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Authorities say a 19-year-old Missouri man with a Nazi flag in the truckcrashed a U-Haul into security barriers near the White House late Monday night. The Nazi flag that authorities say he had with him was later photographed unfurled on the ground near the truck. He could face multiple charges, including threatening to hurt the president.

Trump Jr. wrote, If the threat of white supremacy is so real, why do they have to outsource all the hate?

Donald Trump Jr., the son of the former president, soon retweeted a post that expressed skepticism about the official version of events and added more skepticism of his own. He said of federal law enforcement, You would think they would be able to do a much better job at creating fake crimes and fake hate. Later, in a tweet that drew attention to the suspects Indian name, Trump Jr. wrote, If the threat of white supremacy is so real, why do they have to outsource all the hate?

That wasnt the first time weve seen Trump Jr. accusing federal authorities of exaggerating the white supremacist threat.Last Saturday, after about a hundred members of the white nationalist group Patriot Front marched in Washington, Trump Jr. suggested the marchers were all feds: Do we really want to pretend its not a fed operation? he asked on a podcast. He was preaching to the choir of conspiracy theorists across platforms that echoed similar sentiments. Popular podcaster Joe Rogan joked with guest Matt Taibbi that the marchers had to be federal agents because, he said, there were no fat people among them.

Those high-profile people werent alone. In fact, claiming that federal authorities are falsely connecting crimes to white supremacists has become a trend. Almost as fast as the Secret Service descended on the man in the U-Haul, far-right MAGA followers launched a counteroffensive against any implication that the driver was one of theirs. Were in an interesting moment when followers and close associates of a former president seem compelled, sometimes in unison, to deny any association with the authoritarian, white supremacist, white nationalist or even neo-Nazi ideologies some of them seem to espouse. To paraphrase a character in Shakespeares Hamlet, Methinks they doth protest too much.

This new strategy involves claiming that any violent incident by someone who even appears to have such leanings is not just a false flag operation but maybe a false flag operation staged by the government. These claims happen so quickly, in such large volume and across so many social media platforms, that the word feds was trending on Twitter for much of Tuesday morning. At that time, we didnt yet have the report from authorities that the U-Haul suspect had praised Hitler to police and told them that his intent was to kill President Joe Biden. Facts werent needed. Someone had to defend the honor of MAGA loyalists.

The same strategy of feigned disbelief was on display after the May 6 mass shooting at a mall in Allen, Texas. The police reported that the Latino suspect had neo-Nazi ideation and wore associated patches and tattoos, but the MAGA faithful pretended it was all a government ruse designed to make them look bad. Rep. Marjorie Taylor Greene, R-Ga., tweeted: Only dumb white people would believe that a Mexican gang member is killing people for white supremacy.

The fact that people who arent white have been known to identify with white supremacy didnt stop people from making arguments that law enforcements reports about the Allen shooter were wrong. Twitter CEO Elon Musk also joined in and claimed the shooters alleged ideologies seemed suspicious.

There are three reasons why this strategy of denying the validity of reports linking violent crimes to white supremacy and deflecting them onto scheming federal agents has become so prevalent.

The same strategy of feigned disbelief was on display after the May 6 mass shooting at mall in Allen, Texas.

First, the strategy sends a reassuring message to far-right adherents who might think that a hate-fueled mass shooting, or other violent attack, is their cue to leave the MAGA movement. Well-publicized claims that such crimes or the hateful marchers dressed in khaki cargo pants arent real, provides the kind of solace that helps delude adherents into sticking around. Effectively, the message to the MAGA masses is, Dont worry.We didnt do this.

Second, denial and deflection tactics help far-right extremists convince themselves that the problem of violence associated with white nationalism is overblown. It encourages far-right opinion writers to cherry-pick anecdotes in an attempt to demonstrate that the racism problem isnt as bad as its made out to be. But the data tells another story. Violent hate is on the rise.

In 2020, Christopher Wray, the then-FBI director who'd been appointed by Trump, said in testimony before Congress that the Bureaus data indicates that motivated violent extremistsin recent years have been responsible for the most lethal activity. Similarly, President Biden told the graduating class of Howard University last Saturday that white supremacy is the most dangerous terrorist threat to our homeland.

