miércoles, 21 de junio de 2017

The Quantum Thermodynamics Revolution

Ricardo Bessa for Quanta Magazine

Senior Writer

May 2, 2017

Print this article black holesinformation theoryphysicsquantum information theorytheoretical physicsthermodynamicsIn his 1824 book, Reflections on the Motive Power of Fire, the 28-year-old French engineer Sadi Carnot worked out a formula for how efficiently steam engines can convert heat — now known to be a random, diffuse kind of energy — into work, an orderly kind of energy that might push a piston or turn a wheel. To Carnot's surprise, he discovered that a perfect engine's efficiency depends only on the difference in temperature between the engine's heat source (typically a fire) and its heat sink (typically the outside air). Work is a byproduct, Carnot realized, of heat naturally passing to a colder body from a warmer one.

Carnot died of cholera eight years later, before he could see his efficiency formula develop over the 19th century into the theory of thermodynamics: a set of universal laws dictating the interplay among temperature, heat, work, energy and entropy — a measure of energy's incessant spreading from more- to less-energetic bodies. The laws of thermodynamics apply not only to steam engines but also to everything else: the sun, black holes, living beings and the entire universe. The theory is so simple and general that Albert Einstein deemed it likely to "never be overthrown."

Yet since the beginning, thermodynamics has held a singularly strange status among the theories of nature.

"If physical theories were people, thermodynamics would be the village witch," the physicist Lídia del Rio and co-authors wrote last year in Journal of Physics A. "The other theories find her somewhat odd, somehow different in nature from the rest, yet everyone comes to her for advice, and no one dares to contradict her."

Unlike, say, the Standard Model of particle physics, which tries to get at what exists, the laws of thermodynamics only say what can and can't be done. But one of the strangest things about the theory is that these rules seem subjective. A gas made of particles that in aggregate all appear to be the same temperature — and therefore unable to do work — might, upon closer inspection, have microscopic temperature differences that could be exploited after all. As the 19th-century physicist James Clerk Maxwell put it, "The idea of dissipation of energy depends on the extent of our knowledge."

They've found new, quantum versions of the laws that scale up to the originals. Rewriting the theory from the bottom up has led experts to recast its basic concepts in terms of its subjective nature, and to unravel the deep and often surprising relationship between energy and information — the abstract 1s and 0s by which physical states are distinguished and knowledge is measured. "Quantum thermodynamics" is a field in the making, marked by a typical mix of exuberance and confusion. {"type":"Image","id":"component-594ae4a5bad0e","data":{"id":45268,"src":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium.jpg","class":"","width":1720,"height":962,"mobileSrc":false,"zoomSrc":false,"align":"align=\"right\"","wrapper_width":"","caption":"Sandu Popescu, a professor of physics at the University of Bristol.\n","attribution":"Anna I Popescu\n","variant":"shortcode","size":"wide","disableZoom":false,"srcImage":{"ID":45268,"id":45268,"title":"Sandu_Popescu_Medium","filename":"Sandu_Popescu_Medium.jpg","url":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium.jpg","alt":"","author":"38","description":"","caption":"","name":"sandu_popescu_medium","date":"2017-05-01 16:21:35","modified":"2017-05-01 18:13:26","mime_type":"image\/jpeg","type":"image","icon":"https:\/\/api.quantamagazine.org\/wp-includes\/images\/media\/default.png","width":1720,"height":962,"sizes":{"thumbnail":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium-520x291.jpg","thumbnail-width":520,"thumbnail-height":291,"medium":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium-1720x962.jpg","medium-width":1720,"medium-height":962,"medium_large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium-768x430.jpg","medium_large-width":768,"medium_large-height":430,"large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium.jpg","large-width":1720,"large-height":962,"square_small":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium-160x160.jpg","square_small-width":160,"square_small-height":160,"square_large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Sandu_Popescu_Medium-520x520.jpg","square_large-width":520,"square_large-height":520}}}}

"We are entering a brave new world of thermodynamics," said Sandu Popescu, a physicist at the University of Bristol who is one of the leaders of the research effort. "Although it was very good as it started," he said, referring to classical thermodynamics, "by now we are looking at it in a completely new way."

In an 1867 letter to his fellow Scotsman Peter Tait, Maxwell described his now-famous paradox hinting at the connection between thermodynamics and information. The paradox concerned the second law of thermodynamics — the rule that entropy always increases — which Sir Arthur Eddington would later say "holds the supreme position among the laws of nature." According to the second law, energy becomes ever more disordered and less useful as it spreads to colder bodies from hotter ones and differences in temperature diminish. (Recall Carnot's discovery that you need a hot body and a cold body to do work.) Fires die out, cups of coffee cool and the universe rushes toward a state of uniform temperature known as "heat death," after which no more work can be done.

The great Austrian physicist Ludwig Boltzmann showed that energy disperses, and entropy increases, as a simple matter of statistics: There are many more ways for energy to be spread among the particles in a system than concentrated in a few, so as particles move around and interact, they naturally tend toward states in which their energy is increasingly shared.

But Maxwell's letter described a thought experiment in which an enlightened being — later called Maxwell's demon — uses its knowledge to lower entropy and violate the second law. The demon knows the positions and velocities of every molecule in a container of gas. By partitioning the container and opening and closing a small door between the two chambers, the demon lets only fast-moving molecules enter one side, while allowing only slow molecules to go the other way. The demon's actions divide the gas into hot and cold, concentrating its energy and lowering its overall entropy. The once useless gas can now be put to work.

Maxwell and others wondered how a law of nature could depend on one's knowledge — or ignorance — of the positions and velocities of molecules. If the second law of thermodynamics depends subjectively on one's information, in what sense is it true?



A century later, the American physicist Charles Bennett, building on work by Leo Szilard and Rolf Landauer, resolved the paradox by formally linking thermodynamics to the young science of information. Bennett argued that the demon's knowledge is stored in its memory, and memory has to be cleaned, which takes work. (In 1961, Landauer calculated that at room temperature, it takes at least 2.9 zeptojoules of energy for a computer to erase one bit of stored information.) In other words, as the demon organizes the gas into hot and cold and lowers the gas's entropy, its brain burns energy and generates more than enough entropy to compensate. The overall entropy of the gas-demon system increases, satisfying the second law of thermodynamics.

