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Time May Actually Be One Big Illusion, New Study Says – Popular Mechanics

Time has puzzled scientists for many decades. Does it meaningfully exist apart from our experience of it as everything moves toward the disintegration of

In new research published in the American Physical Society's peer-reviewed journal Physical Review A, scientists from Italy (led by Alessandro Coppo) try to translate one theory of time into real lifeor, at least, closer to it. The theory is called Page and Wootters mechanism, and Coppo has studied it for years. Its a quantum mechanics idea that dates back to 1983.

While general relativity (in the classical physics model) lets time be a variablelike the perception-dependent difference between time on Earth and time in space in stories like Interstellarquantum physics requires it to be nailed down. That means instead of a dependent variable (something defined by an external property, like local gravity or an objects distance from Earth), time must be independent, and there must be some way to measure it as such.

This may seem counterintuitive. After all, quantum mechanics is considered the newer version of thingsthe one that destabilizes the foundation of physics in order to be reconciled with the classical model. But time has a unique role in quantum systems. After all, everything in a particular time, defined in some objective way, is knitted together through quantum interactions until it forms a capture of the entire universe (if you zoom out enough).

In their paper, Coppo and his coauthors turn the Page and Wootters approach into a real concept for a clock. Within quantum physics, a clock isnt much like the one you wear on your wrist or hang in your officeits anything that has a predictable and uniform behavior that can be used as a measurement. (For example, this 2021 Quanta article lists increasingly stinky garbage as a kind of clock!)

New Scientist explains that Page and Wootters wondered if our world is so quantumly entangled within itself that any visible passing of time is a symptom of entanglement. They also suggested that we ourselves are implicated in that entanglement just by seeing the passage of timebecause someone outside of the entangled system would see it standing still. The clock, therefore, is the item within the entangled system that shows time passing.

Its easy to see why this theory has stayed mostly abstract for over 40 years. To turn it into something with measurements based in real life observation, scientists took iconic physics equations and restricted them to conditions that match the Page and Wootters scenario. They considered two systems that are entangled but do not interact, where one system is a harmonic oscillatorlike a quartz timing in a watch, or a pendulum.

Their solution may prove to be consistent within classical and quantum mechanics, because when enough particles are placed into each quantum systemwhen it reaches the threshold called macroscopic, based on massthe systems align with classical physics as well.

Thats a big dealif our entire, very macroscopic world fits into this definition of time based on entanglement, it means everything around us is entangled. Things would need to be entangled almost by definition in order to be part of our observable world. And it would mean that anything we see where time passes (no matter how far away it is) is linked with us in a vital way.

Caroline Delbert is a writer, avid reader, and contributing editor at Pop Mech. She's also an enthusiast of just about everything. Her favorite topics include nuclear energy, cosmology, math of everyday things, and the philosophy of it all.

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From Theory to Reality: Scientists Unveil Quadruple-Q Hedgehog Lattices – SciTechDaily

Recent discoveries in materials such as manganese germanide have unveiled structures that behave like magnetic monopoles. Researchers have identified new dynamic properties in these structures, potentially paving the way for innovative technologies in spintronics and fundamental physics research. Credit: SciTechDaily.com

Magnetic monopoles are elementary particles with isolated magnetic charges in three dimensions. In other words, they behave as isolated north or south poles of a magnet. Magnetic monopoles have attracted continuous research interest since physicist Paul Diracs first proposal in 1931.

However, real magnetic monopoles have not yet been observed and their existence remains an open question. On the other hand, scientists have discovered quasi-particles that mathematically behave as magnetic monopoles in condensed matter systems, resulting in interesting phenomena.

Recently, researchers discovered that a material called manganese germanide (MnGe) has a unique periodic structure, formed by special magnetic configurations called hedgehogs and antihedgehogs, which is called a magnetic hedgehog lattice. In these special configurations, the magnetic moments point radially outward (hedgehog) or inward (antihedgehog), resembling the spines of a hedgehog. These hedgehogs and antihedgehogs act like magnetic monopoles and antimonopoles, serving as sources or sinks of emergent magnetic fields.

The collective excitation modes of hedgehog lattices are governed by oscillation of Dirac strings, connecting a hedgehog and an antihedgehog, which can be used to study their spatial configuration in magnets. Credit: Masahito Mochizuki from Waseda University

MnGe exhibits what is known as a triple-Q hedgehog lattice. However, recent experiments have shown that the substitution of Ge with Si (MnSi1-xGex) transforms the arrangement into the quadruple-Q hedgehog lattice (4Q-HL). This new arrangement, also found in the perovskite ferrite SrFeO3, provides a promising avenue for studying and controlling the properties of hedgehog lattices. Moreover, these magnetic monopoles can also induce electric fields through moving following Maxwells laws of electromagnetism. To understand the resulting new physical phenomena, it is essential to study the inherent excitations of hedgehog lattices.

In a recent study, Professor Masahito Mochizuki and Ph.D. course student Rintaro Eto, both from the Department of Applied Physics at Waseda University, theoretically studied the collective excitation modes of 4Q-HLs in MnSi1-xGex and SrFeO3. Our research clarified the unknown dynamical nature of emergent magnetic monopoles in magnetic materials for the first time. This can inspire future experiments on hedgehog-hosting materials with applications in electronic devices and for bridging particle physics and condensed-matter physics, says Mochizuki. Their study was published in the journal Physical Review Letters on 31 May 2024.