Third, the deniers and deflectors are increasingly aware that the feds, as they consistently call them, are not only investigating their leader but may be close to indicting him. They fear whats coming. If and when charges come, folks such as Donald Trump Jr. will need to be able to refute any charges by repeating the mantra that the feds make stuff up, including, even criminal cases. Theyll likely tell their followers that the folks who investigated Trump are the same people who staged violent incidents to make it look like MAGA followers were responsible.

Denial, deflection and delusion. Thats not just a Trump Jr. thing. It's also the strategic opiate of the chronically unaware. Sad to see how often it works.

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Donald Trump Jr.'s response to White House U-Haul crash reveals ... - MSNBC

San Jose is on a path to close anelection loophole that former Mayor Sam Liccardo and his right-hand man usedto raise more than $1.5 million to fill seats on the City Council.

The city is looking to prohibit elected officials and their staff from working on political action committees (PACs) that raise money for local races. This move comes after residents and city leadersquestioned the extracurricular political activities of Jim Reed while he served as Liccardos chief of staff. The council voted 8-1-2 on Tuesday to change city laws, with Councilmember Bien Doan dissenting and Councilmembers Sergio Jimenez and Omar Torres absent. The law is slated to take effect by August, pending final approval.

Current city policy only prohibits someone running for officea candidatefrom working on PACs. The definition of candidate would be redefined to include elected city officials, their employees and any City Hall employee. The shift would align San Jose with state law.

Reed and Liccardo raised nearly $1.5 million from wealthy landowners, developers and business executives through their political action committee Common Good Silicon Valley. Most of the dollars went to support Mayor Matt Mahans bid for the citys top seat. Reed is now Mahans chief of staff. And while his fundraising involvement was allowed then, it could soon violate city policy.

Mahan and Reed previously told San Jos Spotlightno one on the mayors staff will be working on a local PAC while Mahan runs for reelection in 2024. Reed said he volunteered for Common Good and never received payment for his work. However, councilmembers want to expedite the rule change to take effect by August when election season officially starts.

The importance of maintaining the integrity of our political system and preventing corruption and undue inputs from special interest groups is paramount, Councilmember Domingo Candelas said. Thats ultimately what were doing, protecting the public trust in our government.

Former Councilmember Maya Esparzawas one of the first to call on the city to change local election laws last November, after she lost her reelection bid to Doan. She was one of the candidates that Reed and Liccardos PAC spent money against.

Several residents called out Reed by name at Tuesdays council meeting. John Tucker, a union member of MEF-AFSCME Local 101, said hes particularly concerned with Reeds political activity because having wealthy contractors donate to Common Good could curry favors from the mayors office.He pointed to two different contractors that donated $10,000 each to the PAC: California Waste Solutions and GreenWaste Recovery Inc.

Bully for Jim Reed who abused this loophole to get his candidate elected and keep his own job in the process, Tucker said.

Tucker said the policy change would help eliminate the perception of favoritism and potential corruption at City Hall.

Esparza also directed the city to explore banning elected officials and city employees from working at a local PAC for a specific period of timeafter they leave the position, also known as a revolving door policy. However, the city attorneys office said the idea could violate their First Amendment rights to participate in local elections. Councilmembers deferred further discussion of the policy until August.

Matthew Alvarez, board member of the California Political Attorneys Association, said the changes would be unconstitutional during last weeks Rules and Open Government Committee meeting. Alvarez works at the Sutton Law Firm which represents Common Good.

The city has no compelling interest to prevent employees from participating in their personal time on whatever campaigns they wish and in whatever capacity they wish, Alvarez told councilmembers. This is basic First Amendment law 101 and the city is completely ignoring it.

The first hearing of the local election rule changes is June13 and the council will vote on June 20. If approved, the rule will go into effect on July 20. Learn how to watch and participate.

Contact Jana Kadah at [emailprotected] or @Jana_Kadah on Twitter.

