Transparent RAM

This report covers the fabrication of a fully transparent resistive random access memory (TRRAM) device based on an ITO (indium tin oxide)/ZnO/ITO capacitor structure and its resistive switching characteristics. The fabricated TRRAM has a transmittance of 81% (including the substrate) in the visible region and an excellent switching behavior under 3 V.




The retention measurement suggests that the memory property of the TRRAM device could be maintained for more than 10 years. We believe that the TRRAM device presented in this work could be a milestone of future see-through electronic devices. ©2008 American Institute of Physics. Jung Won Seo, Jae-Woo Park, Keong Su Lim, Ji-Hwan Yang, and Sang Jung Kang, School of Electrical Engineering and Computer Science, Korea Advanced Institute of Science and Technology (KAIST). [link]

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2.5 Inch SSD

Shortly on the heels of Toshiba’s propping up of SanDisk to gain some leverage in the SSD market against giant Samsung, Toshiba has announced that it will be bringing a new lineup of NAND-flash-based solid state drives to market in the first quarter of 2009. Claiming the industry’s first 2.5-inch 512GB SSD, based on 43 nanometer Multi-Level Cell NAND, Toshiba Semiconductor VP Kiyoshi Kobayashi stated “This new 43nm SSD family balances value/performance characteristics for its targeted consumer applications, through use of MLC NAND and an advanced controller architecture.”
The drives maximum sequential read speed is 240MB ps, with a maximum sequential write speed of 200MBps. Mass production isnt supposed to begin until the second quarter of 09.

More here

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Record your Dreams

Opens the way for people to communicate directly from their mind

TOKYO - Japanese researchers have reproduced images of things people were looking at by analyzing brain scans, opening the way for people to communicate directly from their mind.

They hope their study, published in the U.S. journal Neuron, will lead to helping people with speech problems or doctors studying mental disorders, although there are privacy issues if it gets to the stage where someone can read a sleeping person's dreams.

"When we want to convey a message, we need to move our body, for example by speaking or by tapping a keyboard," said Yukiyasu Kamitani, the project's head researcher from the Advanced Telecommunications Research Institute International, a private institute based in Kyoto, Japan.

"But if we can get information directly from the brain, it will be possible to communicate directly by imagining what we want to say, without having to move," Kamitani said in a telephone interview with Reuters.

Such technology might one day open the way to communication for people who cannot speak or help visualize hallucinations to assist doctors diagnosing mental disorders, Kamitani added.

When we see, light is converted into electric signals by the retina, at the back of the eye, then processed by the brain's visual cortex.

Researchers from the five institutions involved in the research used a medical brain scanner to look at activity patterns in the visual cortex.

Kamitani's team calibrated a computer program by scanning two volunteers staring at over 400 different still images in black, white and grey.

Then, the volunteers were shown different black-and-white geometric figures and letters of the alphabet.

Their computer program was able to reproduce the figures and letters that the volunteers had seen, although more blurry than the originals.

"In this experiment, we reconstructed images of what people actually saw, but the brain's visual cortex is said to be active even when just imagining something," Kamitani said.

The next step for the team is to study how to visualize images inside people's minds, he said.

"We want to know how our subjective experiences and dreams are expressed inside our brains," Kamitani said, adding that the study might lead to producing images of dreams.

If the team does manage that there were potential privacy issues and strong safeguards would be needed, he said.

"As accuracy rises, it is possible that information that people want to keep private could also be visualized while they are sleeping."

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Reasons for seasons

Earth's tilt affects seasons. In this graphic, distances and sizes are not to scale.

View related photos

The seasons are a powerful force in our lives. They affect the activities we do, the foods we crave, the clothes we wear — and quite often, the moods we are in. The seasons officially changed once again Sunday, with winter beginning in the Northern Hemisphere and summer starting in the south.

What is it that causes the change in seasons?

The ability to predict the seasons — by tracking the rising and setting points of the sun throughout the year — was key to survival in ancient times. Babylonians, the Maya and other cultures developed complex systems for monitoring seasonal shifts. But it took centuries more to unravel the science behind the seasons.

Nicolai Copernicus (1473-1543) radically changed our understanding of astronomy when he proposed that the sun, not Earth, was the center of the solar system. This led to our modern understanding of the relationship between the sun and Earth.