Utilizing the three-dimensional Kondo-lattice model, the researchers reproduced the two distinct 4Q-HLs found in MnSi1-xGex and SrFeO3 and analyzed their dynamical properties. They discovered that the 4Q-HLs have collective excitation modes associated with the oscillation of Dirac strings. A Dirac string is a theoretical concept in quantum mechanics that describes a string that connects a magnetic monopole and a magnetic antimonopole, in this case, a hedgehog and an antihedgehog.

The researchers found that the number of these excitation modes depends on the number and configuration of Dirac strings, offering a way to experimentally determine the spatial configuration of hedgehogs and antihedgehogs and their unique topology in real magnets such as MnSi1-xGex and SrFeO3. This finding offers insights into the dynamics of hedgehog lattices in other magnets as well. Moreover, the finding enables us to switch on and off the excitation modes through controlling the presence or absence of the Dirac strings with external magnetic field.

Explaining the significance of their results, Eto remarks, The collective spin excitation modes revealed in the study are elementary excitations that directly reflect the presence (or absence) of emergent magnetic monopoles. Thus, our findings will be a fundamental guideline for studying the more detailed dynamical nature of emergent monopoles in magnetic materials in the future. Moreover, they might become the building blocks of novel field-switchable spintronic devices such as nano-sized power generators, light-voltage converters, and light/microwave filters based on emergent electromagnetism.

These discoveries have the potential to open new research avenues in fundamental physics and lead to the development of new technologies involving emergent magnetic monopoles in magnets.

Reference: Theory of Collective Excitations in the Quadruple- Magnetic Hedgehog Lattices by Rintaro Eto and Masahito Mochizuki, 31 May 2024, Physical Review Letters. DOI: 10.1103/PhysRevLett.132.226705

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Quantum entanglement precisely measures Earth’s spin for first time – Study Finds

VIENNA In 1913, French physicist Georges Sagnac demonstrated that light travels at different speeds in opposite directions in a spinning frame of reference an effect that came to be known as the Sagnac effect. Over a century later, a team of physicists at the University of Vienna has given this classic experiment a quantum twist. By injecting entangled photons into a rotating fiber optic setup, theyve measured the rotation of the Earth itself with unprecedented precision, opening up exciting new possibilities for probing the intersection of quantum mechanics and gravity.

The team, led by Raffaele Silvestri and Philip Walther and publishing their work in Science Advances, constructed a massive quantum-enhanced Sagnac interferometer a device that splits light into two beams that travel in opposite directions around a closed path before recombining. Due to the Earths rotation, the light traveling in the direction of the spin experiences a slightly shorter path than the light traveling against it, creating a detectable interference pattern when the beams remix.

But the Vienna team wasnt content with ordinary light. They used pairs of photons that were quantum mechanically entangled, meaning their properties were inextricably linked regardless of the distance between them. When these entangled photons were sent in opposite directions around the 715 square meter fiber optic loop, the researchers observed a telltale doubling of the phase shift compared to unentangled photons a signature of the photons spooky quantum connection.

Remarkably, this setup allowed the team to measure the Earths rotation with a sensitivity of five microradians per second the most precise quantum optical measurement of this kind to date. Thats like being able to detect a one-degree turn of a basketball in New York City from the distance of Los Angeles.

To achieve this, the researchers began by generating pairs of photons that were entangled in their polarization states using a process called spontaneous parametric down-conversion. These photon pairs were then sent into a Sagnac interferometer constructed from a two-kilometer long spool of optical fiber, with the two photons from each pair traveling in opposite directions.

A key innovation was the inclusion of an optical switch that could instantly change the effective area of the interferometer to zero. By toggling this switch on and off, the researchers could compare the interference patterns with and without the Earths rotation signal, allowing them to isolate the effect from other noise sources.

To further increase the sensitivity, the team varied the orientation of the fiber loop relative to the Earths rotational axis, mapping out the sinusoidal dependence of the Sagnac phase shift. This allowed them to precisely calibrate their setup and extract the maximum possible signal.

The core of the matter lies in establishing a reference point for our measurement, where light remains unaffected by Earths rotational effect. Given our inability to halt Earth from spinning, we devised a workaround: splitting the optical fiber into two equal-length coils and connecting them via an optical switch, explains lead author Raffaele Silvestri in a media release.

The results were striking. When entangled photon pairs were used, the observed phase shift was consistently twice as large as for individual unentangled photons, regardless of the interferometers orientation. This is a direct consequence of the quantum mechanical nature of the entangled state.

By fitting their data to the theoretical model of the Sagnac effect, the researchers determined the Earths rotation rate to be approximately 7.3 x 10^-5 radians per second, in excellent agreement with the accepted value. The precision achieved is orders of magnitude better than previous quantum optical measurements and begins to approach the regime where effects from general relativity come into play.

We have basically tricked the light into thinking its in a non-rotating universe, says Silvestri.

While groundbreaking, the experiment still faces some limitations. The main factor restricting the sensitivity is noise from environmental vibrations and temperature fluctuations, which can slightly change the effective size of the fiber loop. As the researchers scale up to even larger interferometers, these effects will need to be carefully controlled.

