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Modern computers are incredibly versatile, but even the most potent ones struggle with certain types of calculations and modelling

Now, imagine an entirely different kind of computer, with head-spinning power, using mind-bending quantum mechanics to bring barely believable capabilities to life. A super super computer that can tackle calculations that the most powerful conventional machines would need decades to process in a split second. This contraption which resembles a baroque chandelier that could have hung at Versailles is a quantum computer.

They probably wont replace todays computers dont expect your next laptop to be a quantum device but they will be able to tackle certain boxed and highly complex tasks that force traditional computers to throw in the towel. If there are near-endless possible answers to a clearly defined problem, a quantum computer will find the solution much quicker than any conventional computer.

Quantum computers are powered by qubits (i.e., quantum bits), which, due to the strange properties of quantum mechanics, can exist in something called superposition, which in simplified terms means they exist in both 0 and 1 states simultaneously. Imagine flipping a coin. Itll eventually land on either heads or tails. But if you spin it, you could say that before it settles it is both heads and tails at the same time or, rather, there is a possibility that it can be either of the two. It is in superposition. In order to operate at scale, qubits need to be entangled wired together in superposition. Quantum entanglement, explains IBM, allows qubits, which behave randomly, to be perfectly correlated with each other.

Alas, superposition is fickle, and when decoherence forces a qubit out of superposition, it no longer possesses quantum properties. The solution is called error correction, and quantum computing pioneers like IBM, Microsoft and Google are hard at work making it happen.

For a more comprehensive explanation of quantum computing, check out this primer. And dont miss this irresistible video featuring IBM scientist Talia Gershon explaining quantum computers to five individuals from an eight-year-old to a theoretical physicist from Yale.

Possibilities for quantum use cases include predictive analytics and advanced modeling, which could help streamline and optimize large-scale transit operations and fleet maintenance, energy exploration, disaster prevention and recovery, as well as climate change mitigation. Also on the radar: chemistry simulations of molecules and atoms whose complex behavior is driven by quantum mechanics and simply too hard to handle for conventional machines.Meanwhile, automakers, including Volkswagen, are investigating quantum computing in search of improved battery chemistry for electric vehicles.

In oil refining, massively big machines, called hydrocrackers, are used to upgrade low-quality heavy gas oils into high-quality, clean-burning jet fuel, diesel and gasoline. Extremely complicated and costly to maintain, hydrocrackers may sit idle several months each year, but implementing a predictive modeling application has enabled hydrocracker operators to shave off months of downtime for these behemoths. The idea: Make all acute repairs when the machine is down and use technology to predict what might break next and fix it preemptively. Adding quantum-driven AI as the brain for the hydrocracker could further minimize downtime because the quantum computer could calculate exponentially more scenarios than current technology.

In another example of the immense potential of the technology, bright minds from the University of Glasgows School of Physics & Astronomy recently announced that they have adapted a quantum algorithm called Grovers algorithm to drastically cut down the time it takes to identify and analyze gravitational wave signals.

One of the most interesting use cases is artificial intelligence. Indeed, adding quantum power to AI could be what takes present-day Narrow AI to the next level General AI. The quantum-AI hydrocracker brain described above is a possible example of General AI. Quantum computing could also propel machines toward sentience within specific fields. Imagine computers perfectly empathizing and emulating emotions, with the ability to respond to complex signals, like expressions, eye movement and body language. Perhaps one day, quantum computing could drive us all the way to that barely fathomable third level of AI Super AI where machines outperform humans in every way.

Todays quantum machines are scientific marvels, and they are evolving rapidly. By [2025], IBM says, we envision that developers across all levels of the quantum computing stack will rely upon our advanced hardware with a cloud-based API. The hope is that by 2030, companies and users are running billions, if not a trillion quantum circuits a day. Big Blue, whose most powerful machine currently packs 126 qubits, expects to have an 1121-qubit version in 2023.

