Category Archives: Quantum Computing

Imagine what will happen if we robots can process information, store data and transfer the same at a pace at which humans do, will they not be as good as humans? Just to let you know we will touch on one aspect in this article (Quantum Computing) which takes care of processing information, however there is tremendous progress already made to store information like our DNA and also transmit the same like our nervous system does.

As the smartest creatures on Earth, our journey from the analogue to the digital world has been at a tremendous pace in the past decades.

There was a time, few decades ago, when invention of electronic calculator marked a major breakthrough in the world of technology. The transformational advancements of processing information since then have been remarkable. Undoubtedly, we have come a long way with smartphones, wearable and smart devices, shifting from press the keys to touch, swipe and speak.

With Artificial Intelligence (AI), Virtual Reality (VR), Internet of Things (IoT) and Metaverse being technological realities today, we are also heading towards a new era of data & computation called quantum computing.

Now, Whats That?

Well, quantum computing is a futuristic technology which employs the power of quantum mechanics for solving extremely complex problems that are beyond the capacity of classical computers. To define it simply, this computer-based technology functions around the quantum theory principals where behaviours of matter and energy are studied on the atomic and subatomic levels.

Supercomputers designed on quantum theory consume comparative less energy while operating at an exponentially higher speed.

This quantum computer implements the laws of quantum mechanism for such complex calculation which are much beyond human comprehensions.

Tech titans envision that humans will be accelerated into the future by quantum computing through its impact on data analytics and artificial intelligence. Its massive speed and power shall help us crack even the complex challenges that we, human beings, face.

In the Next Decades, What If I Say That Robots Can Become a Challenge to the Humans?

If thats going to happen, it would be for AI and quantum technology. Scientists have already started to research on bridging the two avenues quantum physics having its strong algorithms and artificial intelligence coupled with autonomous machines. They are investigating the ways to use quantum technology for the advantage of learning robots. So far, the results show that robots can decide faster.

#Case Study:

A team of experimental physicists led by Philip Walther from The University of Vienna collaborated with theoreticians from German Aerospace Center, the Austrian Academy of Sciences and University of Innsbruck. Together, for the first time, they succeeded in proving the increase in actual learning time of a robot. Their experiment included the use of fundamental particles of light, single photons and integrated photonic quantum processor. The researchers implemented learning tasks by using this processor as a robot. The result showed significant reduction in the learning time, compared to the no quantum physics cases.

Hence, artificial intelligence devices that are integrated with quantum computing are capable of self-correction and learning through experience, much like humans.

Sounds interesting?Let me make it more intriguing for you.

As the speed of quantum computing is significantly higher than the traditional machines, this could result in quantum robots if rapid responses are recorded. Such robots are envisioned to be highly advanced and way more sophisticated, with unparalleled capabilities of multitasking. Not just that, but they will also be able to fully examine and adapt to various environments for survival, becoming independently more creative and data processing at a greater speed.

Scientists also opine that the concept of technological singularity will be possible, which signifies machines will be more progressive and smarter than humans.

Upcoming: Robots with Human Intelligence

Yes! You read that right.

Plans are already on to build robots that would share similar values as well as rights like us. They will have the ability to understand the world like humans, have same feelings as well as emotional spectrum. Such human-like technology will profoundly change our relationship with technology and the world around us.

What next?

Remember the movie titled Transcendence? The protagonist uploads his consciousness into quantum computer and outsmarts death! Well, what you might have thought to be unrealistic then may not be so today. Popular predictions say that humans will soon become transhumans through the concept of virtual or digital immortality. We already have quantum computer amongst us, though not a consumer product, but commercially available.

How would this technology make it happen?

Well, going back to its definition again, quantum computers utilise quantum bits or qubits. These tiny physical objects help them cope with highly complex problems and extremely large volumes of data in less than a second. Hence, storing a humans memories and personality would be an effortless job for the quantum computers.

Recent breakthroughs show that narrow AI can perform certain tasks much better than humans. It wont be surprising to say that artificial intelligence will emulate the human skill, i.e. responding to various tasks, and thereby, put our race at a challenge in the future.