The findings revealed that, as Landauer put it, "Information is physical." The more information you have, the more work you can extract. Maxwell's demon can wring work out of a single-temperature gas because it has far more information than the average user.

But it took another half century and the rise of quantum information theory, a field born in pursuit of the quantum computer, for physicists to fully explore the startling implications.

Over the past decade, Popescu and his Bristol colleagues, along with other groups, have argued that energy spreads to cold objects from hot ones because of the way information spreads between particles. According to quantum theory, the physical properties of particles are probabilistic; instead of being representable as 1 or 0, they can have some probability of being 1 and some probability of being 0 at the same time. When particles interact, they can also become entangled, joining together the probability distributions that describe both of their states. A central pillar of quantum theory is that the information — the probabilistic 1s and 0s representing particles' states — is never lost. (The present state of the universe preserves all information about the past.)

{"type":"LinkList","id":"component-594ae4a5bbf66","data":{"title":"Related articles","links":[{"type":"internal","link":"https:\/\/www.quantamagazine.org\/quantum-entanglement-drives-the-arrow-of-time-scientists-say-20140416\/","title":"Time\u2019s Arrow Traced to Quantum Source"},{"type":"internal","link":"https:\/\/www.quantamagazine.org\/the-computational-foundation-of-life-20170126\/","title":"How Life (and Death) Spring From Disorder"},{"type":"internal","link":"https:\/\/www.quantamagazine.org\/frontier-of-physics-interactive-map-20150803\/","title":"Theories of Everything, Mapped"},{"type":"internal","link":"https:\/\/www.quantamagazine.org\/tensor-networks-and-entanglement-20150428\/","title":"How Quantum Pairs Stitch Space-Time"}]}}Over time, however, as particles interact and become increasingly entangled, information about their individual states spreads and becomes shuffled and shared among more and more particles. Popescu and his colleagues believe that the arrow of increasing quantum entanglement underlies the expected rise in entropy — the thermodynamic arrow of time. A cup of coffee cools to room temperature, they explain, because as coffee molecules collide with air molecules, the information that encodes their energy leaks out and is shared by the surrounding air.

Understanding entropy as a subjective measure allows the universe as a whole to evolve without ever losing information. Even as parts of the universe, such as coffee, engines and people, experience rising entropy as their quantum information dilutes, the global entropy of the universe stays forever zero.

Renato Renner, a professor at ETH Zurich in Switzerland, described this as a radical shift in perspective. Fifteen years ago, "we thought of entropy as a property of a thermodynamic system," he said. "Now in information theory, we wouldn't say entropy is a property of a system, but a property of an observer who describes a system."

Moreover, the idea that energy has two forms, useless heat and useful work, "made sense for steam engines," Renner said. "In the new way, there is a whole spectrum in between — energy about which we have partial information."

Entropy and thermodynamics are "much less of a mystery in this new view," he said. "That's why people like the new view better than the old one."

The relationship among information, energy and other "conserved quantities," which can change hands but never be destroyed, took a new turn in two papers published simultaneously last July in Nature Communications, one by the Bristol team and another by a team that included Jonathan Oppenheim at University College London. Both groups conceived of a hypothetical quantum system that uses information as a sort of currency for trading between the other, more material resources.

{"type":"Image","id":"component-594ae4a5bcfe9","data":{"id":45429,"src":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500.jpg","class":"","width":615,"height":344,"mobileSrc":false,"zoomSrc":false,"align":"align=\"right\"","wrapper_width":"","caption":"Jonathan Oppenheim, a professor of quantum theory at University College London.\n","attribution":"Ezra Press\n","variant":"shortcode","size":"wide","disableZoom":false,"srcImage":{"ID":45429,"id":45429,"title":"Oppenheim_LR-500","filename":"Oppenheim_LR-500.jpg","url":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500.jpg","alt":"","author":"38","description":"","caption":"","name":"oppenheim_lr-500","date":"2017-05-01 18:29:54","modified":"2017-05-01 18:51:49","mime_type":"image\/jpeg","type":"image","icon":"https:\/\/api.quantamagazine.org\/wp-includes\/images\/media\/default.png","width":615,"height":344,"sizes":{"thumbnail":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500-520x291.jpg","thumbnail-width":520,"thumbnail-height":291,"medium":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500.jpg","medium-width":615,"medium-height":344,"medium_large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500.jpg","medium_large-width":615,"medium_large-height":344,"large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500.jpg","large-width":615,"large-height":344,"square_small":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500-160x160.jpg","square_small-width":160,"square_small-height":160,"square_large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Oppenheim_LR-500-520x344.jpg","square_large-width":520,"square_large-height":344}}}}Imagine a vast container, or reservoir, of particles that possess both energy and angular momentum (they're both moving around and spinning). This reservoir is connected to both a weight, which takes energy to lift, and a turning turntable, which takes angular momentum to speed up or slow down. Normally, a single reservoir can't do any work — this goes back to Carnot's discovery about the need for hot and cold reservoirs. But the researchers found that a reservoir containing multiple conserved quantities follows different rules. "If you have two different physical quantities that are conserved, like energy and angular momentum," Popescu said, "as long as you have a bath that contains both of them, then you can trade one for another."

In the hypothetical weight-reservoir-turntable system, the weight can be lifted as the turntable slows down, or, conversely, lowering the weight causes the turntable to spin faster. The researchers found that the quantum information describing the particles' energy and spin states can act as a kind of currency that enables trading between the reservoir's energy and angular momentum supplies. The notion that conserved quantities can be traded for one another in quantum systems is brand new. It may suggest the need for a more complete thermodynamic theory that would describe not only the flow of energy, but also the interplay between all the conserved quantities in the universe.