We now know that Earth orbits the sun elliptically and, at the same time, spins on an axis that is tilted relative to its plane of orbit. This means that different hemispheres are exposed to different amounts of sunlight throughout the year. Because the sun is our source of light, energy and heat, the changing intensity and concentration of its rays give rise to the seasons of winter, spring, summer and fall.

Solstices and equinoxes
The seasons are marked by solstices and equinoxes — astronomical terms that relate to Earth’s tilt.

The solstices mark the points at which the poles are tilted at their maximum toward or away from the sun. This is when the difference between the daylight hours and the nighttime hours is most acute. The solstices occur each year on June 20 or 21 and Dec. 21 or 22, and represent the official start of the summer and winter seasons.

The vernal equinox and autumnal equinox herald the beginning of spring and fall, respectively. At these times of the year, the sun appears to be directly over Earth’s equator, and the lengths of the day and the night are equal over most of the planet.

On March 20 or 21 of each year, the Northern Hemisphere is reaching the vernal equinox and enjoying the signs of spring. At the same time, the winds are turning cold in the Southern Hemisphere as the autumnal equinox sets in.

The year's other equinox occurs on Sept. 22 or 23, when summer fades to fall in the north, and winter’s chill starts giving way to spring in the south.

From year to year, there is always some variability in the equinoxes and solstices because of the way Earth's changing tilt matches up with its orbit around the sun. This year, the precise moment of the December solstice came at 7:04 a.m. ET Sunday.

Effect on climate
Here’s how the seasonal change affects the weather: Around the time of the June solstice, the North Pole is tilted toward the sun and the Northern Hemisphere is starting to enjoy summer. The density of the solar radiation is higher because it's coming from directly overhead — in other words, the sun's rays are concentrated over a smaller surface area. The days are longer, too, meaning that more radiation is absorbed in northern climes during the 24-hour cycle. Another factor that may come into play is that the radiation takes a somewhat shorter path through the energy-absorbing atmosphere before striking the earth.

At the same time that the Northern Hemisphere is entering summer, the South Pole is tilted away from the sun, and the Southern Hemisphere is starting to feel the cold of winter. The sun’s glancing rays are spread over a greater surface area and must travel through more of the atmosphere before reaching the earth. There are also fewer hours of daylight in a 24-hour period.

The situations are reversed in December, when it’s the Southern Hemisphere that basks in the most direct rays of the sun, while the Northern Hemisphere receives less dense solar radiation for shorter periods of time.

Although the solstices represent the pinnacles of summer and winter with respect to the intensity of the sun’s rays, they do not represent the warmest or coldest days. This is because temperature depends not only on the amount of heat the atmosphere receives from the sun, but also on the amount of heat it loses due to the absorption of this heat by the ground and ocean. It is not until the ground and oceans absorb enough heat to reach equilibrium with the temperature of the atmosphere that we feel the coldest days of winter or hottest days of summer.

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Sensor detects cancer toxins

CHICAGO - U.S. scientists have developed a tiny sensor that can detect small amounts of cancer-causing toxins or trace the effectiveness of cancer drugs inside living cells.

The finding, reported on Sunday in the journal Nature Nanotechnology, offers a new tool for tracking specific chemicals in the body.

"We made a very small nanosensor that can detect cancer-causing molecules or important therapeutic drugs inside of a single living cell," said Michael Strano of Massachusetts Institute of Technology in Cambridge, who worked on the study.

"It's much smaller than a living cell in your body," Strano said in a telephone interview. "It's so small it can be placed into environments that aren't accessible with larger sensors."

Strano said the sensors are made up of thin filaments of carbon molecules known as carbon nanotubes.

Several teams are using nanomaterials -- thousands of times smaller than the width of a human hair -- to develop new ways to deliver drugs in the body or improve diagnosis of disease.

For its sensors, Strano's team wrapped carefully shaped carbon nanotubes with DNA, which offers a binding site for DNA-damaging agents inside cells.

The sensors give off a fluorescent light that can be detected in the near-infrared light spectrum. Because human tissues do not light up in this spectrum, the nanotubes stand out.

Strano said the light signal changes when the sensors interact with DNA inside cells. These changes can help them identify specific molecules.

"It's a way of fingerprinting chemistry," Strano said.

Because the sensors are coated in DNA, Strano said they can be safely injected into living cells.

"Eventually the cell eats the protein off the coating and it essentially spits it out," he said.

He said the most immediate use of the technology will be as a very powerful tool for scientists to study the effects of very small amounts of a chemical.