Additionally, the current setup can only measure the magnitude of the Earths rotation, not its direction. Future experiments could potentially use more sophisticated quantum states to gain directional information as well.

Despite these limitations, this work has profound implications. As the precision of quantum sensors continues to improve, it may soon be possible to observe subtle effects that arise from the interplay of quantum mechanics and gravity a major unsolved problem in theoretical physics.

For instance, some theories predict that the gravitational field of a spinning mass can cause minute changes in the entanglement between particles. The techniques demonstrated in this experiment could potentially be adapted to search for such effects, providing a much-needed experimental probe of quantum gravity.

Moreover, ultra-precise quantum gyroscopes like this one could have a wide range of practical applications, from navigation of autonomous vehicles to tests of fundamental physics. By pushing the limits of quantum metrology, this research opens the door to a new era of ultra-precise sensing and tests of natures most elusive phenomena.

In the end, this experiment is a testament to the power of quantum entanglement and the ingenuity of experimental physicists. By applying cutting-edge quantum techniques to a century-old classic, Silvestri, Walther, and their colleagues have not only measured the spin of our planet with record-breaking accuracy but also brought us one step closer to unraveling the deep mysteries that lie at the heart of space, time, and quantum reality. As we stand on the cusp of a quantum revolution in sensing and metrology, the future looks bright and more than a little entangled.

StudyFinds Editor-in-ChiefSteve Fink contributedto this report.

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Quantum entangled photons used to measure the Earth’s rotation – Earth.com

In a remarkable feat of scientific exploration, a team of researchers has successfully measured the effect of Earths rotation on quantum entangled photons.

This pioneering experiment, conducted by a group led by Philip Walther at the University of Vienna, pushes the boundaries of rotation sensitivity in entanglement-based sensors.

These brilliant scientists have brought the world a step closer to the fascinating intersection between quantum mechanics and general relativity.

Their research represents a significant milestone in our understanding of the intricate relationship between rotating reference systems and quantum entanglement.

By employing a giant optical fiber Sagnac interferometer and maintaining low and stable noise levels for several hours, the team achieved a thousand-fold improvement in rotation precision compared to previous quantum optical Sagnac interferometers.

Optical Sagnac interferometers have long been recognized as the most sensitive devices for measuring rotations.

These instruments have played a crucial role in shaping our understanding of fundamental physics since the early years of the last century, contributing to the establishment of Einsteins special theory of relativity.

Today, their unparalleled precision makes them the ultimate tool for measuring rotational speeds, limited only by the boundaries of classical physics.

However, interferometers employing quantum entanglement to measure Earths rotation have the potential to break those bounds.

When two or more particles are entangled, only the overall state is known, while the state of the individual particle remains undetermined until measurement.

This unique property can be harnessed to obtain more information per measurement than would be possible without entanglement.

Despite the immense potential of entanglement-based sensors, their practical implementation has been hindered by the extremely delicate nature of entanglement.

This is where the Vienna experiment made a significant breakthrough.

The researchers constructed a massive optical fiber Sagnac interferometer, with two entangled photons propagating inside a 2-kilometer-long optical fiber wound onto a huge coil.

This setup realized an interferometer with an effective area of more than 700 square meters.

By keeping the noise low and stable for several hours, the team was able to detect enough high-quality entangled photon pairs to outperform the rotation precision of previous quantum optical Sagnac interferometers by a thousand times.

One of the major challenges faced by the researchers was isolating and extracting Earths steady rotation signal.

The core of the matter lays in establishing a reference point for our measurement, where light remains unaffected by Earths rotational effect, lead author Raffaele Silvestri explains.

Given our inability to halt Earths from spinning, we devised a workaround: splitting the optical fiber into two equal-length coils and connecting them via an optical switch.

By toggling the switch on and off, the researchers could effectively cancel the rotation signal at will, allowing them to extend the stability of their large apparatus.

We have basically tricked the light into thinking its in a non-rotating universe, Silvestri concluded.

In a Sagnac interferometer, two particles traveling in opposite directions of a rotating closed path reach the starting point at different times.

However, when two entangled particles are involved, something extraordinary happens: they behave like a single particle testing both directions simultaneously while accumulating twice the time delay compared to the scenario where no entanglement is present.

This unique property is known as super-resolution.

The experiment, conducted as part of the research network TURIS hosted by the University of Vienna and the Austrian Academy of Sciences, successfully observed the effect of Earths rotation on a maximally entangled two-photon state.

This confirmation of the interaction between rotating reference systems and quantum entanglement, as described in Einsteins special theory of relativity and quantum mechanics, represents a thousand-fold precision improvement compared to previous experiments.

That represents a significant milestone since, a century after the first observation of Earths rotation with light, the entanglement of individual quanta of light has finally entered the same sensitivity regimes, says Haocun Yu, who worked on this experiment as a Marie-Curie Postdoctoral Fellow.

The successful demonstration of this methodology opens up exciting possibilities for future research.

Philip Walther, the lead researcher, believes that their result and methodology will set the ground for further improvements in the rotation sensitivity of entanglement-based sensors.

This could open the way for future experiments testing the behavior of quantum entanglement through the curves of spacetime, he adds.

This fascinating experiment marks a significant milestone in our understanding of the intricate relationship between quantum entanglement and the effects of Earths rotation.