The fact that energy has dominated the thermodynamics story up to now might be circumstantial rather than profound, Oppenheim said. Carnot and his successors might have developed a thermodynamic theory governing the flow of, say, angular momentum to go with their engine theory, if only there had been a need. "We have energy sources all around us that we want to extract and use," Oppenheim said. "It happens to be the case that we don't have big angular momentum heat baths around us. We don't come across huge gyroscopes."



Popescu, who won a Dirac Medal last year for his insights in quantum information theory and quantum foundations, said he and his collaborators work by "pushing quantum mechanics into a corner," gathering at a blackboard and reasoning their way to a new insight after which it's easy to derive the associated equations. Some realizations are in the process of crystalizing. In one of several phone conversations in March, Popescu discussed a new thought experiment that illustrates a distinction between information and other conserved quantities — and indicates how symmetries in nature might set them apart.

"Suppose that you and I are living on different planets in remote galaxies," he said, and suppose that he, Popescu, wants to communicate where you should look to find his planet. The only problem is, this is physically impossible: "I can send you the story of Hamlet. But I cannot indicate for you a direction."

There's no way to express in a string of pure, directionless 1s and 0s which way to look to find each other's galaxies because "nature doesn't provide us with [a reference frame] that is universal," Popescu said. If it did — if, for instance, tiny arrows were sewn everywhere in the fabric of the universe, indicating its direction of motion — this would violate "rotational invariance," a symmetry of the universe. Turntables would start turning faster when aligned with the universe's motion, and angular momentum would not appear to be conserved. The early-20th-century mathematician Emmy Noether showed that every symmetry comes with a conservation law: The rotational symmetry of the universe reflects the preservation of a quantity we call angular momentum. Popescu's thought experiment suggests that the impossibility of expressing spatial direction with information "may be related to the conservation law," he said.

The seeming inability to express everything about the universe in terms of information could be relevant to the search for a more fundamental description of nature. In recent years, many theorists have come to believe that space-time, the bendy fabric of the universe, and the matter and energy within it might be a hologram that arises from a network of entangled quantum information. "One has to be careful," Oppenheim said, "because information does behave differently than other physical properties, like space-time."

Knowing the logical links between the concepts could also help physicists reason their way inside black holes, mysterious space-time swallowing objects that are known to have temperatures and entropies, and which somehow radiate information. "One of the most important aspects of the black hole is its thermodynamics," Popescu said. "But the type of thermodynamics that they discuss in the black holes, because it's such a complicated subject, is still more of a traditional type. We are developing a completely novel view on thermodynamics." It's "inevitable," he said, "that these new tools that we are developing will then come back and be used in the black hole."

Janet Anders, a quantum information scientist at the University of Exeter, takes a technology-driven approach to understanding quantum thermodynamics. "If we go further and further down [in scale], we're going to hit a region that we don't have a good theory for," Anders said. "And the question is, what do we need to know about this region to tell technologists?"

{"type":"Image","id":"component-594ae4a5be064","data":{"id":45389,"src":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders.jpg","class":"","width":815,"height":456,"mobileSrc":false,"zoomSrc":false,"align":"align=\"right\"","wrapper_width":"","caption":"Janet Anders (lower right) at a 160-person conference on quantum thermodynamics held at the University of Oxford in March.\n","attribution":"Luis Correa\n","variant":"shortcode","size":"wide","disableZoom":false,"srcImage":{"ID":45389,"id":45389,"title":"Anders","filename":"Anders.jpg","url":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders.jpg","alt":"","author":"38","description":"","caption":"","name":"anders","date":"2017-05-01 18:05:33","modified":"2017-05-01 18:20:26","mime_type":"image\/jpeg","type":"image","icon":"https:\/\/api.quantamagazine.org\/wp-includes\/images\/media\/default.png","width":815,"height":456,"sizes":{"thumbnail":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders-520x291.jpg","thumbnail-width":520,"thumbnail-height":291,"medium":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders.jpg","medium-width":815,"medium-height":456,"medium_large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders-768x430.jpg","medium_large-width":768,"medium_large-height":430,"large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders.jpg","large-width":815,"large-height":456,"square_small":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders-160x160.jpg","square_small-width":160,"square_small-height":160,"square_large":"https:\/\/d2r55xnwy6nx47.cloudfront.net\/uploads\/2017\/05\/Anders-520x456.jpg","square_large-width":520,"square_large-height":456}}}}In 2012, Anders conceived of and co-founded a European research network devoted to quantum thermodynamics that now has 300 members. With her colleagues in the network, she hopes to discover the rules governing the quantum transitions of quantum engines and fridges, which could someday drive or cool computers or be used in solar panels, bioengineering and other applications. Already, researchers are getting a better sense of what quantum engines might be capable of. In 2015, Raam Uzdin and colleagues at the Hebrew University of Jerusalem calculated that quantum engines can outpower classical engines. These probabilistic engines still follow Carnot's efficiency formula in terms of how much work they can derive from energy passing between hot and cold bodies. But they're sometimes able to extract the work much more quickly, giving them more power. An engine made of a single ion was experimentally demonstrated and reported in Science in April 2016, though it didn't harness the power-enhancing quantum effect.

Popescu, Oppenheim, Renner and their cohorts are also pursuing more concrete discoveries. In March, Oppenheim and his postdoctoral researcher, Lluis Masanes, published a paper deriving the third law of thermodynamics — a historically confusing statement about the impossibility of reaching absolute-zero temperature — using quantum information theory. They showed that the "cooling speed limit" preventing you from reaching absolute zero arises from the limit on how fast information can be pumped out of the particles in a finite-size object. The speed limit might be relevant to the cooling abilities of quantum fridges, like the one reported in a preprint in February. In 2015, Oppenheim and other collaborators showed that the second law of thermodynamics is replaced, on quantum scales, by a panoply of second "laws" — constraints on how the probability distributions defining the physical states of particles evolve, including in quantum engines.

