantum computing more accessible to a larger range of consumers, cloud providers are aggressively creating user-friendly tools and interfaces. This emphasis on usability is essential for wider adoption.

Prominent IT firms, academic organizations, and startups are working together to create and implement cloud-based quantum computing solutions. These collaborations promote quicker development and broader market penetration.

Cloud service companies are customizing their products to fit the demands of many sectors, including finance, materials science, and medicines. This personalization contributes to realizing quantum computing's full promise for practical uses.

Numerous governments are funding R&D projects because they understand the strategic significance of quantum computing. This support from the government offers a solid basis for market expansion.

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Top Companies in the Cloud-based Quantum Computing Market

Major players in this market are based in North America and Asia Pacific. IBM (US), Microsoft (US), Google (US), AWS (US), Baidu (China), and Huawei (China) are among a few leading players operating in the cloud-based quantum computing market. These players have adopted various growth strategies to strengthen their position in the market. These include product launches, contracts, partnerships, mergers and acquisitions, and product development activities to expand their presence in the cloud-based quantum computing market. For instance, in March 2023, T-Systems and IBM announced a partnership in cloud-based quantum computing. T-Systems can now provide its customers with cloud access to IBM's quantum systems, including multiple quantum computers powered by the 127-qubit IBM Eagle processor. Additionally, T-Systems will offer dedicated quantum know-how and training.

Microsoft develops and supports software, services, devices, and solutions, including computer software, consumer electronics, personal computers, and related services, and in this market, it provides Azure Quantum. Azure Quantum offers innovative quantum computing and optimization solutions in a single cloud service. Also, it provides an open ecosystem to write and run code on diverse quantum hardware, offers flexibility to use development tools with support for Cirq and Qiskit, and preparation and refining of solutions to run on scaled quantum computers with the resource estimation tool. It serves verticals including automotive, financial services, healthcare, manufacturing, defense and intelligence, and energy. The Microsoft partner network helps expand the company's presence. The company has a geographical presence in North America, Europe, the Middle East & Africa, Asia Pacific, and Latin America. The company engages in partnerships, collaborations, business expansions, and acquisitions to help expand its global presence. In April 2021, Ally Financial, a fintech company, partnered with Microsoft on Azure Quantum solutions to develop quantum computing skills and explore how new algorithms and future quantum hardware could improve customer experience.

Amazon Web Services (AWS) provides solutions in analytics, application integration, blockchain, business applications, cloud financial management, computing, containers, developer tools, the Internet of Things(IoT), machine learning, and more. The cloud-based quantum computing market; offers Amazon Braket, a fully managed quantum computing service designed to help speed up scientific research and software development for quantum computing. Its use cases include researching quantum computing algorithms, testing quantum hardware, building quantum software, and developing open-source software. The company caters to verticals, including aerospace and satellite, automotive, education, energy, financial services, healthcare, life sciences, manufacturing, power, and utilities. AWS Cloud spans 96 availability zones within 30 geographic regions worldwide, with announced plans for 15 more availability zones and five more AWS regions in Australia, Canada, Israel, New Zealand, and Thailand. AWS has a geographical presence in North America, Europe, Asia Pacific, the Middle East& Africa, and Latin America, thus featuring a network of 1,00,000 partners from more than 150 countries. The company is taking several initiatives in the cloud-based quantum computing market. In April-2021, AWS announced a partnership with the Hebrew University of Jerusalem. Through the AWS Cloud Credit for Research Program, AWS supports independent research using Amazon Braket, which enables research organizations to explore quantum, classical high-performance computing (HPC), and quantum-inspired approaches to problems from the same console.

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