By successfully measuring the influence of our planets spin on entangled photons with unprecedented precision, this research confirms the predictions of Einsteins special theory of relativity and quantum mechanics while opening the door to a new era of exploration at the fascinating intersection of these two fundamental fields.

As scientists continue to push the boundaries of entanglement-based sensors, we stand on the brink of unraveling the mysteries of spacetime and gaining a deeper understanding of the universes most fundamental workings.

The full study was published in the journal Science Advances.

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A Missing Piece in the Big Bang Theory Has Surfaced – AOL

A Missing Piece in the Big Bang Theory Has ArrivedAbhishek Mehta - Getty Images

Combining different pieces from Big Bang cosmology could help explain an issue we have today.

The Hubble constant, the speed of expansion of our universe, is not observed with consistency.

These scientists suggest that not-well-understood quantum gravity could account for the gap.

In research published earlier this year, physicists from the University of Hyderabad in India say theyre on the path to solving one of the universes biggest outstanding problems. Since Edwin Hubble realized the universe is always expanding nearly 100 years ago, scientists have used the Hubble constant in calculations on virtually every scale in the universe. But today, estimates for the Hubble constant dont always align, with a difference of up to 10 percent between calculations made using different methods. (When someone at NASA mixes up meters and yards and loses an entire spacecraft, thats not even a full 10 percent deviation.)

The paper appears in the peer reviewed journal Classical and Quantum Gravity. The journal has an ongoing, periodically updated focus issue specifically about this measurement tension, and the editors explain the problem therescientists cant say for sure that the different Hubble constants measured are actually different, rather than just observation or calibration issues.

But the authors of the new paper, physicist P.K. Suresh and his research fellow (referred to as just Anupama B.) say that most measurements taken now are reliable. Instrumentation only continues to improveweve all seen those generation-defining, poster-quality photos of the far-out planets, for example. If the measurements on the local and faraway levels are indeed sound, then something is missing.

Its here where they introduce quantum gravity as a possible factor. This variablewhich, to be honest, is another enigmatic placeholder in some wayscould close the gap in Hubble constant observations. Thats because, as the authors propose, quantum gravity could have affected the rate of change at which the universe expanded itself. When a constant can have a variable rate of change, its easy to see why researchers tend to drop the constant label and instead call the fatcor simply H0, H1, and so on to designate which version of the measurement is in play.

The researchers explain that during inflationthe rapid growth of the universe immediately following the Big Bangthere may not have been a single, uniform inflation zone. Instead, more and more scientists are theorizing around the idea of multi field inflation. The idea originated to explain another measurement discrepancy: the number of particles in particular places or times, compared with the massive speed of inflation overall.

If a theory could help explain one gap in our codified equations for how inflation works, it makes sense to try that theory to find other missing pieces. These researchers used what is called the hybrid inflationary model, which describes two fields: one inflating and one rolling over like a waterfall. By accounting for quantum gravity, they found they were able to reconcile H0the current Hubble constantwith both H1 (during inflation) and HT (during phase transition). Just one adjusted equation with a parameter for quantum gravity could draw a curve that includes all three data points.

The researchers say that to resolve the Hubble tension, one must also establish and validate the inflation model linked with it. Cosmology faces unique challenges, including the ongoing question of quantum gravity itself. So, trying to stake out a specific model like this involves choosing and stabilizing other variables that may not be well understood or have a consensus... yet.

But, Suresh told Live Science, that cant stop researchers from pushing forward. Our equation doesnt need to account for everything, Suresh said, but that does not prevent us from testing quantum gravity or its effects experimentally.

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Earth’s rotation measured 1000x better with quantum entanglement – Interesting Engineering

Researchers at the University of Vienna led by Philip Walther just pioneered the field of quantum mechanics and general relativity by measuring the effect of the rotation of Earth on quantum entangled photons, as stated in a press release.

In the Vienna experiment, they used an interferometer, which is the most sensitive to rotations. Its unparalleled precision makes it the ultimate tool for measuring rotational speeds, limited only by the boundaries of classical physics.

Interferometers employing quantum entanglement have the potential to break those bounds. If two or more particles are entangled, only the overall state is known, while the state of the individual particle remains undetermined until measurement.

This can be used to obtain more information per measurement than would be possible without it. However, the promised quantum leap in sensitivity has been hindered by the extremely delicate nature of entanglement which is prone to decoherence, lead author Raffaele Silvestri explained to Interesting Engineering. Until now.

Here is where the Vienna experiment made the difference. They built a giant optical fibre Sagnac interferometer and kept the noise low and stable for several hours. This enabled the detection of enough high-quality entangled photon pairs such to outperform the rotation precision of previous quantum optical Sagnac interferometers by a thousand.

It is extremely challenging to make precision measurements in large-scale devices by employing these probe states, Silvestri extrapolated to Interesting Engineering.

We have overcome those hurdles by increasing, with innovative techniques, the long-term stability in time of our huge interferometer.'

A significant hurdle the researchers faced was isolating and extracting Earths steady rotation signal.

The core of the matter lays in establishing a reference point for our measurement, where light remains unaffected by Earths rotational effect, Silvestri said in a press release.

Given our inability to halt Earths from spinning, we devised a workaround: splitting the optical fibre into two equal-length coils and connecting them via an optical switch.