As the field of quantum thermodynamics grows quickly, spawning a range of approaches and findings, some traditional thermodynamicists see a mess. Peter Hänggi, a vocal critic at the University of Augsburg in Germany, thinks the importance of information is being oversold by ex-practitioners of quantum computing, who he says mistake the universe for a giant quantum information processor instead of a physical thing. He accuses quantum information theorists of confusing different kinds of entropy — the thermodynamic and information-theoretic kinds — and using the latter in domains where it doesn't apply. Maxwell's demon "gets on my nerves," Hänggi said. When asked about Oppenheim and company's second "laws" of thermodynamics, he said, "You see why my blood pressure rises."



While Hänggi is seen as too old-fashioned in his critique (quantum-information theorists do study the connections between thermodynamic and information-theoretic entropy), other thermodynamicists said he makes some valid points. For instance, when quantum information theorists conjure up abstract quantum machines and see if they can get work out of them, they sometimes sidestep the question of how, exactly, you extract work from a quantum system, given that measuring it destroys its simultaneous quantum probabilities. Anders and her collaborators have recently begun addressing this issue with new ideas about quantum work extraction and storage. But the theoretical literature is all over the place.

"Many exciting things have been thrown on the table, a bit in disorder; we need to put them in order," said Valerio Scarani, a quantum information theorist and thermodynamicist at the National University of Singapore who was part of the team that reported the quantum fridge. "We need a bit of synthesis. We need to understand your idea fits there; mine fits here. We have eight definitions of work; maybe we should try to figure out which one is correct in which situation, not just come up with a ninth definition of work."

Oppenheim and Popescu fully agree with Hänggi that there's a risk of downplaying the universe's physicality. "I'm wary of information theorists who believe everything is information," Oppenheim said. "When the steam engine was being developed and thermodynamics was in full swing, there were people positing that the universe was just a big steam engine." In reality, he said, "it's much messier than that." What he likes about quantum thermodynamics is that "you have these two fundamental quantities — energy and quantum information — and these two things meet together. That to me is what makes it such a beautiful theory."

Correction: This article was revised on May 5, 2017, to reflect that Lluis Masanes is a postdoctoral researcher, not a student.

This article was reprinted on Wired.com.

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As physicists extend the 19th-century laws of thermodynamics to the quantum realm, they're rewriting the relationships among energy, entropy and information.

As physicists extend the 19th-century laws of thermodynamics to the quantum realm, they're rewriting the relationships among energy, entropy and information.

Ricardo Bessa for Quanta Magazine

In his 1824 book, Reflections on the Motive Power of Fire, the 28-year-old French engineer Sadi Carnot worked out a formula for how efficiently steam engines can convert heat — now known to be a random, diffuse kind of energy — into work, an orderly kind of energy that might push a piston or turn a wheel. To Carnot's surprise, he discovered that a perfect engine's efficiency depends only on the difference in temperature between the engine's heat source (typically a fire) and its heat sink (typically the outside air). Work is a byproduct, Carnot realized, of heat naturally passing to a colder body from a warmer one.

Carnot died of cholera eight years later, before he could see his efficiency formula develop over the 19th century into the theory of thermodynamics: a set of universal laws dictating the interplay among temperature, heat, work, energy and entropy — a measure of energy's incessant spreading from more- to less-energetic bodies. The laws of thermodynamics apply not only to steam engines but also to everything else: the sun, black holes, living beings and the entire universe. The theory is so simple and general that Albert Einstein deemed it likely to "never be overthrown."

Yet since the beginning, thermodynamics has held a singularly strange status among the theories of nature.

"If physical theories were people, thermodynamics would be the village witch," the physicist Lídia del Rio and co-authors wrote last year in Journal of Physics A. "The other theories find her somewhat odd, somehow different in nature from the rest, yet everyone comes to her for advice, and no one dares to contradict her."

Unlike, say, the Standard Model of particle physics, which tries to get at what exists, the laws of thermodynamics only say what can and can't be done. But one of the strangest things about the theory is that these rules seem subjective. A gas made of particles that in aggregate all appear to be the same temperature — and therefore unable to do work — might, upon closer inspection, have microscopic temperature differences that could be exploited after all. As the 19th-century physicist James Clerk Maxwell put it, "The idea of dissipation of energy depends on the extent of our knowledge."

\nIn recent years, a revolutionary understanding of thermodynamics has emerged that explains this subjectivity using quantum information theory — "a toddler among physical theories," as del Rio and co-authors put it, that describes the spread of information through quantum systems. Just as thermodynamics initially grew out of trying to improve steam engines, today's thermodynamicists are mulling over the workings of quantum machines. Shrinking technology — a single-ion engine and three-atom fridge were both experimentally realized for the first time within the past year — is forcing them to extend thermodynamics to the quantum realm, where notions like temperature and work lose their usual meanings, and the classical laws don't necessarily apply.

They've found new, quantum versions of the laws that scale up to the originals. Rewriting the theory from the bottom up has led experts to recast its basic concepts in terms of its subjective nature, and to unravel the deep and often surprising relationship between energy and information — the abstract 1s and 0s by which physical states are distinguished and knowledge is measured. "Quantum thermodynamics" is a field in the making, marked by a typical mix of exuberance and confusion. {\"type\":\"Image\",\"id\":\"component-594ae4a5bad0e\",\"data\":{\"id\":45268,\"src\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium.jpg\",\"class\":\"\",\"width\":1720,\"height\":962,\"mobileSrc\":false,\"zoomSrc\":false,\"align\":\"align=\\\"right\\\"\",\"wrapper_width\":\"\",\"caption\":\"Sandu Popescu, a professor of physics at the University of Bristol.\\n\",\"attribution\":\"Anna I Popescu\\n\",\"variant\":\"shortcode\",\"size\":\"wide\",\"disableZoom\":false,\"srcImage\":{\"ID\":45268,\"id\":45268,\"title\":\"Sandu_Popescu_Medium\",\"filename\":\"Sandu_Popescu_Medium.jpg\",\"url\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium.jpg\",\"alt\":\"\",\"author\":\"38\",\"description\":\"\",\"caption\":\"\",\"name\":\"sandu_popescu_medium\",\"date\":\"2017-05-01 16:21:35\",\"modified\":\"2017-05-01 18:13:26\",\"mime_type\":\"image\\/jpeg\",\"type\":\"image\",\"icon\":\"https:\\/\\/api.quantamagazine.org\\/wp-includes\\/images\\/media\\/default.png\",\"width\":1720,\"height\":962,\"sizes\":{\"thumbnail\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium-520x291.jpg\",\"thumbnail-width\":520,\"thumbnail-height\":291,\"medium\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium-1720x962.jpg\",\"medium-width\":1720,\"medium-height\":962,\"medium_large\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium-768x430.jpg\",\"medium_large-width\":768,\"medium_large-height\":430,\"large\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium.jpg\",\"large-width\":1720,\"large-height\":962,\"square_small\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium-160x160.jpg\",\"square_small-width\":160,\"square_small-height\":160,\"square_large\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Sandu_Popescu_Medium-520x520.jpg\",\"square_large-width\":520,\"square_large-height\":520}}}}