Quantum computing is fascinating, promising and just cool. Still, we may need to slow the hype machine down a tad as significant challenges must be overcome before the technology can be commercialized. Functional, stable, production-scale quantum machines could be up to a decade away. But once they materialize, we can start writing software for the quantum stack and begin to realize all these tantalizing quantum computing use cases.

About the Author

Wolf Ruzicka is Chairman atEastBanc Technologies.Wolf is a technology industry veteran with more than 25 years of experience leading enterprise business strategy and innovation. He joined EastBanc Technologies in 2007, originally as CEO. During his tenure, Wolf also served as President of APIphany, a division of EastBanc Technologies, through its acquisition by Microsoft. Wolfs vision and customer-centric approach to digital transformation is credited for helping establish EastBanc Technologies as a leader delivering sophisticated solutions that enable customers to win in todays digital economy. Follow Wolf on LinkedIn.

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A Quantum Leap in the Making Meet Tomorrow's Super Super Computers - TechNative

The semiconductor nanosheets in the water-cooled copper mount turn an infrared laser pulse into an effectively unipolar terahertz pulse. The team says that their terahertz emitter could be made to fit inside a matchbox. Image credit: Christian Meineke, Huber Lab, University of Regensburg

A laser pulse that sidesteps the inherent symmetry of light waves could manipulate quantum information, potentially bringing us closer to room temperature quantum computing.

The study, led by researchers at the University of Regensburg and the University of Michigan, could also accelerate conventional computing.

Quantum computing has the potential to accelerate solutions to problems that need to explore many variables at the same time, including drug discovery, weather prediction and encryption for cybersecurity. Conventional computer bits encode either a 1 or 0, but quantum bits, or qubits, can encode both at the same time. This essentially enables quantum computers to work through multiple scenarios simultaneously, rather than exploring them one after the other. However, these mixed states dont last long, so the information processing must be faster than electronic circuits can muster.

While laser pulses can be used to manipulate the energy states of qubits, different ways of computing are possible if charge carriers used to encode quantum information could be moved aroundincluding a room-temperature approach. Terahertz light, which sits between infrared and microwave radiation, oscillates fast enough to provide the speed, but the shape of the wave is also a problem. Namely, electromagnetic waves are obliged to produce oscillations that are both positive and negative, which sum to zero.

The positive cycle may move charge carriers, such as electrons. But then the negative cycle pulls the charges back to where they started. To reliably control the quantum information, an asymmetric light wave is needed.

The optimum would be a completely directional, unipolar wave, so there would be only the central peak, no oscillations. That would be the dream. But the reality is that light fields that propagate have to oscillate, so we try to make the oscillations as small as we can, said Mackillo Kira, U-M professor of electrical engineering and computer science and leader of the theory aspects of the study in Light: Science & Applications.

Since waves that are only positive or only negative are physically impossible, the international team came up with a way to do the next best thing. They created an effectively unipolar wave with a very sharp, high-amplitude positive peak flanked by two long, low-amplitude negative peaks. This makes the positive peak forceful enough to move charge carriers while the negative peaks are too small to have much effect.

They did this by carefully engineering nanosheets of a gallium arsenide semiconductor to design the terahertz emission through the motion of electrons and holes, which are essentially the spaces left behind when electrons move in semiconductors. The nanosheets, each about as thick as one thousandth of a hair, were made in the lab of Dominique Bougeard, a professor of physics at the University of Regensburg in Germany.

Then, the group of Rupert Huber, also a professor of physics at the University of Regensburg, stacked the semiconductor nanosheets in front of a laser. When the near-infrared pulse hit the nanosheet, it generated electrons. Due to the design of the nanosheets, the electrons welcomed separation from the holes, so they shot forward. Then, the pull from the holes drew the electrons back. As the electrons rejoined the holes, they released the energy theyd picked up from the laser pulse as a strong positive terahertz half-cycle preceded and followed by a weak, long negative half-cycle.