By toggling the switch on and off, the researchers could effectively cancel the rotation signal at will, which also allowed them to extend the stability of their large apparatus.

We have basically tricked the light into thinking its in a non-rotating universe, added Silvestri.

To clarify, Silvestri told Interesting Engineering humorously to not take it too literally.

They swapped the propagation direction of the two counter-propagating photons for half of the propagation length in the optical fiber. This means that when the photons come back to the starting point the delay that they have accumulated, which quantifies Earth rotational speed, is null.

So being that the interferometer is attached to the Earths surface and its rotating with it, the Earths rotation-induced effect is cancelled. Its almost as if the photons dont feel or see any rotation in the end, tricked into thinking they are in a non-rotating reference frame AKA universe.

This enables them to compare the behavior of the entangled state from a rotating to an effectively non-rotating reference frame and brings also several technical advantages as noise suppression and higher stability in the long term.

This technique has never been employed in a quantum Sagnac interferometer and is an innovative invention for this reason, he concluded.

The experiment, which was conducted as part of the research network TURIS hosted by the University of Vienna and the Austrian Academy of Sciences, has successfully observed the effect of the rotation of Earth on a maximally entangled two-photon state.

This confirms the interaction between rotating reference systems and quantum entanglement, as described in Einsteins special theory of relativity and quantum mechanics, with a thousand-fold precision improvement compared to previous experiments.

That represents a significant milestone since, a century after the first observation of Earths rotation with light, the entanglement of individual quanta of light has finally entered the same sensitivity regimes, said Haocun Yu, who worked on this experiment as a Marie-Curie Postdoctoral Fellow.

I believe our result and methodology will set the ground to further improvements in the rotation sensitivity of entanglement-based sensors. This could open the way for future experiments testing the behavior of quantum entanglement through the curves of spacetime, added Philip Walther.

In other words, the next step, Silvestri said, would be increasing the sensitivity by a significant amount to be able to detect general relativistic effects as Frame-Dragging (or Lense-Thirring) on an entangled photon pair. This is a gravitational effect that is predicted by Einsteins general theory of relativity in presence of a rotating massive body, as a rotating Earth drags its spacetime curvature and it simply manifests itself as a small correction to the Earth rotational speed.

This measurement would represent the first experimental test of the behavior of quantum mechanics in curved spacetimes, shining light into this unexplored regime.

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Maria Mocerino Originally from LA, Maria Mocerino has been published in Business Insider, The Irish Examiner, The Rogue Mag, Chacruna Institute for Psychedelic Plant Medicines, and now Interesting Engineering.

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What Is a Quantum Battery? And When Will It Power My Laptop? – Gizmodo

The modern battery has come a long way in its 224-year history. In the place of Alessandro Voltas piles of metal disks and brine-soaked cloth, we now have batteries the dimensions of a graham cracker that can last days before needing a recharge.

But what is the ceiling of the devices currently on the market? What sort of technical challenges must be overcome to break that ceiling, and when will such hurdles be cleared? What is the future of energy storage?

A handful of scientists around the world are working on an answer: a battery technology that uses the laws of quantum physics, rather than classical physics, to hold a charge. Its a long, long way out, but Rome wasnt built in a dayand it certainly wasnt powered in one.

A battery is a piece of technology that uses chemical reactions to produce electrical energy. Household batteries produce electrical energy via the flow of electrons through a circuit. Different battery cells have been developed over the centuries; Benjamin Franklin is considered to have coined the term electrical battery in a 1749 letter, which he concluded with an amusing riff on the marvels of electricity:

A Turky is to be killed for our Dinners by the Electrical Shock; and roasted by the electrical Jack, before a Fire kindled by the Electrified Bottle; when the Healths of all the Famous Electricians in England, France and Germany, are to be drank in Electrified Bumpers, under the Discharge of Guns from the Electrical Battery.

Fast forward through a few different battery cells, mostly named for the scientists who developed them using chemical reactions of various acids and metals, and in 1859 we got the lead-acid batterythe first with the capacity to recharge by reversing current through the system. In the late 20th century, the lithium-ion battery became in vogue and has basically remained popular since, using different permutations of lithium combined with other metals and phosphates. But throughout the modern batterys history, the basic principle of a chemical reaction begetting electrical power has not changed.

Lets quickly review quantum physics in broad strokes. Particles in quantum states operate under an entirely different set of rules from everything you see around you, from the water in clouds to the blood vessels coursing through your veins. Particles enter quantum states under extreme conditions: very cold temperatures and in vacuums. In these conditions, particles can act like multiple things at once, making them useful for doing things like complicated mathematical operations (as a quantum computer does) and checking whether time travel (in a sense) is possible.

Quantum systems can also exhibit entanglement, a phenomenon by which two or more quantum particles define the characteristics of each other. In quantum computers, atoms in an array carry the information necessary for the given operation, as bits do in an ordinary computer. These atoms are quantum bits, or qubits.

But quantum operations are delicate. The moment any value in a quantum system is made certain, the operation falls apart. The entire systemfor example, atoms in an arrayis then back in a classical state.

Quantum states can persist for a long time. Take time crystals, a state of matter first proposed in 2012 which earlier this year physicists showed could persist for at least 40 minutes, about 10 million times longer than other known crystals. These crystals are far afield from quantum batteries but showcase how fleeting some quantum systems normally arean important issue to solve if were ever going to rely on such regimes for power.