"We are entering a brave new world of thermodynamics," said Sandu Popescu, a physicist at the University of Bristol who is one of the leaders of the research effort. "Although it was very good as it started," he said, referring to classical thermodynamics, "by now we are looking at it in a completely new way."

In an 1867 letter to his fellow Scotsman Peter Tait, Maxwell described his now-famous paradox hinting at the connection between thermodynamics and information. The paradox concerned the second law of thermodynamics — the rule that entropy always increases — which Sir Arthur Eddington would later say "holds the supreme position among the laws of nature." According to the second law, energy becomes ever more disordered and less useful as it spreads to colder bodies from hotter ones and differences in temperature diminish. (Recall Carnot's discovery that you need a hot body and a cold body to do work.) Fires die out, cups of coffee cool and the universe rushes toward a state of uniform temperature known as "heat death," after which no more work can be done.

The great Austrian physicist Ludwig Boltzmann showed that energy disperses, and entropy increases, as a simple matter of statistics: There are many more ways for energy to be spread among the particles in a system than concentrated in a few, so as particles move around and interact, they naturally tend toward states in which their energy is increasingly shared.

But Maxwell's letter described a thought experiment in which an enlightened being — later called Maxwell's demon — uses its knowledge to lower entropy and violate the second law. The demon knows the positions and velocities of every molecule in a container of gas. By partitioning the container and opening and closing a small door between the two chambers, the demon lets only fast-moving molecules enter one side, while allowing only slow molecules to go the other way. The demon's actions divide the gas into hot and cold, concentrating its energy and lowering its overall entropy. The once useless gas can now be put to work.

Maxwell and others wondered how a law of nature could depend on one's knowledge — or ignorance — of the positions and velocities of molecules. If the second law of thermodynamics depends subjectively on one's information, in what sense is it true?



A century later, the American physicist Charles Bennett, building on work by Leo Szilard and Rolf Landauer, resolved the paradox by formally linking thermodynamics to the young science of information. Bennett argued that the demon's knowledge is stored in its memory, and memory has to be cleaned, which takes work. (In 1961, Landauer calculated that at room temperature, it takes at least 2.9 zeptojoules of energy for a computer to erase one bit of stored information.) In other words, as the demon organizes the gas into hot and cold and lowers the gas's entropy, its brain burns energy and generates more than enough entropy to compensate. The overall entropy of the gas-demon system increases, satisfying the second law of thermodynamics.

The findings revealed that, as Landauer put it, "Information is physical." The more information you have, the more work you can extract. Maxwell's demon can wring work out of a single-temperature gas because it has far more information than the average user.

But it took another half century and the rise of quantum information theory, a field born in pursuit of the quantum computer, for physicists to fully explore the startling implications.

Over the past decade, Popescu and his Bristol colleagues, along with other groups, have argued that energy spreads to cold objects from hot ones because of the way information spreads between particles. According to quantum theory, the physical properties of particles are probabilistic; instead of being representable as 1 or 0, they can have some probability of being 1 and some probability of being 0 at the same time. When particles interact, they can also become entangled, joining together the probability distributions that describe both of their states. A central pillar of quantum theory is that the information — the probabilistic 1s and 0s representing particles' states — is never lost. (The present state of the universe preserves all information about the past.)

{\"type\":\"LinkList\",\"id\":\"component-594ae4a5bbf66\",\"data\":{\"title\":\"Related articles\",\"links\":[{\"type\":\"internal\",\"link\":\"https:\\/\\/www.quantamagazine.org\\/quantum-entanglement-drives-the-arrow-of-time-scientists-say-20140416\\/\",\"title\":\"Time\\u2019s Arrow Traced to Quantum Source\"},{\"type\":\"internal\",\"link\":\"https:\\/\\/www.quantamagazine.org\\/the-computational-foundation-of-life-20170126\\/\",\"title\":\"How Life (and Death) Spring From Disorder\"},{\"type\":\"internal\",\"link\":\"https:\\/\\/www.quantamagazine.org\\/frontier-of-physics-interactive-map-20150803\\/\",\"title\":\"Theories of Everything, Mapped\"},{\"type\":\"internal\",\"link\":\"https:\\/\\/www.quantamagazine.org\\/tensor-networks-and-entanglement-20150428\\/\",\"title\":\"How Quantum Pairs Stitch Space-Time\"}]}}Over time, however, as particles interact and become increasingly entangled, information about their individual states spreads and becomes shuffled and shared among more and more particles. Popescu and his colleagues believe that the arrow of increasing quantum entanglement underlies the expected rise in entropy — the thermodynamic arrow of time. A cup of coffee cools to room temperature, they explain, because as coffee molecules collide with air molecules, the information that encodes their energy leaks out and is shared by the surrounding air.

Understanding entropy as a subjective measure allows the universe as a whole to evolve without ever losing information. Even as parts of the universe, such as coffee, engines and people, experience rising entropy as their quantum information dilutes, the global entropy of the universe stays forever zero.

Renato Renner, a professor at ETH Zurich in Switzerland, described this as a radical shift in perspective. Fifteen years ago, "we thought of entropy as a property of a thermodynamic system," he said. "Now in information theory, we wouldn't say entropy is a property of a system, but a property of an observer who describes a system."