The resulting terahertz emission is stunningly unipolar, with the single positive half-cycle peaking about four times higher than the two negative ones, Huber said. We have been working for many years on light pulses with fewer and fewer oscillation cycles. The possibility of generating terahertz pulses so short that they effectively comprise less than a single half-oscillation cycle was beyond our bold dreams.

Next, the team intends to use these pulses to manipulate electrons in room temperature quantum materials, exploring mechanisms for quantum information processing. The pulses could also be used for ultrafast processing of conventional information.

Now that we know the key factor of unipolar pulses, we may be able to shape terahertz pulses to be even more asymmetric and tailored for controlling semiconductor qubits, said Qiannan Wen, a Ph.D. student in applied physics at U-M and a co-first-author of the study, along with Christian Meineke and Michael Prager, Ph.D. students in physics at the University of Regensburg.

Collaborators at Justus Liebig University Giessen and Helmut Schmidt University, both in Germany, contributed to the experiment and the characterization of the nanosheets.

This research was supported by the German Research Foundation (DFG), W.M. Keck Foundation and the National Science Foundation.

Study: Scalable high-repetition-rate sub-half-cycle terahertz pulses from spatially indirect interband transitions (DOI: 10.1038/s41377-022-00824-6)

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Emulating impossible 'unipolar' laser pulses paves the way for processing quantum information - University of Michigan News

While the terms might be more familiar to fans of old-fashioned cowboy films, white hat and black hat have found modern relevance in the world of computer hacking.

In the black-and-white cowboy films of yesteryear, the concept of the white hat vs. the black hat was originally developed to help audiences easily identify the hero and the villain. Today, these terms are now used to identify two types of hackers: white hat hackers and black hat hackers.

Much like their cowboy inspiration, white hat hackers are considered to be in the hero camp, as they perform a valuable public service by stress-testing technology and looking for security vulnerabilities so they can be fixed before theyre exploited by their black hat counterparts.

Black hat hackers, cybersecuritys villains, are out for money, power, and chaos, using their talents to enrich themselves at the expense of others well-being.

To learn more about how to become a white hat hacker, we sat down with Avast Chief Information Security Officer (CISO) Jaya Baloo to get her inside perspective on what white hat hackers do, how to become a white hat hacker, and why their work is so crucial to cybersecurity at large.

Whether we notice it or not, cybersecurity is a huge part of each of our daily lives and its time to start paying attention if we want to be safe.

We live in a connected world that is poised to become even more connected in the future. Not only will we be more intrinsically connected to each other, but all of our devices will be interconnected as well.

If the future is going to be made up of smart devices, that means we need to get smarter, too.

Making sure the future of security is simple and accessible to everyone is one of Baloos main missions as a white hat hacker.

As new technology emerges, were seeing an increasing digital divide between the haves and have nots and not only when it comes to the elderly and younger generations, says Baloo. During my travels, Ive seen such stark challenges when it comes to tech adoption across the world, which is why its so important for me that security stays affordable and accessible to the most vulnerable populations.

Before joining our team in 2019, Baloo was CISO at KPN, the largest telecommunications carrier in the Netherlands, where she built and led KPNs security team for seven years, directing the team to defend not only KPN but most of the critical infrastructure in the Netherlands.

Before leading her team at KPN, Baloo worked as a Technical Security Specialist at France Telecom, following a number of years working at different telcos like Verizon. Outside of Avast, Baloo is also Vice-Chair of the EU Quantum Flagship, a billion-euro R&D program for quantum technologies, and a faculty member of Singularity University.

But despite her impressive history and list of credentials, Baloo calls her entire career in security an accident.

She was inspired to study computers after receiving one for Christmas at the age of nine. Although she didnt have access to the internet until she turned 12 (with a dial-up connection), Baloo was a quick fan. After maxing out the familys CompuServe bill, her parents canceled the service, leaving Baloo on her own to find different avenues to get back online.

She soon learned about local dial-up systems through online chat rooms and decided to try to find one by setting up a wardialing programa technique which involves automatically scanning lists of phone numbers in a local area code to search for modems, computers, bulletin board systems (i.e., computer servers), and fax machines. As Baloo recalls, I was that desperate to get back online!