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San Jose officials want to stop shady politics - San Jos Spotlight - San Jos Spotlight

Bavarian science minister Markus Blume views part of a quantum computer with Dieter Kranzlmller (left) at the Leibniz Supercomputing Center.Credit: Sven Hoppe/dpa/Alamy

Most researchers have never seen a quantum computer. Winfried Hensinger has five. Theyre all terrible, he says. They cant do anything useful.

In fact, all quantum computers could be described as terrible. Decades of research have yet to yield a machine that can kick off the promised revolution in computing. But enthusiasts arent concerned and development is proceeding better than expected, researchers say.

Im not trying to take away from how much work there is to do, but were surprising ourselves about how much weve done, says Jeannette Garcia, senior research manager for quantum applications and software at technology giant IBM in San Jose, California.

Nature Spotlight: Quantum computing

Hensinger, a physicist at the University of Sussex in Brighton, UK, published a proof of principle in February for a large-scale, modular quantum computer1. His start-up company, Universal Quantum in Haywards Heath, UK, is now working with engineering firm Rolls-Royce in London and others to begin the long and arduous process of building it.

If you believe the hype, computers that exploit the strange behaviours of the atomic realm could accelerate drug discovery, crack encryption, speed up decision-making in financial transactions, improve machine learning, develop revolutionary materials and even address climate change. The surprise is that those claims are now starting to seem a lot more plausible and perhaps even too conservative.

According to computational mathematician Steve Brierley, whatever the quantum sweet spot turns out to be, it could be more spectacular than anything we can imagine today if the field is given the time it needs. The short-term hype is a bit high, says Brierley, who is founder and chief executive of quantum-computing firm Riverlane in Cambridge, UK. But the long-term hype is nowhere near enough.

Until now, there has been good reason to be sceptical. Researchers have obtained only mathematical proofs that quantum computers will offer large gains over current, classical computers in simulating quantum physics and chemistry, and in breaking the public-key cryptosystems used to protect sensitive communications such as online financial transactions. All of the other use cases that people talk about are either more marginal, more speculative, or both, says Scott Aaronson, a computer scientist at the University of Texas at Austin. Quantum specialists have yet to achieve anything truly useful that could not be done using classical computers.

The problem is compounded by the difficulty of building the hardware itself. Quantum computers store data in quantum binary digits called quantum bits, or qubits, that can be made using various technologies, including superconducting rings; optical traps; and photons of light. Some technologies require cooling to near absolute zero, others operate at room temperature. Hensingers blueprint is for a machine the size of a football pitch, but others could end up installed in cars. Researchers cannot even agree on how the performance of quantum computers should be measured.

Whatever the design, the clever stuff happens when qubits are carefully coaxed into superposition states of indefinite character essentially a mix of digital ones and zeroes, rather than definitely being one or the other. Running algorithms on a quantum computer involves directing the evolution of these superposition states. The quantum rules of this evolution allow the qubits to interact to perform computations that are, in practical terms, impossible using classical computers.

That said, useful computations are possible only on quantum machines with a huge number of qubits, and those do not yet exist. Whats more, qubits and their interactions must be robust against errors introduced through the effects of thermal vibrations, cosmic rays, electromagnetic interference and other sources of noise. These disturbances can cause some of the information necessary for the computation to leak out of the processor, a situation known as decoherence. That can mean dedicating a large proportion of the qubits to error-correction routines that keep a computation on track.

A circuit design for IBMs five-qubit superconducting quantum computer.Credit: IBM Research/SPL

This is where the scepticism about quantum computing begins. The worlds largest quantum computer in terms of qubits is IBMs Osprey, which has 433. But even with 2 million qubits, some quantum chemistry calculations might take a century, according to a 2022 preprint2 by researchers at Microsoft Quantum in Redmond, Washington, and ETH Zurich in Switzerland. Research published in 2021 by scientists Craig Gidney at Google in Santa Barbara, California, and Martin Eker at the KTH Royal Institute of Technology in Stockholm, estimates that breaking state-of-the-art cryptography in 8 hours would require 20 million qubits3.

Yet, such calculations also offer a source of optimism. Although 20 million qubits looks out of reach, its a lot less than the one billion qubits of previous estimates4. And researcher Michael Beverland at Microsoft Quantum, who was first author of the 2022 preprint2, thinks that some of the obstacles facing quantum chemistry calculations can be overcome through hardware breakthroughs.