So how do the rules of quantum mechanics apply to a battery, the technology that allows you to keep reading this article and maybe more thereafter, once you recharge?

Like normal batteries, quantum batteriesas they are imaginedstore energy. But thats where the similarities end. Unlike the chemical reactions that both charge up and expend a batterys stored energy, quantum batteries are powered by quantum entanglement or behaviors that more closely tether the battery and its source.

Quantum batteries are composed of many quantum cells that act like one big quantum battery, said Ju-Yeon Gyhm, a quantum researcher at Seoul National University in South Korea, in an email to Gizmodo. The challenge is how to maintain the quantum properties for a long time.

Since the same properties apply to quantum batteries as quantum computers, a major technical challenge must be cleared to see the technology become a reality outside of research settings: Physicists must figure out how to keep quantum systems in their delicate states outside of the most carefully managed research settings. A room-temperature superconductor would be such a grail, but these days the only folks claiming such a discovery had their work debunked within months.

Thermodynamics at equilibrium does not set bounds on how fast energy is transformed into heat and work, wrote a team of five scientists in a recent colloquium on quantum batteries, currently hosted on the preprint server arXiv. Therefore it seems natural to seek thermodynamic quantum advantages in quantum systems that are driven out of equilibrium.

The group went on to note that quantum entanglement is linked with how fast energy can be stored in many-body quantum systems, a discovery that has prompted research into quantum systems as energy storage devices.

In 2018, a team modeled the Dicke quantum battery, the first proposed to exist in a solid-state architecture, and in 2022, a team tested out a basic framework for a quantum battery in a lab setting using a target, mirrors, and laser light.

Late last year, a team of quantum researchers proposed a system by which quantum batteries could charge in an indefinite causal order, or ICO. Their findingspublished in Physical Review Lettersposited that a charging system with ICO could outperform conventional charging protocols.

Roughly speaking, ICO can be used to construct quantum processes which are not possible in the standard quantum theory, where causal order must be definite, or fixed, said Yuanbo Chen, a researcher at the University of Tokyo and lead author of the research, in an email to Gizmodo. This flexibility allows for a wider variety of quantum processes, some of which can show advantageous and interesting properties.

We saw huge gains in both the energy stored in the system and the thermal efficiency. And somewhat counterintuitively, we discovered the surprising effect of an interaction thats the inverse of what you might expect: A lower-power charger could provide higher energies with greater efficiency than a comparably higher-power charger using the same apparatus, Chen said at the time.

Different experimental setups of quantum battery systemsboth proposed and realizedmean there are different pathways to innovate on the design of such a futuristic technology. Last month, a team from the University of Gdansk and the University of Calgary proposed a quantum battery charging system that maximizes the amount of energy stored in the battery while minimizing the amount of energy that dissipates (or is lost) in the charging process. Part of the teams redesign is that the quantum battery and its charger are coupled to the same reservoir, producing an interference-like pattern which improves the efficiency of energys transfer between the two. The team estimate that the battery can store four times as much energy through the new charging process than using a conventional charger.

Quantum batteries act more like a wave where the molecules or atoms act in unison, whereas in conventional batteries the molecules or atoms act more like individual particles, said James Quach, a quantum researcher at the University of Adelaide in Australia, in an email to Gizmodo. This collective behavior is what underpins the superextensive charging properties of quantum batteries, where it takes less time to charge quantum batteries of larger capacity.

In 2022, a team led by Quach tested out a basic framework of a quantum battery by putting molecular dye called Lumogen-F orange in a small cavity, and pulsed light at it to see how it stored the energy transmitted by the photons of light. The team found that the system charged up remarkably fast, and that larger systems generally ought to charge faster.

Currently it takes femto- to picoseconds to charge a quantum battery that stores about a microjoule of energy for nano- to milliseconds, Quach said. Although this does not sound like a long time, its storage time is actually more than million times longer than its charging time. As a comparison, this would be equivalent to a conventional battery which takes minutes to charge, being able to hold that charge for hundreds of years.

As reported by New Scientist, some physicists theorize that a quantum batterys charge time is inversely proportional to the number of qubits in the system; in other words, the bigger the battery, the faster it charges.

Quantum battery research is gaining traction, but its still very much in its infancy. Though their promise is remarkable, what the ultimate design of the technology will be remains an open question. Commercialization? Thats but a twinkle in the eye of the most business-minded physicist at the moment.

The chief issue remains getting quantum systems to stay in a quantum state when they scale up. Quach believes that quantum batteries could be used as a mobile energy source in phones and cars, but many quantum systems currently need very cold, noiseless conditions to stay that way (as an aside, Quachs 2022 experimental setup operated at room temperature). Not to demoralize you, dear reader, but nuclear fusion is probably closer to reality than quantum batteries in our devices.

Though many a skeptical reporter is loathe to admit it, Id love to eat my words. The only thing better than being right is finding the world a better place at the expense of being wrong. Quantum batteries could charge faster and more efficiently than classical devices, and could integrate with budding quantum technologies that are used for lofty simulations and measurements. A fully operational quantum battery has not yet been demonstrated, but according to the recent colloquium, such a technology could revolutionize the way we harvest, deliver, and control energy. Given humanitys obvious reliance on electricity, energy storage could use a quantum leap.

