Sentences with phrase «new transistor»
It required developing new transistor technology to ensure that the switch had low resistance when it was on but an extremely high resistance when off.
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SMALL WONDER A new transistor, made with carbon nanotubes, is tinier than standard silicon versions.
Alternatively, the new transistors consume less than half the power when at the same performance as 2 - D planar transistors on 32nm chips.
Changes to the 3D structure of the chip's new transistors, thanks to Samsung's 14nm manufacturing process, allows for speeds that are up to 15 percent faster, while also reducing power use by 15 percent.
Not exact matches
In his new book, The Idea Factory: Bell Labs and the Great Age of American Innovation (Penguin), Jon Gertner vividly tells the story of the transistor, as well as the dozens of other innovations that rolled out of Bell Labs.
«Pyre» comes from Supergiant Games, the folks behind new - classics like «Bastion» and «Transistor.»
By the 1970s and 1980s, Japan extended its domination to the global electronics industry as it manufactured the majority of the world's consumer electronics products and introduced innovative and revolutionary new products such as the pocket transistor radio, the VHS recorder and the Sony Walkman, which created a consumer love affair that was similar to the Apple iPod and iPhone craze of recent years.
Yet, the pace of innovation and new efficiencies to be had from shrinking transistors has slowed.
Researchers are now reporting in the journal ACS Nano a new, inexpensive and simple way to make transparent, flexible transistors — the building blocks of electronics — that could help bring roll - up smartphones with see - through displays and other bendable gadgets to consumers in just a few years.
Just when experts were beginning to fear that the conventional transistor would become as outmoded as the eight - track tape, legendary semiconductor guru Nick Holonyak and his colleagues have recast it — literally — in a whole new light.
To build their transistor, Jan Hendrik Schn of Bell Laboratories in New Jersey and colleagues, who describe their findings in the current issue of the journal Nature, allowed many thousands of organic molecules to assemble themselves onto a gold film like bristles on a brush.
«Biologically powered chip created: System combines biological ion channels with solid - state transistors to create a new kind of electronics.»
Based on graphene field - effect transistors, the flexible devices open up new possibilities for the development of functional implants and interfaces.
Addressing these challenges, Jiangwei Liu, from Japan's National Institute for Materials Sciences, and his colleagues describe new work developing diamond - based transistors this week in the journal Applied Physics Letters, from AIP Publishing.
Eight days earlier, on 23 December 1947, John Bardeen and Walter Brattain, two of Shockley's colleagues at Bell Laboratories in Murray Hill, New Jersey, had unveiled a device that would change the world: the first transistor.
This development is promising for new electronic devices that interact with light, such as new kinds of transistors, superconducting switches and gas sensors.
There is a need for new material systems that can be used to make field - effect transistors sensors that work at high temperatures.
New types of solar cells and flexible transistors are also in the works, as well as pressure and temperature sensors that could be built into electronic skin for robotic or bionic applications.
Jan Henrik Schön, Bell Labs History: In 2001 he announced that he had produced a molecular - scale transistor, a new type of electronics that would transform the industry.
The device used a new process to make this world record - setting organic transistor, paving the way for a new generation of cheap, transparent electronic devices.
«Engineers make world's fastest organic transistor, herald new generation of see - through electronics.»
The first is a new technology for creating transistors, those tiny gates that switch electricity on and off to create digital zeroes and ones.
Such phase transitions should allow us to develop entirely new switching elements for next - generation electronics that are faster and potentially more energy efficient than present - day transistors.
The new study confirms that, in terms of size, carbon - nanotube transistors can beat out silicon — and that's no small feat.
Funakubo's team are hopeful that their new thin film ferroelectric material will have applications in novel random - access memory and transistors, along with quantum computing.
BENDING something might break it, or give it new life: graphene grown with bends in it has a quality it needs to act as a transistor.
Testing and analysis of this new combination reveal that it works as an effective transistor, even as it is repeatedly stretched up to 100 % of its length.