Since then, Jaya has used her powers for good and works towards a safer and more secure digital world.

Baloos passion to be online was intense, but she didnt always have a big community to back her up or inspire her.

When I was really young, I was the only girl in my class who was really interested in computers and getting one and playing with them.

At the time, Baloo only thought of technology as a hobby, the ultimate consequence of, If you cant see it, you cant be it.

According to Baloo, I suppose that came from the fact that I was the only girl. I never considered it as a potential for a professional choice because there were no female examples.

Today, Baloo is leading by example to redefine the image of who can be a white hat hacker.

At the EU Quantum Flagship, for example, Baloo is one of few security people holding the position of Vice Chair; most of the other members are leading physicists. Together, the group provides insight into quantum computing developments and calls for action to continue the development of solutions to mitigate security concerns.

Baloos job is to make sure they stay ahead of the curve.

If we allow it to, quantum computing will revolutionize fundamental science. But if we lead from only a security threat standpoint, only worrying about security threats, it will not progress.

Baloo calls her position at EU Quantum Flagship the greatest achievement of her career a long way from the days when she felt being a girl who was interested in technology was a quirky, weird thing about [her.]

Today, she underscores the important role that white hat hackers play, not just in cybersecurity, but in the world at large. And she encourages young women and students to join her.

Admittedly, getting started on the good side of cybersecurity can feel a bit like being The Lone Ranger, at times. Especially in infosec, Baloo shares, there tends to be a lot of competition and pitting people against each others relevant experience or technical merit. This scares a lot of people off.

But Baloo rallies young women and students to not walk away from the challenge.

Hold onto your passion, and dont be afraid of being wrong. Its the only way to learn something new.

To stay informed in a constantly evolving field, Baloo recommends leaning into self-study and community outreach by reading frequently, observing discussions on social media, and listening to researchers at conferences.

The Wild West landscape may have changed, but the threat of black hat villains is not so different than it was years ago.

Instead of black hat cowboys with handlebar mustaches, black hat hackers are now the villainous outlaws, attacking everyone from government institutions to remote workers around the world.

Society needs white hat hackers to triumph over these threats. And today, everyone has the opportunity to become the hero.

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Become a Cybersecurity Hero: An Interview with a White Hat Hacker - Security Boulevard

The Nobel Prize-winning physicist discusses free will, time travel, and the relationship between innovation and scientific discovery.

Todays scientific landscape teems with conversations and interactions between scientists and humanists. The cutting edge of new knowledge is the product of collaboration across traditional disciplinary boundaries; it emerges, I believe, from places where researchers from diverse backgrounds come together to solve concrete problems.

This is the premise that sparked the idea for my book Is the Universe a Hologram? Scientists Answer the Most Provocative Questions, which comprises a series of interconnected dialogues with leading scientists who are asked to reflect on key questions and concepts about the physical world, technology, and the mind. These thinkers offer both specific observations and broader comments about the intellectual traditions that inform these questions; in doing so, they reveal a rich seam of interacting ideas.

When the book went to press a few years ago, I hadnt yet had a chance to sit down with Frank Wilczek, the Nobel Prize-winning physicist whose work Ive long admired. Our conversation which took place in 2020 during his visit to the city of Valencia, Spain, as a member of the jury of the prestigious Rei Jaume I Awards made its way into the recently published Spanish edition of the book titled De neuronas a galaxias (From neurons to galaxies). Im so pleased to share our discussion, translated and edited for length, below.

Adolfo Plasencia: Professor Wilczek, lets jump right into a difficult but, I think, fascinating subject. In my dialogue with the physicist Ignacio Cirac, a pioneer in the field of quantum computing, he said that quantum physics in a way takes into account free will. Its a bold statement, and Ive been eager to get your take on it. Do you agree with Cirac?