Coming back to digital immortality, it is a theoretical concept of transferring and storing an individuals consciousness into a robot, a virtual body or a computer. The required technology with appropriate hardware for this transfer is expected to arrive soon in this decade, although several milestones are needed to be achieved yet.

Digital Immortality: How far are we?

Once a persons consciousness is uploaded, it can be stored in two different ways:

From there, it can easily interact with the physical as well as the virtual worlds. The fascinating result would be that the persons consciousness will remain alive in a virtual space for thousands and thousands of years to come. Thats not all. He can also travel to various virtual worlds and download content for enriched experience. Being still alive, he can work with his own digital clones to accomplish essential jobs in real life faster.

Quite a far future though, the second instance says human beings will possibly grow or build completely new bodies. While models may vary with the type of technology used, the least expensive one could be machine-like or robotic in appearance.

Fast forwarding many decades from today, we might have these machines as highly expensive synthetic bodies similar to the real human bodies using several hi-tech features to enhance their mental and physical capabilities. Moving thousands of years further, the world might have so advanced synthetic bodies that their capabilities would probably exceed our wildest imaginations today. If need be, new versions of these bodies can also come up.

According to the predictions of renowned futurist, Ray Kurzweil, uploading the human mind would be possible in the next quarter century, though perfection might need a lot of time.

In a major breakthrough in research a year ago, one of the most complex organs, eyes of mice, were reprogrammed in a lab. If a human goes blind when older, he/she never recovers the vision. Hence, the experiment was done on one-year old mice using gene therapy where their retinas were turned to be young again. Three out of the four reprogramming factors were implemented. Scientists successfully reversed aging in their retinas taking those backwards to around two months old in age. The mice could clearly see everything again much, like they saw when young. Additionally, the system can be turned on and off whenever required. Scientists confirmed that this can be done with any tissue to reverse aging, not going back too far though.

Probably, the concept of death will vanish in a century or so owing to the dynamic evolution of technology. Humans will just be moving from one body to another, with their memory and consciousness stored in the form of data.

To say so, its just the beginning for us to understand what possibilities artificial intelligence have. Every new and successful experiment, thus, adds to the development of the scope of quantum computing. IBM believes that quantum computing will become the mainstream technology in probably the next 5 years. At this point, can we look back to our mythology and sum up that our culture has been talking about it since eons?

Food for thought:

In simple terms, History for which we dont have documented proof is called Mythology. Do you think we will need to document or even speak 100 years from now? We have already moved from paper documents to speaking in a mic and recording the artefacts, why is it not possible to just transfer thoughts from one person (robot) to another without any speech or text?

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Robots & Humans: Are we heading towards Singularity? - INDIAai

VANCOUVER Researchers have made a breakthrough in quantum technology development that has the potential to leave todays supercomputers in the dust, opening the door to advances in fields including medicine, chemistry, cybersecurity and others that have been out of reach.

In a study published in the journal Nature on Wednesday, researchers from Simon Fraser University in British Columbia said they found a way to create quantum computing processors in silicon chips.

Principal investigator Stephanie Simmons said they illuminated tiny imperfections on the silicon chips with intense beams of light. The defects in the silicon chips act as a carrier of information, she said. While the rest of the chip transmits the light, the tiny defect reflects it back and turns into a messenger, she said.

There are many naturally occurring imperfections in silicon. Some of these imperfections can act as quantum bits, or qubits. Scientists call those kinds of imperfections spin qubits. Past research has shown that silicon can produce some of the most stable and long-lived qubits in the industry.

"These results unlock immediate opportunities to construct silicon-integrated, telecommunications-band quantum information networks," said the study.

Simmons, who is the university's Canada Research Chair in silicon quantum technologies, said the main challenge with quantum computing was being able to send information to and from qubits.

"People have worked with spin qubits, or defects, in silicon before," Simmons said. "And people have worked with photon qubits in silicon before. But nobody's brought them together like this."

Lead author Daniel Higginbottom called the breakthrough "immediately promising" because researchers achieved what was considered impossible by combining two known but parallel fields.

Silicon defects were extensively studied from the 1970s through the '90s while quantum physics has been researched for decades, said Higginbottom, who is a post-doctoral fellow at the university's physics department.