More:Physicists Got a Quantum Computer to Work by Blasting It With the Fibonacci Sequence

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Quantum education: Are universities gearing up? – Deccan Herald

Driverless cars and robotic surgeries are only diminutive indicators of tomorrows world. Artificial intelligence driven by quantum machine learning will increase automation that will transform life on Earth. Two-thirds of the skills humanity relies on today to make a living would be obsolete. Tomorrows citizens must be schooled in emerging technologies and lifestyles in an environment beyond todays fiction.

A few hundred years ago, the responsibility for general life preparation shifted from parents to universities. A university is the stage where the scene changes; it must rehearse tomorrows citizens to perform on a 3+n-dimensional scaffold. Sustainability, virtualisation of the physical experience, novel sensors, and communication strategies pose unprecedented challenges for university curricula.

Important milestones in developing digital logic include the works of George Boole, Maurice Karnaugh, Claude Shannon, and Alan Turing. This field leapfrogged into the quantum world through the visions of Richard Feynman, Paul Benioff, and David Deutsch over four decades ago. Willfully or unwittingly, (i) Quantum Computing & Simulations, (ii) Quantum Communications, (iii) Quantum Sensing & Metrology, and (iv) Quantum Material & Devices have crawled into our lives. These are the four verticals of the Titanic National Quantum Mission undertaken by the Indian government.

Explaining the unexplained

Even though Newtons laws describe most of the everyday phenomena, they cannot explain all natural phenomena in the physical world, including some involving macroscopic objects. One needs the quantum theory, developed by Planck, Einstein, Schrdinger, Heisenberg, Dirac and others.

Quantum theory is over a hundred years old. Along with its heroes mentioned above, distinguished scholars from Bharat, like Satyendranath Bose, C V Raman, and Meghnad Saha, made outstanding contributions to develop it.

Their works led to developing and understanding semiconductors and lasers, laying the foundations of a societal revolution. However, certain aspects of the quantum principle of superposition, which produce the entanglement of objects, are only beginning to be exploited. It is this developing scenario that is called the quantum sciences and technologies.

An algorithm is a set of rules that produces an output for an input. It performs computations involving decision-making and data processing; essentially, it solves problems of our interest. Current computers are built using quantum devices (such as semiconductors). Still, the calculation algorithm is driven by classical (Boolean) logic, using bits (0 or 1, i.e., a switch that is off or on). Quantum computers employ quantum logic; they use quantum bits or qubits (quantum superpositions of 0 and 1).

Quantum computing employs abstract mathematics but is highly successful in describing nature. It produces exceptional power to implement computations. Quantum computers are, however, not expected to replace classical algorithms. They will nonetheless be able to outperform classical machines unimaginably, addressing the mounting demands of our changing world.

The earliest schemes that used qubits are the Deutsch-Jozsa algorithm (1992), Shors factorisation scheme (1994), Simons algorithm (1994), and Grovers search algorithm (1996). Now, quantum computational schemes have advanced to address extremely complex problems.

Wide-ranging applications

The quantum future began a century ago, but the present is incubating unprecedented technology driven by quantum entanglement, which gives us a new sense of the physical reality. Wide-ranging applications include the development of efficient algorithms for drug discovery, indissoluble encryptions for information and wealth management, secure communication, the development of ultrafast sensors and metrology that would trigger a rapid response to unforeseen adversities, etc. Encryption standards would be revolutionised under Post-Quantum-Cryptography (PQC), though challenges remain in developing practical protocols.

Artificial intelligence and machine learning are already pushing technologies; the AI-ML tools would be supercharged when driven by quantum entanglement. Only a few quantum computers are available today, but there will be thousands in another decade!

The changes in technology these computers will produce in the coming decade will surpass the number of those produced in the past hundred years. Quantum algorithms will drive supply chain, travel, healthcare, financial services, entertainment and media, information processing, buildings and infrastructure, telecommunication and networks, determining optimum routes amid multiple nodes in a complex environment, and whatnot!

Emerging quantum technologies are intrinsically interdisciplinary. Expertise in mathematics, physics, and all specialised engineering domains will continue to be needed, but in increasingly novel ways. Universities must reinvent the curricula since tomorrows workers will use different tools and extraordinary ideas. Education has to begin with familiar and intuitive ideas, but it must gently and swiftly ramp up todays students to be prepared for tomorrow before it becomes yesterday.

(The author is a professor at the School of Computer Science and Engineering at a university in Bengaluru)

Published 17 June 2024, 20:21 IST

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Physicists Discover Innovative Approach to Represent Pi – Mirage News

While investigating how string theory can be used to explain certain physical phenomena, scientists at the Indian Institute of Science (IISc) have stumbled upon on a new series representation for the irrational number pi. It provides an easier way to extract pi from calculations involved in deciphering processes like the quantum scattering of high-energy particles.

The new formula under a certain limit closely reaches the representation of pi suggested by Indian mathematician Sangamagrama Madhava in the 15th century, which was the first ever series for pi recorded in history. The study was carried out by Arnab Saha, a post-doc and Aninda Sinha, Professor at Centre for High Energy Physics (CHEP), and published in Physical Review Letters.