For instance, Nicole Holzmann, who leads the applications and algorithms team at Riverlane, and her colleagues have shown that quantum algorithms to calculate the ground-state energies of around 50 orbital electrons can be made radically more efficient5. Previous estimates of the runtime of such algorithms had come in at more than 1,000 years. But Holzmann and her colleagues found that tweaks to the routines altering how the algorithmic tasks are distributed around the various quantum logic gates, for example cut the theoretical runtime to just a few days. Thats a gain in speed of around five orders of magnitude. Different options give you different results, Holzmann says, and we havent thought about many of these options yet.

At IBM, Garcia is starting to exploit these gains. In many ways, its easy pickings: the potential quantum advantage isnt limited to calculations involving vast arrays of molecules.

One example of a small-scale but classically intractable computation that might be possible on a quantum machine is finding the energies of ground and excited states of small photoactive molecules, which could improve lithography techniques for semiconductor manufacturing and revolutionize drug design. Another is simulating the singlet and triplet states of a single oxygen molecule, which is of interest to battery researchers.

In February, Garcias team published6 quantum simulations of the sulfonium ion (H3S+). That molecule is related to triphenyl sulfonium (C18H15S), a photo-acid generator used in lithography that reacts to light of certain wavelengths. Understanding its molecular and photochemical properties could make the manufacturing technique more efficient, for instance. When the team began the work, the computations looked impossible, but advances in quantum computing over the past three years have allowed the researchers to perform the simulations using relatively modest resources: the H3S+ computation ran on IBMs Falcon processor, which has just 27 qubits.

Part of the IBM teams gains are the result of measures that reduce errors in the quantum computers. These include error mitigation, in which noise is cancelled out using algorithms similar to those in noise-cancelling headphones, and entanglement forging, which identifies parts of the quantum circuit that can be separated out and simulated on a classical computer without losing quantum information. The latter technique, which effectively doubles the available quantum resources, was invented only last year7.

Michael Biercuk, a quantum physicist at the University of Sydney in Australia, who is chief executive and founder of Sydney-based start-up firm Q-CTRL, says such operational tweaks are ripe for exploration. Biercuks work aims to dig deeper into the interfaces between the quantum circuits and the classical computers used to control them, as well as understand the details of other components that make up a quantum computer. There is a lot of space left on the table, he says; early reports of errors and limitations have been naive and simplistic. We are seeing that we can unlock extra performance in the hardware, and make it do things that people didnt expect.

Similarly, Riverlane is making the daunting requirements for a useful quantum computer more manageable. Brierley notes that drug discovery and materials-science applications might require quantum computers that can perform a trillion decoherence-free operations by current estimates and thats good news. Five years ago, that was a million trillion, he says.

Some firms are so optimistic that they are even promising useful commercial applications in the near future. Helsinki-based start-up Algorithmiq, for instance, says it will be able to demonstrate practical quantum advances in drug development and discovery in five years time. Were confident about that, says Sabrina Maniscalco, Algorithmiqs co-founder and chief executive, and a physicist at the University of Helsinki.

Maniscalco is just one of many who think that the first commercial applications of quantum computing will be in speeding up or gaining better control over molecular reactions. If anything is going to give something useful in the next five years, it will be chemistry calculations, says Ronald de Wolf, senior researcher at CWI, a research institute for mathematics and computer science in Amsterdam. Thats because of the relatively low resource requirements, adds Shintaro Sato, head of the Quantum Laboratory at Fujitsu Research in Tokyo. This would be possible using quantum computers with a relatively small number of qubits, he says.

Financial applications, such as risk management, as well as materials science and logistics optimization also have a high chance of benefiting from quantum computation in the near term, says Biercuk. Still, no one is taking their eyes off the longer-term, more speculative applications including quantum versions of machine learning.

Machine-learning algorithms perform tasks such as image recognition by finding hidden structures and patterns in data, then creating mathematical models that allow the algorithm to recognize the same patterns in other data sets. Success typically involves vast numbers of parameters and voluminous amounts of training data. But with quantum versions of machine learning, the huge range of different states open to quantum particles means that the routines could require fewer parameters and much less training data.