"For the longest time people didn't see any potential for optical technology in silicon defects. But we've really pioneered revisiting these and have found something with applications in quantum technology that's certainly remarkable."

Although in an embryonic stage, Simmons said quantum computing is the rock 'n' roll future of computers that can solve anything from simple algebra problems to complex pharmaceutical equations or formulas that unlock deep mysteries of space.

"We're going to be limited by our imaginations at this stage. What's really going to take off is really far outside our predictive capabilities as humans."

The advantage of using silicon chips is that they are widely available, understood and have a giant manufacturing base, she said.

"We can really get it working and we should be able to move more quickly and hopefully bring that capability mainstream much faster."

Some physicists predict quantum computers will become mainstream in about two decades, although Simmons said she thinks it will be much sooner.

In the 1950s, people thought the technology behind transistors was mainly going to be used for hearing aids, she said. No one then predicted that the physics behind a transistor could be applied to Facebook or Google, she added.

"So, we'll have to see how quantum technology plays out over decades in terms of what applications really do resonate with the public," she said. "But there is going to be a lot because people are creative, and these are fundamentally very powerful tools that we're unlocking."

This report by The Canadian Press was first published July 14, 2022.

Hina Alam, The Canadian Press

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Old computer technology points the way to future of quantum computing - Alberta Prime Times

A University of Minnesota Twin Cities-led team received a $1.4 million award from the W. M. Keck Foundation to study a new process that combines quantum physics and biochemistry. If successful, the research could lead to a major breakthrough in the quantum computing field.

The project is one of two proposals the University of Minnesota submits each year to the Keck Foundation and is the first grant of its kind the University has received in 20 years.

Quantum computers have the potential to solve very complex problems at an unprecedented fast rate. They have applications in fields like cryptography, information security, supply chain optimization and could one day assist in the discovery of new materials and drugs.

One of the biggest challenges for scientists is that the information stored in quantum bits (the building blocks of quantum computers) is often short-lived. Early-stage prototype quantum computers do exist, but they lose the information they store so quickly that solving big problems of practical relevance is currently unachievable.

One approach researchers have studied to attempt to make quantum devices more stable is by combining semiconductors and superconductors to obtain robust states called Majorana modes, but this approach has been challenging and so far inconclusive since it requires very high-purity semiconductors. U of M School of Physics and Astronomy Associate Professor Vlad Pribiag, who is leading the project, has come up with a new idea that could yield stable Majorana quantum structures.

Pribiags proposed method leverages recent advances in DNA nanoassembly, combined with magnetic nanoparticles and superconductors, in order to detect Majoranas, which are theoretical particles that could be a key element for protecting quantum information and creating stable quantum devices.

This is a radically new way to think about quantum devices, Pribiag said. When I heard about this technique of DNA nanoassembly, I thought it fit right into this problem I had been working on about Majoranas and quantum devices. Its really a paradigm shift in the field and it has tremendous potential for finding a way to protect quantum information so that we can build more advanced quantum machines to do these complex operations.

The project, entitled Topological Quantum Architectures Through DNA Programmable Molecular Lithography, will span three years. Pribiag is collaborating with Columbia University Professor Oleg Gang, whose lab will handle the DNA nanoassembly part of the work.

About the W. M. Keck FoundationBased in Los Angeles, the W. M. Keck Foundation was established in 1954 by the late W. M. Keck, founder of the Superior Oil Company. The Foundations grant making is focused primarily on pioneering efforts in the areas of medical research and science and engineering. The Foundation also supports undergraduate education and maintains a Southern California Grant Program that provides support for the Los Angeles community, with a special emphasis on children and youth. For more information, visit the Keck Foundation website.

About the College of Science and EngineeringThe University of Minnesota College of Science and Engineering brings together the Universitys programs in engineering, physical sciences, mathematics and computer science into one college. The college is ranked among the top academic programs in the country and includes 12 academic departments offering a wide range of degree programs at the baccalaureate, master's, and doctoral levels. Learn more at cse.umn.edu.