Frank Wilczek: I think the question can be understood in two different ways. So let me answer each of them separately.

The first interpretation is to ask whether quantum mechanics explains the phenomenon of free will, or whether there is something else that must be taken into account in our description of the world which is not within the scope of quantum mechanics or which is not within physics as we understand it. And the answer is that we dont really know for sure. But there seems to be a very good hypothesis that I think scientists are in fact adopting, and it is that the phenomena of mental life, including free will, can be derived from the physical embodiment of mind in matter. So what we call emergent phenomena are qualitatively different behaviors that can be very difficult to see in the basic laws but can emerge in large systems with many components that have a rich structure. So, for example, when neurobiologists study the nervous system, when they study the brain, they adopt the working hypothesis that thought, memory all mental phenomena have a physical basis, have a physical correlate.

Another aspect is that you can ask yourself if, when we do physical experiments, we have to add something else that is mental. Do we have to make corrections for what people are thinking? Physicists now do very refined, precise, delicate experiments in which corrections have to be made for all sorts of things. You have to make corrections for trucks that pass by, you have to make corrections for electric and magnetic fields, you have to control the temperature very precisely, and so on, but something that people have never needed before is to make corrections related to what people are thinking. So I think there is very good circumstantial evidence that the world, the physical world, is not influenced by a separate mental world.

I believe that the barriers that physicists are encountering are not barriers of principle, but barriers of technique.

The second interpretation of the question is whether in the formulation of quantum mechanics one should involve the observer as a separate object that has free will, that decides what to observe. Quantum mechanics has an unusual mechanism since the theory has equations, and to interpret the equations one must make an observation. I believe that, eventually, in order to understand the phenomena of free will on a physical basis, and thus fully understand quantum mechanics, we will need to understand that we have that model of consciousness that corresponds to our experience of everyday life, which is fully based on quantum mechanics. At present, I dont think we have that. However, I believe that the barriers that physicists are encountering are not barriers of principle, but barriers of technique.

We are not advanced enough in quantum mechanics to make models where we can identify something wed begin to recognize as consciousness. Thats a big challenge for the future. But we have every reason to believe that this challenge can one day be met. So what we need is a model thats fully quantum mechanical and contains complicated objects that you can point to and say, thats behaving like a conscious mind and that thing is something I can recognize as a thinking entity. Part of the trouble, of course, is that the definition of consciousness is very slippery.

AP: Your response reminds me of something someone quipped to me after seeing the table of contents of my book and reading the discussion with Cirac: So physicists are now getting into philosophy too?

FW: Physicists have always been philosophers. In fact, historically, the beginnings of philosophy and of natural science, in ancient Greece, involved the same set of people. People like Pythagoras and Thales and Plato did not consider themselves philosophers or physicists, they were both. They developed the main issues of both disciplines, somehow, together, from the very beginning. Now, in recent years physics has become much more sophisticated and has become separated from academic philosophy, which is a discipline in itself, has its own techniques and body of academic literature, and so forth.

However, I dont think physicists should give up the enterprise of attempting to understand the world fully. They have made many advances in understanding the physical world, with precision, accuracy, and great depth, and I dont think this disqualifies them from addressing the classic questions of philosophy. On the contrary, I think that empowers them so that they can bring in new kinds of insights into what have become the traditional philosophical questions.

And I think many physicists have not wanted to do that, either because they are busy with physics or because they dont dare, but I think it is perfectly appropriate for physicists to also be philosophers. In fact, I think they should be, because many of the ideas weve learned about the physical world in physics are very surprising things that you wouldnt guess from everyday experience so I think we have things to teach philosophers. Especially since quantum mechanics is really a vast expansion of what we mean by reality, and it requires adjusting how you think. If you want to be a serious student of reality or of mind you really should know quantum mechanics. To me, a philosopher who doesnt know quantum mechanics is like a swimmer with his or her hands tied behind their back.

To me, a philosopher who doesnt know quantum mechanics is like a swimmer with his or her hands tied behind their back.