Producing hafnium oxide transistors would require chipmakers to add multiple new steps to the manufacturing process — in part because the electrodes must be fashioned from metal, instead of from a form of silicon, to remain compatible with the hafnium.
A new study by University of Illinois engineers found that in the transistor laser, a device for next - generation high - speed computing, the light and electrons spur one another on to faster switching speeds than any devices available.
About a dozen possible next - generation candidates exist, including tunnel FETs (field effect transistors, in which the output current is controlled by a variable electric field), carbon nanotubes, superconductors and fundamentally new approaches, such as quantum computing and brain - inspired computing.
Intel's new Tri-Gate transistors, first demonstrated last May, replace those flat channels with thin, rectangular silicon pillars, or «fins,» that rise above the surface of the chip.
The new method should reduce the time nano manufacturing firms spend in trial - and - error searches for materials to make electronic devices such as solar cells, organic transistors and organic light - emitting diodes.
Using this new ink, the group created a wrist - band muscle activity sensor by printing an elastic conductor on a sportswear material and combining it with an organic transistor amplifier circuit.
The one - atom - thick carbon sheets could revolutionize the way electronic devices are manufactured and lead to faster transistors, cheaper solar cells, new types of sensors and more efficient bioelectric sensory devices.
By replacing the bulky switches with smaller, cooler - running transistors, Cocconi came up with a new, digital - chip - based inverter package that tipped the scales at a mere 60 pounds.
This could lead to new kinds of amplifiers, transistors or data storage devices.
In a collaborative international effort, American colleagues have built the first field - effect transistors from the new material.
The result is a hundredfold increase of the spin signal, big enough to be used in real life applications, such as new spin transistors and spin - based logic.
As a result, the team designed a new type of transistor — with the concept published in the journal Applied Physics Letters — that could open new routes for graphene - based high - speed electronic and optoelectronic devices.
This chart from Intel co-founder Gordon Moore's seminal 1965 paper showed the cost of transistors decreased with new manufacturing processes even as the number of transistors on a chip increased.
Now, in a bid to continue decreasing transistor size while increasing computation and energy efficiency, chip - maker Intel has partnered with researchers from the U.S. Department of Energy's Lawrence Berkeley National Lab (Berkeley Lab) to design an entirely new kind of resist.
Intel's «Ivy Bridge» quad - core chips, the third - generation Core i7 found found in the newest Mac and Windows PCs, has 1.4 billion transistors on a surface area of 160 square millimeters — and there are chips with even more.
«A new class of two - dimensional materials: New kinds of «superlattices» could lead to improvements in electronics, from transistors to LEDs.&raqnew class of two - dimensional materials: New kinds of «superlattices» could lead to improvements in electronics, from transistors to LEDs.&raqNew kinds of «superlattices» could lead to improvements in electronics, from transistors to LEDs.»
Within five years, it could begin powering faster and better transistors, computer chips, and LCD screens, according to researchers who are smitten with this new supermaterial.
UCLA researchers develop a new class of two - dimensional materials: New kinds of «superlattices» could lead to improvements in electronics, from transistors to LEDs March 11th, 2new class of two - dimensional materials: New kinds of «superlattices» could lead to improvements in electronics, from transistors to LEDs March 11th, 2New kinds of «superlattices» could lead to improvements in electronics, from transistors to LEDs March 11th, 2018
An international team of scientists has discovered a new route to ultra-low-power transistors using a graphene - based composite material.
The new structure gives thin - film transistors stability comparable to those made with inorganic materials, allowing them to operate in ambient conditions — even underwater...
In the first, IBM announced a new speed record for an experimental graphene transistor that looks exceptionally promising for processing analog signals.
The new method could yield improved and new classes of electronic and optoelectronic devices, including applications for superfast and ultra-efficient semiconductors for transistors in computers and smart devices, as well as advanced LEDs and lasers.
Here's the lowdown on two of its newest and brightest lights, Pen - ek Ratanaruang, director of Mon - rak Transistor, and Apichatpong Weerasethakul, with his new Blissfully Yours.