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UMN-led team receives $1.4M Keck Foundation grant to study possible breakthrough in quantum computing - UMN News

With the crypto market continuing to trade sideways with mounting bearish pressure, niche categories for crypto tokens remain highly popular as traders and investors prowl for underrated and undervalued projects for long-term investments. Some popular crypto token types include Metaverse tokens, Web3 coins, and dApp tokens on various ecosystems like Tron, Elrond, Ethereum, Polkadot, etc.

Cryptocurrencies have the power to revolutionize finance by cutting out intermediaries. By bringing their exceptional capability to the design process, quantum computers and supercomputers have the potential to revolutionize the way medicines and materials are created.

But, Heres the issue: If quantum computing develops more quickly than efforts to future-proof digital money, the blockchain accounting system that underpins cryptocurrencies may be susceptible to sophisticated hacks and fake transactions.

On the other hand, some new cryptocurrencies claim to be quantum secure and quantum-resistant, which means they can withstand known quantum computer assaults. We will look at some cryptocurrency tokens at the top of their game.

Note: This list is ordered by market capitalization, from lowest to highest.

Mochimo (MCM), a brand-new cryptocurrency developed by an international team and released on June 25th, 2018, is resistant to threats from quantum computers.

Mochimo uses WOTS+ Quantum Resistant Security approved by the EU-funded PQCrypto research organization and a one-time addressing feature to secure privacy when you want it.

According to the website, the Mochimo blockchain remains small while substantially increasing TX speed using ChainCrunch, a proprietary algorithm. Using a compressed portion of the historical blockchain available on every node in the decentralized network, anyone can set up a full working node in minutes.

Industry experts in computer networking, artificial intelligence, telecommunications, cryptography, and software engineering make up the critical contributors of Mochimo.

Some top cryptocurrency exchanges for trading Mochimo $MCM are currently CITEX, FINEXBOX, and VinDAX.

The goal of HyperCash (HC), originally known as Hcash, is to make value transfers possible between various blockchains. It supports DAO governance, quantum resistance, and zero-hash proofs.

Its a decentralized and open-source cross-platform cryptocurrency designed to facilitate the exchange of information between blockchains and non-blockchain networks.

Its also a highly secure network featuring quantum-resistant signature technology.

The HCASH network has two chains running laterally, each serving different functions within the ecosystem.

Hcashs governance is based on a hybrid PoW/PoS consensus methodology and blockchain/DAG network.

If you want to know where to buy HyperCash at the current rate, check out these exchanges OKX, MEXC, KuCoin, Huobi Global, Gate.io, and Hoo. HyperCash is up 3.87% in the last 24 hours.

Nexus (NXS) is a community-driven initiative with the shared goal of creating a society characterized by progressive and ethical principles, advanced technology, and universal access to connection on a free and open basis.

Since September 23rd, 2014, Nexus has been created through mining alone, without an ICO or premine. Nexus uses post-quantum signature schemes (FALCON) and automated key management functions through the Signature Chains technology.

This technology eliminates key management issues (wallet.dats) by allowing users to access their accounts with the familiarity of a username, password, and PIN.

Another technology being developed by Nexus includes;

All the tech mentioned above is connected through a multi-dimensional chaining structure. Nexus is bringing this possibility to life with an end-to-end decentralized platform designed to empower every human being with technology to reclaim their digital identity.

Some top cryptocurrency exchanges for trading $NXS are Binance, Pionex, Bittrex, and CoinDCX.

The Quantum Resistant Ledger (QRL) is a fully quantum-resistant blockchain network using PQ-CRYPTO recommended/IETF standardized cryptography.

The QRL utilizes a hash-based eXtended Merkle Tree Signature Scheme (XMSS) instead of ECDSA, which is reportedly vulnerable to quantum attacks and found in many other blockchain projects.

According to the project, a set of applications and a development environment that enable users to simply build blockchain applications on its provably quantum-resistant network enhance the security of its platform.

Combining on-chain lattice key storage with their robust ephemeral messaging layer to internode communication provides a first-of-its-kind post-quantum secure message layer for ultra-secure digital communications.

The platform has a full suite of end-user products designed with the end-user in mind: from integrations with hardware wallets to mobile applications.

If you want to know where to buy $QRL, check out the CoinTiger exchange.