AP: Lets move into what Ill call the weird ideas questions stuff Ive been wondering about, as a non-scientist, coming from a position of great ignorance but with deep curiosity. If theres any known symbol or idea about quantum physics that for ordinary people clashes with everyday logic, thats the subject of Schrdingers cat. Dont you think its difficult to explain to people that, not knowing if the cat is dead or alive, when you try to find out, you come to the conclusion that the cat is both dead and alive at the same time? That is something rather strange, counterintuitive, even to university students who study the subject.

FW: There are many situations when you describe them by probability that you dont know before you observe what you will observe. That, almost by definition, is what probability means. You dont know what you can find when you look into it, when you make the observation, when you pick from a sample, or whatever, but the quantum mechanical situation is a little bit different. What makes it paradoxical is that there is a very real sense in which the cats alive state and dead state possibilities coexist in a way that is not true in classical situations. Now, this coexistence is not a practical situation for cats, but we can talk about a similar situation for atoms, and it does become practical for atoms. But, in the spirit of your question, let me go back to talking about cats.

In principle lets assume that after some time T, the probability of having a cat alive or the probability of having a cat dead, according to quantum mechanics, is predicted to be 50/50, so each of them is equally likely. We have that situation, and we can check it and experiment, so we have a lot of cats, and we can do the same experiment over and over again. But quantum mechanics tells you that if you do certain operations after that time T you can reverse the situation so that the cat will be certainly alive or that the cat will be certainly dead and both of those possibilities were present and you could restore them by doing different things to the initial situation, to the initial wave function.

So what is different about quantum mechanics, is that those two possibilities are not mutually exclusive, they both coexist in the situation and what happens when you observe is you find out whats called collapse of the wave function. You fix one possibility, but before you made the observation, before you intervened in the situation, both were present. And if you dont intervene, but let the systems stay close, dont observe it, manipulate it with some fields, never looking in to know if the cat is alive or dead, you can reverse the evolution and make it totally alive or you can make it totally dead. For real cats this is not practical at all, but it is for atoms If you are not talking about a live cat or a dead cat but about the spin of an atom, pointing up or down, you can literally do these things you can create a situation where there is a 50/50 percent chance that the spin is up or the spin is down, but then, by operating on that wave function, without observing, just operating on it, you can show that either possibility was really present.

AP: So you believe that quantum superposition is part of human logic

FW: Oh, yes! Well, some human beings do physics and quantum mechanics pretty successfully. You know, I do quantum mechanics sometimes and I make mistakes occasionally, but Ive always been able to correct them. There is no real doubt about how you apply quantum mechanics to physical situations; there are right and wrong answers. It can be hard to think about there are sometimes very counterintuitive aspects of quantum mechanics. You have to sort of take yourself outside the realm of common sense and think about some things differently, because if you did apply common sense you would get the wrong answer. Sometimes, it is only necessary to follow the equations. But you know, there are many people who practice quantum mechanics very successfully and use it in design of computers and all kinds of other strange gadgets, use it to do very many concrete things. It is certainly not beyond human comprehension.

You have to sort of take yourself outside the realm of common sense and think about some things differently, because if you did apply common sense you would get the wrong answer.

AP: All right, lets move on to the next issue: time travel. An article you published in Quanta magazine some time ago digs into the concept of the arrow of time, which was coined by Arthur Eddington almost 100 years ago but remains an unsolved problem of modern physics. This idea postulates the one-way direction or asymmetry of time. Let me just ask you directly: Why does time travel only work in science fiction, and therefore in the imagination, and not in our everyday reality?

FW: Well, this is a very complex question. Not only in content but also in formulation. So, let me try to boil your question down to essentials. One aspect is, what do physicists mean when they talk about a universal symmetry? Since you cant actually reverse [in the reality in which we live] the direction of time it sounds like metaphysics to say: Okay, if we reverse the direction of time, such and such and such will happen.