Moreover, the idea that energy has two forms, useless heat and useful work, "made sense for steam engines," Renner said. "In the new way, there is a whole spectrum in between — energy about which we have partial information."

Entropy and thermodynamics are "much less of a mystery in this new view," he said. "That's why people like the new view better than the old one."

The relationship among information, energy and other "conserved quantities," which can change hands but never be destroyed, took a new turn in two papers published simultaneously last July in Nature Communications, one by the Bristol team and another by a team that included Jonathan Oppenheim at University College London. Both groups conceived of a hypothetical quantum system that uses information as a sort of currency for trading between the other, more material resources.

{\"type\":\"Image\",\"id\":\"component-594ae4a5bcfe9\",\"data\":{\"id\":45429,\"src\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500.jpg\",\"class\":\"\",\"width\":615,\"height\":344,\"mobileSrc\":false,\"zoomSrc\":false,\"align\":\"align=\\\"right\\\"\",\"wrapper_width\":\"\",\"caption\":\"Jonathan Oppenheim, a professor of quantum theory at University College London.\\n\",\"attribution\":\"Ezra Press\\n\",\"variant\":\"shortcode\",\"size\":\"wide\",\"disableZoom\":false,\"srcImage\":{\"ID\":45429,\"id\":45429,\"title\":\"Oppenheim_LR-500\",\"filename\":\"Oppenheim_LR-500.jpg\",\"url\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500.jpg\",\"alt\":\"\",\"author\":\"38\",\"description\":\"\",\"caption\":\"\",\"name\":\"oppenheim_lr-500\",\"date\":\"2017-05-01 18:29:54\",\"modified\":\"2017-05-01 18:51:49\",\"mime_type\":\"image\\/jpeg\",\"type\":\"image\",\"icon\":\"https:\\/\\/api.quantamagazine.org\\/wp-includes\\/images\\/media\\/default.png\",\"width\":615,\"height\":344,\"sizes\":{\"thumbnail\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500-520x291.jpg\",\"thumbnail-width\":520,\"thumbnail-height\":291,\"medium\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500.jpg\",\"medium-width\":615,\"medium-height\":344,\"medium_large\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500.jpg\",\"medium_large-width\":615,\"medium_large-height\":344,\"large\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500.jpg\",\"large-width\":615,\"large-height\":344,\"square_small\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500-160x160.jpg\",\"square_small-width\":160,\"square_small-height\":160,\"square_large\":\"https:\\/\\/d2r55xnwy6nx47.cloudfront.net\\/uploads\\/2017\\/05\\/Oppenheim_LR-500-520x344.jpg\",\"square_large-width\":520,\"square_large-height\":344}}}}Imagine a vast container, or reservoir, of particles that possess both energy and angular momentum (they're both moving around and spinning). This reservoir is connected to both a weight, which takes energy to lift, and a turning turntable, which takes angular momentum to speed up or slow down. Normally, a single reservoir can't do any work — this goes back to Carnot's discovery about the need for hot and cold reservoirs. But the researchers found that a reservoir containing multiple conserved quantities follows different rules. "If you have two different physical quantities that are conserved, like energy and angular momentum," Popescu said, "as long as you have a bath that contains both of them, then you can trade one for another."

In the hypothetical weight-reservoir-turntable system, the weight can be lifted as the turntable slows down, or, conversely, lowering the weight causes the turntable to spin faster. The researchers found that the quantum information describing the particles' energy and spin states can act as a kind of currency that enables trading between the reservoir's energy and angular momentum supplies. The notion that conserved quantities can be traded for one another in quantum systems is brand new. It may suggest the need for a more complete thermodynamic theory that would describe not only the flow of energy, but also the interplay between all the conserved quantities in the universe.

The fact that energy has dominated the thermodynamics story up to now might be circumstantial rather than profound, Oppenheim said. Carnot and his successors might have developed a thermodynamic theory governing the flow of, say, angular momentum to go with their engine theory, if only there had been a need. "We have energy sources all around us that we want to extract and use," Oppenheim said. "It happens to be the case that we don't have big angular momentum heat baths around us. We don't come across huge gyroscopes."



Popescu, who won a Dirac Medal last year for his insights in quantum information theory and quantum foundations, said he and his collaborators work by "pushing quantum mechanics into a corner," gathering at a blackboard and reasoning their way to a new insight after which it's easy to derive the associated equations. Some realizations are in the process of crystalizing. In one of several phone conversations in March, Popescu discussed a new thought experiment that illustrates a distinction between information and other conserved quantities — and indicates how symmetries in nature might set them apart.

"Suppose that you and I are living on different planets in remote galaxies," he said, and suppose that he, Popescu, wants to communicate where you should look to find his planet. The only problem is, this is physically impossible: "I can send you the story of Hamlet. But I cannot indicate for you a direction."

There's no way to express in a string of pure, directionless 1s and 0s which way to look to find each other's galaxies because "nature doesn't provide us with [a reference frame] that is universal," Popescu said. If it did — if, for instance, tiny arrows were sewn everywhere in the fabric of the universe, indicating its direction of motion — this would violate "rotational invariance," a symmetry of the universe. Turntables would start turning faster when aligned with the universe's motion, and angular momentum would not appear to be conserved. The early-20th-century mathematician Emmy Noether showed that every symmetry comes with a conservation law: The rotational symmetry of the universe reflects the preservation of a quantity we call angular momentum. Popescu's thought experiment suggests that the impossibility of expressing spatial direction with information "may be related to the conservation law," he said.

The seeming inability to express everything about the universe in terms of information could be relevant to the search for a more fundamental description of nature. In recent years, many theorists have come to believe that space-time, the bendy fabric of the universe, and the matter and energy within it might be a hologram that arises from a network of entangled quantum information. "One has to be careful," Oppenheim said, "because information does behave differently than other physical properties, like space-time."