But it could eventually be used as a new way to image the human body.

"It's a new tool. There is nothing else like it."

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Roads are power stations

AN ENVIRONMENTALLY friendly road that positively welcomes heavy traffic may sound odd, but by placing piezoelectric crystals under the asphalt that convert vibration into electricity, Israeli engineers hope to harvest energy from passing vehicles.

Developer Haim Abramovich at the Technion-Israel Institute of Technology in Haifa says the crystals can produce up to 400 kilowatts from a 1-kilometre stretch of four-lane highway. His spin-out company, Innowattech, also based inHaifa, will begin testing the system on a 100-metre stretch of road in northern Israel in January.

Installing the technology need not produce unnecessary greenhouse gases, says Abramovich: "We're advocating that the system be fitted to roads only during routine maintenance, so there's no extra digging."

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'Mind-reading' software

Pictures you are observing can now be recreated with software that uses nothing but scans of your brain. It is the first "mind reading" technology to create such images from scratch, rather than picking them out from a pool of possible images.

Earlier this year Jack Gallant and colleagues at the University of California, Berkeley, showed that they could tell which of a set of images someone was looking at from a brain scan.

To do this, they created software that compared the subject's brain activity while looking at an image with that captured while they were looking at "training" photographs. The program then picked the most likely match from a set of previously unseen pictures.

Now Yukiyasu Kamitani at ATR Computational Neuroscience Laboratories in Kyoto, Japan has gone a step further: his team has used an image of brain activity taken in a functional MRI scanner to recreate a black-and-white image from scratch.

"By analysing the brain signals when someone is seeing an image, we can reconstruct that image," says Kamitani.

This means that the mind reading isn't limited to a selection of existing images, but could potentially be used to "read off" anything that someone was thinking of, without prior knowledge of what that might be.

"It's absolutely amazing, it really is a very significant step forward," says John-Dylan Haynes of the Max Planck Institute for Human Cognitive and Brain Sciences in Leipzig, Germany.

Dream catcher

Kamitani starts by getting someone to look at a selection of images made up of black and white squares on a 10 by 10 square grid, while having their brain scanned. Software then finds patterns in brain activity that correspond to certain pixels being blacked out. It uses this to record a signature pattern of brain activity for each pixel.

The person then sits in the scanner and is shown fresh patterns. Another piece of software then matches these against the list to reconstruct the pixels on a 10 by 10 grid.

The quality of images that were recreated is quite crude. However, the word "neuron" and several numbers and shapes that people were indeed being shown (see image, top right) could be observed in the reconstructed images. It is an important proof of principle, says Haynes.

As fMRI technology improves, Kamitani adds that an image could potentially be split into many more pixels, producing much higher quality images, and even colour images.

The next step is to find out if it is possible to image things that people are thinking of - as well as what they are looking at - Haynes says it may be possible to "make a videotape of a dream".

Ethical concerns

Haynes also raises the prospect of "neural marketing", where advertisers might one day be able to read the thoughts of passers by and use the results to target adverts. "This [new research] specifically doesn't lead to this - but the whole spirit in which this is done is in line with brain reading and the applications that come with that," he says.

"If you have a technique that allows you to read out what people are thinking we need clearer ethical guidelines about when and how you are able to do this," he says. "A lot of people want their minds to be read - take for example a paralysed person. They want us to read their thoughts," he says. "But it shouldn't be possible to do this for commercial purposes."

Kamitani is well aware of the negative potential of the technology. "If the image quality improves, it could have a very serious impact on our privacy and other issues. We will have to discuss with many people - not just scientists - how to apply this technology," he says.

Journal reference: Neuron

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Water behave as black holes

WHAT does a drop of water have in common with a black hole and an atom? Well, levitating water droplets can now simulate the dynamics of both cosmological and subatomic objects.

Richard Hill and Laurence Eaves at the University of Nottingham, UK, turned to water droplets because the surface tension that holds the drops together can be used to model other forces. For example, the event horizon of a black hole is sometimes thought of as a "stretched" membrane with a surface tension. Similar forces also prevent atoms from flying apart.

The team levitated the droplets using an effect called diamagnetism: when an external magnetic field was applied to the droplets, they created their own opposing magnetic field, initiating a repulsive force strong enough to counteract gravity. To set the droplets spinning, they implanted two tiny electrodes, which generated an electric field.