But, actually, it means something very concrete. It means if you have a physical situation where particles are moving with certain velocities, so at some initial moment you know where they are and what direction they are moving these are based on certain equations you can also discuss the situation where you struck with particles in the same space but moving in the opposite direction. So that if you change (in the equations) the direction of time, they would be moving in the opposite direction instead. You can see whether those two situations are governed by exactly the same equations.

Time reversal symmetry simply says that if you reverse the directions of rotation and the speeds of everything in your system, you will see that it is based on the same equations as if you did not. So that is what time reversal means very concretely for physicists. There are many details that are more complicated, that have to do with the spin and have to do with exotic kinds of particles. But thats the idea. And, we find in physics that that principle works very, very accurately. Not perfectly but very, very accurately. But in everyday life it doesnt seem that way. It doesnt seem that the direction of time forwards and backwards is experienced in the same way in our lives. Of course, it definitively isnt.

So, how is that consistent with the experiment I mentioned? Well, first of all, we cannot, as a practical matter, in any complicated system, let alone a human body, change the direction that every particle is moving. So you cant really do it, in practice. You cant get the direct consequence of the underlying time-reversal symmetry. The past and the future are very different and there is a long story about why that is, even though the basic equations look the same forwards and backwards. And I dont think its appropriate to get into that whole story now, but let me say something. The essence of it is that, in the beginning, at the very early stage of the universe, the universe was much hotter and denser and was expanding. That was the Big Bang. And the Big Bang was in the past, not in the future. So that tells you that things were very different in the past and that we are heading toward a future that is very different from the origin (of the universe). And by a long series of arguments about the formation of structure and the universe cooling down and so on, you can sketch a history of the universe that makes sense and accords with our experience of time going in only one direction, although in the fundamental equations, we would have the same behavior if it moved in the opposite direction.

AP: Whew, all right. Sci-fi writers beware

FW: I mean, it is a very intriguing possibility in principle that of reversing the direction of the motion of particles and getting them to reverse their evolution in time so that they reconstitute their state at an earlier time. Maybe if we did that for some key molecules, to reverse aging, for example. But in practice, we dont know what, if any, key elements we need to reverse, and so, the time-reversal symmetry of the fundamental laws does not help us in anything that is very practical for us.

AP: Finally, I want to ask you about something important to me, but not explicitly related to physics. I write and publish a lot about innovation, which has been a buzzword for decades and seems to still be. Everyone these days, from entrepreneurs to politicians, has to innovate. How do you view this term, its notion, and its meaning today, from your point of view as a scientist, but also just as a citizen? What differences do you see between the concepts of discovery, invention, and innovation in the world we live in now?

FW: I think we live in a very special time now, because of the means of communication and the aids to thinking that we have electronics and microelectronics and computer technology and telecommunication. With all these things, people can exchange ideas much more efficiently. People can get together and think. And on the other hand, there is more to think about because the technology is very powerful and we understand matter very, very well. So we can design things based on imagination and planning and be sure that they work or at least be pretty confident that they will work. So thats innovation kind of exploding our knowledge of the world in order to make improvements here and there. And, to me, as a physicist, I am very proud that so much innovation has emerged from a profound understanding of the physical world and reality, that was provided originally by people who were just curious about how the physical world works, and in particular, the quantum world that we were talking about.

All microelectronics, transistors, semiconductors, etc. wouldnt exist without a profound understanding of matter that physics produced during the 20th century. And this isnt over yet. We understand, but we have not exhausted the potential thats been opened up by this profound understanding of the world. In fact, the theory itself tells us that there is much more room for improvement. Richard Feynman, one of my heroes, gave a famous talk in 1959 called Theres plenty of room in the bottom, which anticipated the richness of the micro-world: There are many, many, many atoms in even small things. And if you can work skillfully with them, you can do little machines, you can do useful things, in medicine, and in computing, of course. In principle, he foresaw this would open up various possibilities in many directions; of course he couldnt predict the details but he pointed in that direction. And now we see them embodied in microelectronics, nanotechnology, and modern telecommunications. All these things come from understanding this microcosmic world really well, in great detail and depth. A recent Nobel Prize in Chemistry was awarded for building molecules that function as motors and understanding how to do that. So, in many ways, this fundamental science is opening up new possibilities for innovation.