In exploratory work with South Korean car manufacturer Hyundai, Jungsang Kim at Duke University in Durham, North Carolina, and researchers at the firm IonQ in College Park, Maryland, developed quantum machine-learning algorithms that can tell the difference between ten road signs in laboratory tests (see go.nature.com/42tt7nr). Their quantum-based model used just 60 parameters to achieve the same accuracy as a classical neural network using 59,000 parameters. We also need far fewer training iterations, Kim says. A model with 59,000 parameters requires at least 100,000 training data sets to train it. With quantum, your number of parameters is very small, so your training becomes extremely efficient as well.

Quantum machine learning is nowhere near being able to outperform classical algorithms, but there is room to explore, Kim says.

In the meantime, this era of quantum inferiority represents an opportunity to validate the performance of quantum algorithms and machines against classical computers, so that researchers can be sure about what they are delivering in the future, Garcia says. That is what will give us confidence when we start pushing past what is classically possible.

For most applications, that wont be any time soon. Silicon Quantum Computing, a Sydney-based start-up, has been working closely with finance and communications firms and anticipates many years to go before payday, says director Michelle Simmons, who is also a physicist at the University of New South Wales in Sydney.

Thats not a problem, Simmons adds: Silicon Quantum Computing has patient investors. So, too, does Riverlane, says Brierley. People do understand that this is a long-term play.

And despite all the hype, its a slow-moving one as well, Hensinger adds. Theres not going to be this one point when suddenly we have a rainbow coming out of our lab and all problems can be solved, he says. Instead, it will be a slow process of improvement, spurred on by fresh ideas for what to do with the machines and by clever coders developing new algorithms. Whats really important right now is to build a quantum-skilled workforce, he says.

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Quantum computers: what are they good for? - Nature.com

ParityQC licenses the intellectual property for it's quantum-computing architecture to other companies.Credit: Elisabeth Fitsch

Parity Quantum Computing in Innsbruck, Austria, spun off from the University of Innsbruck, Austria, in 2020.

In 2013, Wolfgang Lechner had an idea that he thought was probably too good to be true: a mathematical trick that would change how quantum computers encode information. If it worked, he reasoned, it would be a big deal. Quantum computers can, in theory, perform certain calculations many times faster than conventional digital computers, but they are extremely sensitive to interference and are hard to scale up. Lechners brainwave was to provide these computers with an architecture based on the concept of parity. This could transform them from small laboratory devices into vast, commercial machines capable of solving problems that are currently intractable.

Read more about The Spinoff Prize

Lechner, a physicist at the University of Innsbruck in Austria, discussed the proposal with a colleague, but they managed to persuade themselves that it was a non-starter. Over the next two years he kept turning the idea over in his mind, and says it became an obsession. Eventually, at 3 a.m. in a hotel room, he had a flash of inspiration that could mean his parity-based approach should work after all.

He quickly filed a patent and, just six months later, received an offer for the intellectual property from a large technology company. (Lechner declined to reveal the company or the size of the offer.) This told him that the architecture had commercial potential, and that it might be better to try to reap the rewards directly. So he and his colleagues at the University of Innsbruck decided to reject the offer and set up a spin-off company. ParityQC launched in 2020, and has been named a finalist in The Spinoff Prize 2023.

Three years on from its set-up, the company now employs about 30 people. It has landed sizeable contracts from high-tech manufacturers and from governments with one deal alone worth several tens of millions of euros. According to Lechners co-chief-executive Magdalena Hauser, this early success combined with grants from the European Union and the governments of Austria and Germany has meant that the company has avoided having to drum up support from venture capitalists. We made revenue from the start, says Hauser.

Quantum computers owe their calculating prowess to certain quantum phenomena of atomic-scale objects. These computers encode data in the form of qubits, which can exist as 0 and 1 at the same time unlike conventional bits, which exist as only one or the other. Multiple qubits can be entangled to generate all possible values from a string of 0s and 1s simultaneously, enabling parallel processing that is not possible with classical computers.