They found that once a droplet with a diameter of 1 centimetre reached about 3 revolutions per second, its shape, when viewed from above, became triangular, an effect never seen before in the lab (Physical Review Letters, DOI: 10.1103/PhysRevLett.101.234501).

"The breakthrough in this work is the ability to reproduce, in a simple table-top experiment, 100 years of theoretical work in fluid dynamics," says Vitor Cardoso of the University of Mississippi.

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Contacts lens

The University of Washington's Babak Parviz has created a prototype "bionic" contact lens that creates a display over the wearer's visual field, so images, maps, data, etc., appear to float in midair. The lens works using tiny LEDs, which are powered by solar cells, and a radio-frequency receiver.

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Solar Panels

There are countless ways to manufacture solar panels, but there's only one metric that counts: how the cost of solar power compares with that of electricity from fossil fuels. Until energy from the sun can beat energy from coal at the marketplace, solar will remain a niche player, adorning the rooftops of those who care more for their green reputation than for their bottom lines. Enter Nanosolar, a San Jose-based start-up that manufactures thin-film solar panels. Unlike the bulky silicon panels that dominate the solar market, Nanosolar thin-film technology is light and extremely cheap to make. The key is the manufacturing process: while silicon panels need to be baked in batches, Nanosolar's thin-film panels roll off the assembly line, as if from a printing press.

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The invisible

Scientists at UC Berkeley have taken a major step toward making Harry Potter's disguise of choice a reality. They've engineered two new materials — one using a fishnet of metal layers, the other using tiny silver wires — that neither absorb nor reflect light, causing it instead to bend backward. The principle at work is refraction, which is what makes a straw appear bent in a glass of water.

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The 46th Mersenne Prime

A Mersenne number is a positive number that can be expressed in the form 2n-1. A Mersenne prime is a Mersenne number that is, well, prime. Searching for higher and higher Mersenne primes is the unofficial national sport of mathematicians. The 45th and 46th (right) Mersenne primes were found this year, the latter by a team at UCLA. It has almost 13 million digits.

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Einstein's Fridge

That Albert Einstein guy had some pretty good ideas — relativity, the photoelectric effect, the "up" hairdo — but his contributions to the field of refrigerator theory have been sadly neglected. No longer. Scientists at Oxford University have resurrected an eco-friendly refrigerator design that Einstein and a collaborator patented in 1930. Instead of cooling the interior of the refrigerator with freon — a serious contributor to global warming — Einstein's design uses ammonia, butane and water. It also requires very little energy. Though Einstein's original refrigerator wasn't all that efficient, the Oxford researchers have tweaked his version and believe it could eventually compete in the marketplace. Then maybe we'll remember Einstein the way he wanted — as a guy who liked to keep things cool.

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Made-in-Transit Packaging

Most fresh food comes with a "best before" date, but Amsterdam-based Canadian designer Agata Jaworska thinks it should be marked "ready by." Her concept: packaging in which food can keep growing during shipping to the supermarket so that it arrives ready to be harvested, in a state of optimum freshness.

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Super Bike

You really need the mind of a Swiss engineer to come up with a vehicle that combines the lithe maneuverability of a motorcycle with the not-getting-rained-on-ability of a conventional automobile. In addition to looking as though it just fell out of a time machine from a distant and much cooler future, the MonoTracer furnishes its driver (and one passenger) with such luxuries as air-conditioning and windshield wipers, plus the safety of a cockpit made from Kevlar and carbon fiber and reinforced with an aluminum roll cage. The MonoTracer is also energy-efficient: its BMW engine, which goes from zero to 62 m.p.h. in 4.8 sec. (100 km/h), gets about 65 m.p.g. (28 km/L).

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Super electric car

The Aptera is one of the first eco-friendly cars to get high mileage: the all-electric model gets 120 miles (193 km) per charge, and the hybrid gets 300 (483). Extra points for cool design and acceleration from zero to 60 (97 km/h) in under 10 seconds — living up to its name, Greek for "wingless flight."

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A Camera For the Blind

Paradoxical as it sounds, the Touch Sight camera makes it possible for the visually impaired to take pictures. The photographer holds the camera up to his or her forehead, and a Braille-like screen on the back makes a raised image of whatever the lens sees.