"Our efforts, initially, were never to find a way to look at pi. All we were doing was studying high-energy physics in quantum theory and trying to develop a model with fewer and more accurate parameters to understand how particles interact. We were excited when we got a new way to look at pi," Sinha says.

Sinha's group is interested in string theory the theoretical framework that presumes that all quantum processes in nature simply use different modes of vibrations plucked on a string. Their work focuses on how high energy particles interact with each other such as protons smashing together in the Large Hadron Collider and in what ways we can look at them using as few and as simple factors as possible. This way of representing complex interactions belongs to the category of "optimisation problems." Modelling such processes is not easy because there are several parameters that need to be taken into account for each moving particle its mass, its vibrations, the degrees of freedom available for its movement, and so on.

Saha, who has been working on the optimisation problem, was looking for ways to efficiently represent these particle interactions. To develop an efficient model, he and Sinha decided to club two mathematical tools: the Euler-Beta Function and the Feynman Diagram. Euler-Beta functions are mathematical functions used to solve problems in diverse areas of physics and engineering, including machine learning. The Feynman Diagram is a mathematical representation that explains the energy exchange that happens while two particles interact and scatter.

What the team found was not only an efficient model that could explain particle interaction, but also a series representation of pi.

In mathematics, a series is used to represent a parameter such as pi in its component form. If pi is the "dish" then the series is the "recipe". Pi can be represented as a combination of many numbers of parameters (or ingredients). Finding the correct number and combination of these parameters to reach close to the exact value of pi rapidly has been a challenge. The series that Sinha and Saha have stumbled upon combines specific parameters in such a way that scientists can rapidly arrive at the value of pi, which can then be incorporated in calculations, like those involved in deciphering scattering of high-energy particles.

"Physicists (and mathematicians) have missed this so far since they did not have the right tools, which were only found through work we have been doing with collaborators over the last three years or so," Sinha explains. "In the early 1970s, scientists briefly examined this line of research but quickly abandoned it since it was too complicated."

Although the findings are theoretical at this stage, it is not impossible that they may lead to practical applications in the future. Sinha points to how Paul Dirac worked on the mathematics of the motion and existence of electrons in 1928, but never thought that his findings would later provide clues to the discovery of the positron, and then to the design of Positron Emission Tomography (PET) used to scan the body for diseases and abnormalities. "Doing this kind of work, although it may not see an immediate application in daily life, gives the pure pleasure of doing theory for the sake of doing it," Sinha adds.

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The Pentagon Is Trying to Build a Laser That Never Fails – Yahoo News Canada

Lasers are a fundamental technology of todays society, but this amplified light still suffers from shortcomingsextreme temperatures, long distances, or even just fog.

Researchers from the Washington University in St. Louis and Texas A&M University are turning to quantum mechanics to create an entangled laser than can overcome these pitfalls.

The research is being conducted via a two-year, $1 million grant from the Defense Advanced Research Projects Agency (DARPA), which can probably think of a few use cases for a quantum laser.

Light Amplification by Stimulated Emission of Radiation, otherwise known as the laser, fundamentally changed human society upon its introduction in the early 1960s. The uses for lasers seem almost endless, and have rearranged how we communicate, perform surgeries, and even pay for groceries. In other words, we very much live in the laser era.

However, this ubiquitous technology isnt without its shortcomings. Because lasers are essentially just the optical amplifications of light, theyre still subject to failing in adverse conditionswhether that be fog, extreme temperatures, or even just long distances.

Now, scientists at Washington University in St. Louis and Texas A&M University are turning to quantum mechanics to solve these laser-based shortcomings. The research will be conducted thanks to a two-year, $1 million grant from the Defense Advanced Research Projects Agency (DARPA) and will be led by Washington University associate professor Jung-Tsung Shen, who hopes to develop a prototype device called a quantum photonic-dimer laser.

As its name suggests, this device is built around concepts from quantum mechanics. The idea is that two carefully controlled particles of light (a.k.a. photonic dimers) can be used to create a powerful laser beam. The quantum part of the equation comes in when these two particles are entangled, which can help protect from some of the deleterious effects lasers can face in challenging environmentswhen charge is applied to one photon, it directly applies to the other.

Photons encode information when they travel, but the travel through the atmosphere is very damaging to them, Shen said in a press statement. When two photons are bound together, they still suffer the effects of the atmosphere, but they can protect each other so that some phase information can still be preserved.

As you can probably imagine, entangling two photons isnt exactly easy, especially since they dont have a charge. Shen says he instead glued two different-colored photons together, which then exhibited the behavior of a blue photon. These entangled photons can then be tweaked to work optimally in fog, extreme temperatures, or any other adverse condition. This would be a huge boon for both communication and imaging, which can be specifically limited by atmosphere and distance.

Quantum entanglement is a correlation between photons, Shen said in a press statement. We are trying to exploit the property of entanglement to do something innovative. The entanglement can do many things that we can only dream of this is just the tip of the iceberg.

Researchers around the world are busy applying quantum mechanical properties to classical technologies. Last year, a French research team reported that their quantum radarwhich similarly uses quantum entanglement techniquesoutperformed classical radar by 20 percent. Researchers are also hard at work creating a quantum internet that will one day transmit information in quantum state, which could increase security and improve the study of materials.

So, while the laser was no doubt a world-changing invention, its revolutionary introduction may only be the first chapter of its technological journal.

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