Part of Nature Outlook: The Spinoff Prize 2023

But qubits are fragile. Their states can be disrupted by the slightest amount of heat or other interference. Their durability varies according to the kind of physical qubit used ions, neutral atoms, superconducting circuits or quantum dots. They might remain intact for a few seconds if they are perfectly isolated or might disappear after milliseconds if they interact with other qubits during a calculation.

A second major issue for quantum computing is the spatial properties of qubits. The physical processes that link qubits to one another usually occur only over very short distances, such as the overlap of two electron clouds around atomic nuclei or the connection of two superconducting circuits. This means that each qubit typically interacts only with its nearest neighbours, rather than qubits farther away.

ParityQCs architecture helps quantum computers to deal with both limitations. It does so by changing how the data are encoded in qubits. Rather than representing the values of individual logical qubits as specified by the program being executed physical qubits instead record the relationship between pairs of logical qubits in terms of parity. If the qubits in a pair have the same value, then the parity is 1; if the values are different, then the parity is 0 (See Blueprint for quantum computing).

Credit: Alisdair MacDonald

This change in encoding to a system based on parity transforms all operations involving several qubits, no matter how far apart they are, into the equivalent of local interactions. That eliminates the need for interactions over long distances. And operations can be carried out on all qubits in a computer simultaneously, maximizing the complexity of calculations that can be performed in the brief period during which qubits remain intact.

Since dreaming up the parity architecture1, Lechner and his colleagues at ParityQC and the University of Innsbruck have gone on to have dozens of papers published that elaborate the scheme. In one of the most recent2, they have proposed a specific set of operations, or gates, that rely on parity encoding and have confirmed3 that this set would speed up several of the most important quantum algorithms devised so far. These include an algorithm that would allow quantum computers to find the prime factors of large numbers, posing a threat to Internet encryption schemes that rely on the difficulty of such calculations.

To turn this knowledge into revenue, ParityQC licenses its intellectual property to hardware developers so that they can build chips incorporating the architecture. According to Hauser, the company has sold licences to Japanese electronics giant NEC to produce a superconducting quantum chip, and has entered several consortia that were set up in response to the German government investing 2 billion (US$2.2 billion) to fund the development of quantum technologies.

Notably, the company jointly received an 83-million contract awarded by the German Aerospace Center in Cologne to build ion-trap computers. Along with manufacturers eleQtron in Siegen, Germany, and NXP Semiconductors in Eindhoven, the Netherlands, it won the contract to build a 10-qubit demonstration computer and then develop modular and scalable devices. (This type of computer is also being developed by another The Spinoff Prize 2023 finalist, Alpine Quantum Technologies, although Alpine is not part of ParityQCs collaboration.)

Sue Sundstrom, a start-up coach based in Clevedon, UK, and a judge for The Spinoff Prize 2023, is impressed by what she describes as ParityQCs analysis of how previously radically different technologies have been able to get into the market and make money. She notes a parallel with Arm in Cambridge, UK, a firm which started selling blueprints of chips for reduced-instruction set computers in the 1980s. She also praises the hiring of people with commercial expertise. For quantum companies that is quite rare, she says.

Fellow judge Emily MacKay, who is a technology strategist at Siemens Energy and is based in Cambridge, UK, applauds ParityQCs efforts to make its architecture scalable and applicable to various types of hardware. Their research approach is future-proofing as far as possible, she says. (Her comments on ParityQC do not necessarily reflect the views of Siemens Energy.)

But MacKay adds that the company faces an elephant in the room having to decide whether to compete or collaborate with the worlds biggest provider of cloud computing, Amazon Web Services. Lechner says that ParityQC would be an ideal supplier to the larger firm, arguing that its parity architecture is well suited to Amazon which plans to build quantum computers that mitigate errors, partly in hardware and partly through software. We are not in contact [with Amazon] at the moment but would be happy to [be], he says.

However, not all specialists are convinced that the parity architecture will achieve its desired results, at least when it comes to solving optimization problems (such as maximizing the return from a financial portfolio or minimizing the distance travelled by goods vehicles). Itay Hen, a numerical physicist at the University of Southern California in Los Angeles, questions whether a quantum computer fitted with the architecture could solve such problems more quickly than would a classical computer given what he says is the absence of any quantum algorithm that guarantees such an outcome. Even if we had the perfect quantum computer, we still wouldnt know whether it is better than a laptop, he says.