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The Large Hadron Collider

If someone invented a practical 200-m.p.g. automobile and that automobile got a flat tire, nobody would claim that the car itself was a failure. The same applies to the Large Hadron Collider, the world's biggest particle accelerator, which went online in September, ran for 10 days and then had to shut down at least until next spring because of an overheated wire. The mammoth machine will send protons wheeling in opposite directions at nearly the speed of light, then smash them together at 6,000 times a second to try to answer such deep questions as why mass exists and whether the universe has extra dimensions. If it takes a few extra months to find out, so what?

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The Shadowless Skyscraper

Very tall buildings are a tough sell in Paris. The Parisians don't want their lovely low-rise city looking too much like Houston.
So Swiss architects Jacques Herzog and Pierre de Meuron knew they'd have to win over skeptical neighbors to get their 50-story tower built.
Le Project Triangle, a combination office/hotel, is the first skyscraper to be approved since Paris lifted a 31-year-old ban on high-rise construction in the city center.
Using computer modeling, the designers of Beijing's "bird's nest" Olympic stadium came up with a building almost as startling: a slender glass-and-steel triangle, like a shark fin, that they say won't cast shadows on surrounding streets.
The pyramid is one of history's oldest building shapes, but a slim triangle? That's new.
Is it the shape of things to come?

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Memristors:Ground breaking circuit

Since the dawn of electronics, we’ve had only three types of circuit components — resistors, inductors, and capacitors.

1 May 2008—Anyone familiar with electronics knows the trinity of fundamental components: the resistor, the capacitor, and the inductor. In 1971, a University of California, Berkeley, engineer predicted that there should be a fourth element: a memory resistor,or memristor. But no one knew how to build one. Now, 37 years later, electronics have finally gotten small enough to reveal the secrets of that fourth element. The memristor, Hewlett-Packard researchers revealed today in the journal Nature, had been hiding in plain sight all along—within the electrical characteristics of certain nanoscale devices. They think the new element could pave the way for applications both near- and far-term, from nonvolatile RAM to realistic neural networks.

The memristor's story starts nearly four decades ago with a flash of insight by IEEE Fellow and nonlinear-circuit-theory pioneer Leon Chua. Examining the relationships between charge and flux in resistors,capacitors, and inductors in a 1971 paper, Chua postulated the existence of a fourth element called the memory resistor. Such a device, he figured, would provide a similar relationship between magnetic flux and charge that a resistor gives between voltage and current. In practice, that would mean it acted like a resistor whose value could vary according to the current passing through it and which would remember that value even after the current disappeared.

But the hypothetical device was mostly written off as a mathematical dalliance. Thirty years later, HP senior fellow Stanley Williams and his group were working on molecular electronics when they started to notice strange behavior in their devices. “They were doing really funky things, and we couldn't figure out what [was going on],” Williams says. Then his HP collaborator Greg Snider rediscovered Chua's work from 1971. “He said, ‘Hey guys, I don't know what we've got, but this is what we want,' ” Williams remembers. Williams spent several years reading and rereading Chua's papers. “It was several years of scratching my head and thinking about it.” Then Williams realized their molecular devices were really memristors. “It just hit me between the eyes.”

The reason that the memristor is radically different from the other fundamental circuit elements is that,unlike them, it carries a memory of its past. When you turn off the voltage to the circuit, the memristor still remembers how much was applied before and for how long.That's an effect that can't be duplicated by any circuit combination of resistors, capacitors, and inductors,which is why the memristor qualifies as a fundamental circuit element.

The classic analogy for a resistor is a pipe through which water (electricity) runs. The width of the pipe is analogous to the resistance of the flow of current—the narrower the pipe, the greater the resistance. Normal resistors have an unchanging pipe size. A memristor, on the other hand, changes with the amount of water that gets pushed through. If you push water through the pipe in one direction, the pipe gets larger (less resistive).If you push the water in the other direction, the pipe gets smaller (more resistive). And the memristor remembers. When the water flow is turned off, the pipe size does not change.

Such a mechanism could technically be replicated using transistors and capacitors, but, Williams says, “it takes a lot of transistors and capacitors to do the job of a single memristor.”

The memristor's memory has consequences: the reason computers have to be rebooted every time they are turned on is that their logic circuits are incapable of holding their bits after the power is shut off. But because a memristor can remember voltages, a memristor-driven computer would arguably never need a reboot. “You could leave all your Word files and spreadsheets open, turn off your computer, and go get a cup of coffee or go on vacation for two weeks,” says Williams. “When you come back, you turn on your computer and everything is instantly on the screen exactly the way you left it.”