Now, you asked me about the relationship between innovation and scientific discovery. I think they kind of shade into each other. But basically science, curiosity-driven basic science is more long-term. It doesnt focus on goals that you know how to reach, and you just want to reach them quickly or efficiently. It takes us into unknown territory, where we dont know what were doing or why were doing it. But that kind of thing provides new possibilities for innovation later. So I would say that scientific research is continuous with innovation, it is a long-term curiosity-driven enterprise. While short-term innovation harvests the fruit of discovery.

Adolfo Plasencia is a writer and columnist who covers science and technology, and the author of Is the Universe a Hologram? Scientists Answer the Most Provocative Questions.

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'Physicists Have Always Been Philosophers': In Conversation With Frank Wilczek - The MIT Press Reader

Classiq, the leader in quantum computing software, today announced theClassiq Coding Competition, rewarding those that create highly-efficient quantum circuits to solve important real-world problems. The Classiq Coding Competition is the first competition focused on quantum efficiency. Quantum computers have limited resources, so building compact, optimized solutions that can make maximum use of those resources is critical.

Creating efficient quantum algorithms is part engineering, part art. The Classiq Coding Competition is a call to the worlds quantum software community to showcase their talents and demonstrate how quantum computing can take humans to new heights, said Classiq CEO Nir Minerbi. Efficient circuits enhance the ability of any quantum computer to solve important problems.

The Classiq Coding Competition will consist of four problems and will award 17 cash prizes. The top entry for each of the four problems will receive $3,000, while $1,500 and $500 will be awarded for the second and third places in each problem. Classiq will also award several $1,000 prizes to creators of the best innovative solutions as well as to the most promising youth participants under the age of 18. In addition, first-place winners will be profiled inThe Quantum Insider.

A panel of esteemed judges will determine the winners. The judges are:

For some problems, the winning entries will be those that create a working circuit with the fewest two-qubit gates, while others will seek to minimize the circuit depth. Classiq will reveal the Classiq Coding Competition winners in mid-June.

You would be surprised how much can be achieved with compact, efficient circuits, said Minerbi. The onboard computer used in the Apollo 11 space mission got a man to the moon using just 72 kilobytes of ROM. Quantum computing is taking off, and the need to create elegant and efficient quantum algorithms will exist for years to come. Organizations that manage to fit larger problems into available computers will reap their quantum benefits sooner than others. The Classiq Coding Competition will encourage the creativity and ingenuity required to make this happen and highlight the art of the possible in compact, efficient circuits.

The Classiq Coding Competition is open to all parties worldwide, except Classiq employees and their families. Clickhereto learn about and register for the Classiq Coding Competition.

About Classiq

Classiq is the leader in quantum computing software, provides a development platform built for organizations that want to jumpstart and accelerate their quantum computing programs. Classiqs patented CAD for quantum software engine automatically converts high-level functional models into optimized, hardware-aware circuits. Customers use the Classiq platform to build sophisticated algorithms that could not otherwise be created, bypassing the need to work at the quantum assembly level. Backed by powerful investors such as HPE, HSBC, Samsung NEXT, NTT and others, Classiq has raised more than $50 million since its 2020 inception, built a world-class team of scientists and engineers, and distilled decades of their quantum expertise into its groundbreaking platform. With Classiq, customers can push the envelope of whats possible in quantum software, build valuable IP blocks, explore quantum solutions for real-life problems, and prepare to take full advantage of the coming quantum computing revolution.To learn more, follow Classiq onLinkedIn,TwitterorYouTubeor visitwww.classiq.io.

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Classiq Announces the Classiq Coding Competition a $25K Challenge to Encourage Innovation and Build the World's Best Quantum Circuits - StartupHub.ai