Launched in 2016, IOTA (MIOTA) is a distributed ledger. However, it differs significantly from a blockchain in that it isnt one. Instead, it uses a system of nodes called Tangle, its patented technology, to confirm transactions.

There are no fees since there is no blockchain, no mining, i.e., no miners. When congestion worsens, costs soar on many conventional networks, but IOTA seeks to offer limitless capacity at a low price.

The platforms foundation claims it provides much faster speeds than traditional blockchains and has the perfect footprint for the ever-expanding Internet of Things ecosystem.

The objective of IOTA is to establish itself as the default platform for carrying out IoT device transactions.

In summary:

According to the team behind the project, their distributed ledger may provide everyone access to digital identities, lead to auto insurance policies based on actual usage, open the door to cutting-edge smart cities, facilitate frictionless international trade, and establish the legitimacy of goods.

Some top cryptocurrency exchanges for trading $MIOTA are Binance, OKX, Bybit, Bitget, and BingX.

Disclosure: This is not trading or investment advice. Always do your research before buying any Quantum Computing token or investing in any cryptocurrency.

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Top 5 Quantum Computing Crypto Tokens to Watch in 2022 - The VR Soldier

Abu Dhabi: At the heart of Abu Dhabis science research hub in Masdar, a new era of computing is taking shape. With massive investments towards becoming a leader in the field, Abu Dhabi could well revolutionise quantum computing when a newly-developed foundry starts churning out quantum chips this summer.

With the world of computing still undecided on which platform works best to enable, and then scale up, quantum computing, chips manufactured at the laboratory will allow important experiments into the possibilities of various material and configurations.

Quantum foundry

The laboratory is part of the Quantum Research Centre, one of a number of research interests at the Technology Innovation Institute (TII), which focuses on applied research and is part of the over-arching Advanced Technology Research Council in Abu Dhabi.

TII Quantum Foundry will be the first quantum device fabrication facility in the UAE. At the moment, it is still under construction. We are installing the last of the tools needed to manufacture superconducting quantum chips. We are hoping that it will be ready soon, and hopefully by then, we can start manufacturing the first quantum chips in the UAE, Alvaro Orgaz, lead for the quantum computing control at the TIIs Quantum Research Centre, told Gulf News.

The design of quantum chips is an area of active research at the moment. We are also interested in this. So, we will manufacture our chips and install them into our quantum refrigerators, then test them and improve on each iteration of the chip, he explained.

What is quantum computing?

Classical computers process information in bits, tiny on and off switches that are encoded in zeroes and ones. In contrast, quantum computing uses qubits as the fundamental unit of information.

Unlike classical bits, qubits can take advantage of a quantum mechanical effect called superposition where they exist as 1 and 0 at the same time. One qubit cannot always be described independently of the state of the others either, in a phenomenon called entanglement. The capacity of a quantum computer increases exponentially with the number of qubits. The efficient usage of quantum entanglement drastically enhances the capacity of a quantum computer to be able to deal with challenging problems, explained Professor Dr Jos Ignacio Latorre, chief researcher at the Quantum Research Center.

Why quantum computing?

When quantum computers were first proposed in the 1980s and 1990s, the aim was to help computing for certain complex systems such as molecules that cannot be accurately depicted with classical algorithms.

Quantum effects translate well to complex computations in some fields like pharmaceuticals, material sciences, as well as optimisation processes that are important in aviation, oil and gas, the energy sector and the financial sector. In a classical computer, you can have one configuration of zeroes and ones or another. But in a quantum system, you can have many configurations of zeroes and ones processed simultaneously in a superposition state. This is the fundamental reason why quantum computers can solve some complex computational tasks more efficiently than classical computers, said Dr Leandro Aolita, executive director of quantum algorithms at the Quantum Research Centre.

Complementing classical computing

On a basic level, this means that quantum computers will not replace classical computers; they will complement them.

There are some computational problems in which quantum computers will offer no speed-up. There are only some problems where they will be superior. So, you would not use a quantum computer which is designed for high-performance computing to write an email, the researcher explained. This is why, in addition to research, the TII is also working with industry partners to see which computational problems may translate well to quantum computing and the speed-up this may provide, once the computers are mature enough to process them.