Lechner acknowledges that there is no general proof showing that quantum computers have an advantage over their classical counterparts when it comes to optimization problems. But he is confident that at some point in the next few years perhaps by around 2030 the parity architecture will enable a quantum computer to pass this milestone for one or more problems, with classically impossible optimization made possible by new algorithms that emerge. That is our dream, Lechner says, and the target we are working towards.

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Rewriting the quantum-computer blueprint - Nature.com

Source: Bartlomiej K. Wroblewski / Shutterstock.com

Quantum computing stocks are up on major news from an industry leader. Semiconductor producer Nvidia (NASDAQ:NVDA) announced a significant breakthrough today. Along with Rolls-Royce (OTCMKTS:RYCEY) and quantum computing innovator Classiq, the company has achieved something that stands to revolutionize jet engine efficiency. Nvidia laid out the following in a statement on May 21:

Using NVIDIAs quantum computing platform, the companies have designed and simulated the worlds largest quantum computing circuit for computational fluid dynamics (CFD) a circuit that measures 10 million layers deep with 39 qubits. By using GPUs, Rolls-Royce is preparing for a quantum future despite the limitations of todays quantum computers, which only support circuits a few layers deep.

This news came out over the weekend, yet it has helped spur a rally for quantum computing stocks so far this week. NVDA isnt currently rising, but its announcement has pushed several of its peers into the green. On top of it, other positive developments have helped generate further momentum for the sector.

As impressive as its recent breakthrough is, Nvidia has been trending downward all day, though it still remains in the green for the week. For other quantum computing stocks, though, it has been a smooth ride to the top. Things have gone much better for IonQ (NYSE:IONQ), which has surged about 40% over the past five days. Last week, it announced that its powerful IonQ Aria computer would be available through the Amazon (NASDAQ:AMZN) Bracket quantum computer service, sending shares up.

Quantum Computing (NASDAQ:QUBT) also reported a positive catalyst recently. The penny stock hasnt been enjoying the same type of growth as IonQ, but it has two reasons to celebrate. Aside from the quantum computing stocks rally, the company has received a follow-on task order to continue supporting NASA in its remote sensing and climate change monitoring. Quantum Computing has high hopes for its work in this field. As Chief Technology Officer Dr. William McGann states:

Our current prototype systems have shown outstanding performance in both pattern prediction and recognition, demonstrating good potential for sunlight noise removal. Through this project, we hope to prove the concept and develop a roadmap for future large-scale deployment to help NASA and many other potential customers.

This has also been a good day for Arqit Quantum (NASDAQ:ARQQ), which has risen 2% for the day. Like its penny stock peer QBUT, this company has spent the past week rising steadily as investor enthusiasm for quantum computing stocks continues to mount. This could be a turning point for the industry, especially as Nvidia continues its quest for market dominance. The company is already making significant headways in the artificial intelligence (AI) race, giving investors the type of exposure that they need. Now it is reminding everyone that it should also be counted as a leader among quantum computing stocks. As it rises, smaller cap companies can easily follow, as IONQ and QUBT have proven this week.

On Penny Stocks and Low-Volume Stocks:With only the rarest exceptions, InvestorPlace does not publish commentary about companies that have a market cap of less than $100 million or trade less than 100,000 shares each day. Thats because these penny stocks are frequently the playground for scam artists and market manipulators. If we ever do publish commentary on a low-volume stock that may be affected by our commentary, we demand thatInvestorPlace.coms writers disclose this fact and warn readers of the risk.

Read More:Penny Stocks How to Profit Without Getting Scammed

On the date of publication, Samuel OBrient did 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.com Publishing Guidelines.

Samuel OBrient has been covering financial markets and analyzing economic policy for three-plus years. His areas of expertise involve electric vehicle (EV) stocks, green energy and NFTs. OBrient loves helping everyone understand the complexities of economics. He is ranked in the top 15% of stock pickers on TipRanks.

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Why Are Quantum Computing Stocks ARQQ, IONQ, QUBT Up Today? - InvestorPlace