Chua deduced the existence of memristors from the mathematical relationships between the circuit elements.The four circuit quantities (charge, current, voltage,and magnetic flux) can be related to each other in six ways. Two quantities are covered by basic physical laws,and three are covered by known circuit elements (resistor, capacitor, and inductor), says Columbia University electrical engineering professor David Vallancourt. That leaves one possible relation unaccounted for. Based on this realization, Chua proposed the memristor purely for the mathematical aesthetics of it, as a class of circuit element based on a relationship between charge and flux.

Chua calls the HP work a paradigm shift; he likens the addition of the memristor to the circuit design arsenal to adding a new element to the periodic table: for one thing, “now all the EE textbooks need to be changed,” he says.

So why hadn't anyone seen memristance? Chua actually produced a memristor in the 1970s with an impractical combination of resistors, capacitors, inductors,and amplifiers as a proof of concept. But memristance as a property of a material was, until recently, too subtle to make use of. It is swamped by other effects,until you look at materials and devices that are mere nanometers in size.

No one was looking particularly hard for memristance,either. In the absence of an application, there was no need. No engineers were saying, “If we only had a memristor, we could do X,” says Vallancourt. In fact,Vallancourt, who has been teaching circuit design for years, had never heard of memristance before this week.

"now all the EE textbooks need to be changed"

But the smaller the scales of the devices scientists and engineers were working with got, the more the devices started behaving with the postulated memristor” effect, says Chua, who is now a senior professor at Berkeley.

There had been clues to the memristor's existence all along. “People have been reporting funny current voltage characteristics in the literature for 50 years,”Williams says. “I went to these old papers and looked at the figures and said, ‘Yup, they've got memristance, and they didn't know how to interpret it.' ”

“Without Chua's circuit equations, you can't make use of this device,” says Williams. “It's such a funky thing. People were using all the wrong circuit equations. It's like taking a washing machine motor and putting it into a gasoline-powered car and wondering why it won't run.”

Williams found an ideal memristor in titanium dioxide—the stuff of white paint and sunscreen. Like silicon, titanium dioxide (TiO₂)is a semiconductor, and in its pure state it is highly resistive. However, it can be doped with other elements to make it very conductive. In TiO₂, the dopants don't stay stationary in a high electric field; they tend to drift in the direction of the current. Such mobility is poison to a transistor, but it turns out that's exactly what makes a memristor work. Putting a bias voltage across a thin film of TiO₂ semiconductor that has dopants only on one side causes them to move into the pure TiO₂ on the other side and thus lowers the resistance. Running current in the other direction will then push the dopants back into place, increasing the TiO₂'s resistance.

HP Labs is now working out how to manufacture memristors from TiO₂ and other materials and figuring out the physics behind them. They also have a circuit group working out how to integrate memristors and silicon circuits on the same chip. The HP group has a hybrid silicon CMOS memristor chip “sitting on a chip tester in our lab right now,” says Williams.

The implications for circuit design may be niche at the moment. “This will require a fair amount of work to exploit,” says Columbia's Vallancourt. Applications will have to be identified in which the memristor's unique characteristics offer possibilities not covered by today's components.

Williams is in talks with several neuroscience/engineering labs that are pursuing the goal of building devices that emulate neural systems.Chua says that synapses, the connections between neurons,have some memristive behavior. Therefore, a memristor would be the ideal electronic device to emulate a synapse.

By redesigning certain types of circuits to include memristors, Williams expects to obtain the same function with fewer components, making the circuit itself less expensive and significantly decreasing its power consumption. In fact, he hopes to combine memristors with traditional circuit-design elements to produce a device that does computation in a non-Boolean fashion.“We won't claim that we're going to build a brain, but we want something that will compute like a brain,”Williams says. They think they can abstract “the whole synapse idea” to do essentially analog computation in an efficient manner. “Some things that would take a digital computer forever to do,an analog computer would just breeze through,” he says.

The HP group is also looking at developing a memristor-based nonvolatile memory. “A memory based on memristors could be 1000 times faster than magnetic disks and use much less power,” Williams says, sounding like a kid in a candy store.

Chua agrees that nonvolatile memory is the most near-term application. “I'm very happy that this is a breakthrough,” he says. “The reality is that at the nanoscale, this effect becomes dominant, and you'll find it whether you like it or not. I'm glad I can point people in the right direction.”

The new component added to the basic components in the science of electronics.

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