Knowing the logical links between the concepts could also help physicists reason their way inside black holes, mysterious space-time swallowing objects that are known to have temperatures and entropies, and which somehow radiate information. "One of the most important aspects of the black hole is its thermodynamics," Popescu said. "But the type of thermodynamics that they discuss in the black holes, because it's such a complicated subject, is still more of a traditional type. We are developing a completely novel view on thermodynamics." It's "inevitable," he said, "that these new tools that we are developing will then come back and be used in the black hole."

Janet Anders, a quantum information scientist at the University of Exeter, takes a technology-driven approach to understanding quantum thermodynamics. "If we go further and further down [in scale], we're going to hit a region that we don't have a good theory for," Anders said. "And the question is, what do we need to know about this region to tell technologists?"

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Popescu, Oppenheim, Renner and their cohorts are also pursuing more concrete discoveries. In March, Oppenheim and his postdoctoral researcher, Lluis Masanes, published a paper deriving the third law of thermodynamics — a historically confusing statement about the impossibility of reaching absolute-zero temperature — using quantum information theory. They showed that the "cooling speed limit" preventing you from reaching absolute zero arises from the limit on how fast information can be pumped out of the particles in a finite-size object. The speed limit might be relevant to the cooling abilities of quantum fridges, like the one reported in a preprint in February. In 2015, Oppenheim and other collaborators showed that the second law of thermodynamics is replaced, on quantum scales, by a panoply of second "laws" — constraints on how the probability distributions defining the physical states of particles evolve, including in quantum engines.

As the field of quantum thermodynamics grows quickly, spawning a range of approaches and findings, some traditional thermodynamicists see a mess. Peter Hänggi, a vocal critic at the University of Augsburg in Germany, thinks the importance of information is being oversold by ex-practitioners of quantum computing, who he says mistake the universe for a giant quantum information processor instead of a physical thing. He accuses quantum information theorists of confusing different kinds of entropy — the thermodynamic and information-theoretic kinds — and using the latter in domains where it doesn't apply. Maxwell's demon "gets on my nerves," Hänggi said. When asked about Oppenheim and company's second "laws" of thermodynamics, he said, "You see why my blood pressure rises."



While Hänggi is seen as too old-fashioned in his critique (quantum-information theorists do study the connections between thermodynamic and information-theoretic entropy), other thermodynamicists said he makes some valid points. For instance, when quantum information theorists conjure up abstract quantum machines and see if they can get work out of them, they sometimes sidestep the question of how, exactly, you extract work from a quantum system, given that measuring it destroys its simultaneous quantum probabilities. Anders and her collaborators have recently begun addressing this issue with new ideas about quantum work extraction and storage. But the theoretical literature is all over the place.

"Many exciting things have been thrown on the table, a bit in disorder; we need to put them in order," said Valerio Scarani, a quantum information theorist and thermodynamicist at the National University of Singapore who was part of the team that reported the quantum fridge. "We need a bit of synthesis. We need to understand your idea fits there; mine fits here. We have eight definitions of work; maybe we should try to figure out which one is correct in which situation, not just come up with a ninth definition of work."

Oppenheim and Popescu fully agree with Hänggi that there's a risk of downplaying the universe's physicality. "I'm wary of information theorists who believe everything is information," Oppenheim said. "When the steam engine was being developed and thermodynamics was in full swing, there were people positing that the universe was just a big steam engine." In reality, he said, "it's much messier than that." What he likes about quantum thermodynamics is that "you have these two fundamental quantities — energy and quantum information — and these two things meet together. That to me is what makes it such a beautiful theory."

Correction: This article was revised on May 5, 2017, to reflect that Lluis Masanes is a postdoctoral researcher, not a student.

This article was reprinted on Wired.com.

Ricardo Bessa for Quanta Magazine



Source

lunes, 29 de agosto de 2016

Ocho arquitectos del sur del continente entregan su conocimiento en la USFQ

José Guaygua

La Universidad San Francisco de Quito (USFQ) realiza, por decimoséptima vez, su foro internacional de arquitectura.

Esta vez el tema será 'Arquitectos de cinco ciudades del Cono Sur desde el llano', y han sido invitados relevantes arquitectos de Argentina, Paraguay y Uruguay.

El evento se desarrollará entre el viernes 24 y el sábado 25, en el teatro Calderón de la Barca, desde las 10:15 hasta las 18:00.

La apertura del evento estará a cargo de Fernando Diez, quien analizará 'La Huella de la madera en la arquitectura argentina'. Él es doctor por la Universidad Federal de Rio grande do Sul, Brasil. Actualmente es docente en la Universidad de Palermo, donde también es director del Departamento de Historia y Teoría.

Sus logros han sido reconocidos con los premios Rogelio Salmona y Latin America Holcim Awards 2008 y 2014, respectivamente. Desde 1994 se ha desempeñado como director editorial de la revista Summa+. Y ha publicado libros destacados como 'Buenos Aires y algunas constantes en las transformaciones urbanas' (1996), 'Crisis de autenticidad' (2008) y 'Agenda Pendiente'.

Inmediatamente se abordará la temática 'Entre luces y sombras'. Para ello se invitó, desde Paraguay, a Luis Elgue, miembro del Consejo Directivo de la Facultad de Arquitectura Diseño y Arte (FADA) de la Universidad Nacional de Asunción.

Gracias a su obra, Boceto el año pasado ganó la IX Bienal de Arquitectura y Urbanismo, en Rosario (Argentina). Su talento lo ha llevado como docente invitado a facultades como la Escuela de Arquitectura en Venecia (Italia), Universidad Nacional de Colombia en Bogotá. Hace dos años fue invitado por la G.S.D –Escuela de Posgrado en Diseño- de la Universidad de Harvard (Estados Unidos).

Por la tarde, a partir de las 15:15, Marcelo Gualano dictará la charla 'Obra Propia'. Este arquitecto uruguayo tiene ocho premios a su haber y ha dictado 20 conferencias en países como México, Venezuela, Perú, Argentina, Paraguay, España, Brasil e Italia.

El último invitado del día es el argentino Gerardo Caballero. Un experto que, desde 1988, desarrolla varias obras importantes en su país, específicamente en la ciudad de Rosario.