Quantum effect fragility

At this stage, the simplest quantum computer is already operational at the QRC laboratory in Masdar City. This includes two superconducting qubit chips mounted in refrigerators at the laboratory, even though quantum systems can be created on a number of different platforms.

Here, the super conducting qubit chip is in a cooler that takes the system down to a temperature that goes down to around 10 millikelvin, which is even cooler than the temperature of outer space. You have to isolate the system from the thermal environment, but you also need to be able to insert cables to control and read the qubits. This is the most difficult challenge from an engineering and a technological perspective, especially when you scale up to a million qubits because quantum effects are so fragile. No one knows exactly the exact geometric configurations to minimise the thermal fluctuations and the noise, [and this is one of the things that testing will look into once we manufacture different iterations of quantum chip], Dr Aolita explained.

Qubit quality

The quality of the qubit is also very important, which boils down to the manufacture of a chip with superconducting current that displays quantum effects. The chips at TII are barely 2x10 millimetres in size, and at their centre is a tiny circuit known as the Josephson junction that enables the control of quantum elements.

It is also not just a matter of how many qubits you have, as the quality of the qubits matters. So, you need to have particles that preserve their quantum superposition, you need to be able to control them, have them interact the way you want, and read their state, but you also have to isolate them from the noise of the environment, he said.

Optimistic timeline

Despite these massive challenges to perfect a minute chip, Dr Aolita was also quite hopeful about the work being accomplished at TII, including discussions with industry about the possible applications of quantum computing.

I think we could see some useful quantum advantages in terms of classical computing power in three to five years, he said. [Right now], we have ideas, theories, preliminary experiments and even some prototypes. Quantum computers even exist, but they are small and not still able to outperform classical supercomputers. But this was the case with classical computing too. In the 1950s and 1940s, a computer was like an entire gym or vault. Then the transistor arrived, which revolutionised the field and miniaturised computers to much smaller regions of space that were also faster. Something similar could happen here and it really is a matter of finding which kind of qubit to use and this could ease the process a lot. My prediction for a timeline is optimistic, but not exaggerated, the researcher added.

Science research

Apart from the techonological breakthroughs, the QRCs efforts are likely to also improve Abu Dhabis status as a hub for science and research.

The UAE has a long tradition of adopting technologies and incorporating technologies bought from abroad. This is now [different in] that the government is putting a serious stake in creating and producing this technology and this creates a multiplicative effect in that young people get more enthusiastic about scientific careers. This creates more demand for universities to start new careers in physics, engineering, computer science, mathematics. This [will essentially have] a long-term, multiplicative effect on development, independent of the concrete goal or technical result of the project on the scientific environment in the country, Dr Aolita added.

The QRC team currently includes 45 people, but this will grow to 60 by the end of 2022, and perhaps to 80 people in 2023. We also want to prioritise hiring the top talent from across the world, Dr Aolita added.

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Watch: How Abu Dhabi is ushering in a new era of computing with state-of-the-art quantum lab - Gulf News

The latest competent intelligence report published by WMR with the title An increase in demand and Opportunities for Global Quantum Computing in Chemistry Market 2022 provides a sorted image of the Quantum Computing in Chemistry industry by analysis of research and information collected from various sources that have the ability to help the decision-makers in the worldwide market to play a significant role in making a gradual impact on the global economy. The report presents and showcases a dynamic vision of the global scenario in terms of market size, market statistics, and competitive situation.

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IBM Google D-Wave Solutions Microsoft Rigetti Computing Intel Anyon Systems Inc. Cambridge Quantum Computing Ltd Origin Quantum Computing Technology Quantum Circuits Inc.

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Quantum Hardware Quantum Software

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Chemical Plant Research Institute Other

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1.1 Definition and forecast parameters1.2 Methodology and forecast parameters1.3 Information Sources

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2.1 Regional trends2.2 Product trends2.3 End-use trends2.4 Business trends

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3.1 Industry fragmentation3.2 Industry landscape3.3 Vendor matrix3.4 Technological and innovative landscape

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Quantum Computing in Chemistry Market to Witness Huge Growth in Coming Years With Profiling Leading Companies: IBM, Google, D-Wave Solutions,...