Su propuesta es 'La construcción del pensamiento'. En esta explicará la simbiosis entre teoría y práctica. Por una parte la arquitectura atiende las demandas del mundo de las ideas, de lo abstracto, de los conceptos de la reflexión. Pero no puede descuidarse del mundo de la acción y la experiencia.

El sábado, Mónica Bertolino abrirá el telón con 'Entonces la alteridad'. Inauguró su propia oficina de arquitectura en 1982, donde desarrolló proyectos que le valieron el Premio Konex 2010 a las Artes Visuales rubro Arquitectura y la nominación Marcus Prize Milwakee 2011 y 2013 The University of Wisconsin-Milwaukee School of Architecture & Urban Planning (Estado Unidos).

Por su edificación Granja Educativa en Capilla del Monte ganó el Premio Bienal Iberoamericana de Arquitectura y Urbanismo, en 2010.

Fue profesora y conferencista invitada en universidades y congresos de Argentina, Brasil, Chile, Ecuador, Perú, Uruguay, Colombia, Nicaragua, Estados Unidos, Alemania, Sudáfrica, España, Italia y Grecia.

El profesor de Proyecto y Construcción de la Escuela de Arquitectura y Estudios Urbanos de la UTDT de Buenos Aires, Mariano Clusella, llega al foro con la propuesta 'Ficciones'. Su trabajo está enfocado en obras de escala media en áreas urbanas, suburbanas y rurales de Argentina y Uruguay.

Ana Rascovsky, especializada en urbanismo, diseño de paisaje, arquitectura y diseño industrial, expondrá el tópico 'Más conferencias sobre edificios y comida'.

Sus creaciones le valieron el premio Bienal SCA-CPAU 2008, 2010 y 2012. Asimismo, el premio Puro Diseño 2009 y premio Jóvenes Arquitectos Klaukol, en 2010.

El evento concluye con la intervención de Augusto Penedo con 'Arquitectura sin/con'. Tiene una trayectoria de 41 años, y entre sus edificaciones destacan el Hospital de Orán (Salta), Centro Gubernamental de La Plata, Aeropuerto Internacional de Ezeiza, Mercado Central de Buenos Aires y la planta impresora de diario La Nación.

Ha ganado siete premios. Entre estos el de la Cámara Argentina de la Construcción y el del Museo de la Ciudad a las obras del Hotel 725 Continental y el Edificio de Oficinas de la Avenida Santa Fe 927, declarado Testimonio Vivo de la Memoria Ciudadana (2004).

Fuente

jueves, 19 de noviembre de 2015

How SAP helped streamline modern database response time

Decades ago, in-memory databases were divided into two distinct components: transactional databases and analytic databases. This was done because, in terms of response time, the analytic databases began to seriously outpace their transactional counterparts. However, because of SAP SE’s HANA database management system, analytic and transactional databases are being reunified, because HANA allows them to function together in real-time, according to Quentin Clark, chief business officer at SAP.

Clark spoke to George Gilbert, Wikibon’s Big Data analyst and cohost of theCUBE, from the SiliconANGLE Media team, during Structure 2015 in San Francisco.

SAP S/4HANA and new features in supply management

Although transitional and analytic databases have been reunified, other issues, such as duplicate data and certain user inputs, have meant that newer reunified databases do not always function in real-time.

“This month we released this version of S/4HANA that supports all our logistics, manufacturing, supply management, that functionality, in addition to finance,” Clark said. “And in that space, (with) the supply optimization that can be done, with the prediction capabilities that are in HANA, in that integrated hole between what has happened, and what is currently going on, has produced new features in supply management.”

Database pricing: Traditional vs. logical tier

As modern data capture volumes change compared to past levels, traditional database pricing is seen by some as excessive, Clark explained. Logical tier pricing is an option, although some companies are unsure about this approach because it would require changes in how applications treat the data.

“The HANA system, because it’s married together the transactional/analytic side, is allowing us to build our applications with new value,” said Clark, “and leveraging the in-memory data structures and leveraging the in-memories per revolution if you will … to achieve that, the value is there. And customers will always pay for the great value.”

Source

lunes, 6 de octubre de 2014

El maíz, ¿la posible cura del cáncer?

Sus proteínas y péptidos contienen propiedades antioxidantes y anticancerígenas. Diversos estudios ya trabajan en un nuevo enfoque, evaluando los componentes de este cereal con la finalidad de que puedan aplicarse como fármacos.

Su precio en el mercado internacional baja, aumentan los costos locales y encima se aplican derechos de exportación del 20%: el maíz no atraviesa su mejor momento en la Argentina y en el mundo. El maíz, ¿la posible cura del cáncer?

Sin embargo, la cuestión para este cereal podría cambiar, ya que no sólo se trata de un pilar de la buena alimentación, sino que está comprobado que el maíz y otros granos poseen un enorme potencial en el cuidado de la salud.

Esto se debe a sus proteínas y péptidos (componente de menor tamaño pero igual composición que las proteínas), que contienen propiedades antioxidantes y anticancerígenas, y sus compuestos tienen aplicación en la prevención y el tratamiento de enfermedades crónico-degenerativas. Así lo informó desde Madrid, España, la web Noticias de la Ciencia y la Tecnología.

Y más aún. Todas estas propiedades han hecho que se empiece a trabajar en el maíz en cuestiones más allá de las alimenticias. Margarita Ortiz Martínez, alumna del Doctorado en Biotecnología (DBT) del Tecnológico de Monterrey, en Monterrey, México, trabaja en un nuevo enfoque, que consiste en la evaluación de los componentes de este cereal pero de manera aislada, con la finalidad de que puedan aplicarse como fármacos.

El rastreo de péptidos en cereales es una forma de aprovechar su patrimonio genético y las particularidades de su proteoma (la totalidad de proteínas expresadas en una célula particular bajo condiciones de medioambiente y etapa de desarrollo) para obtener un beneficio en la salud humana.

Esta actividad ya se ha hecho con otros cereales. Sin embargo, que se trate del maíz no es algo menor, ya que en Argentina hay, y mucho.

 

 

Fuente