«Light transistor:
Efficient transistor for light could lead to optical computers.»
This produces
an efficient transistor for light that can be miniaturised and used to build optical computers.
The tuning of this property can sequentially create and destroy the hourglass fermions, suggesting a range of potential applications such as
efficient transistor switching.
High - power gallium nitride - based high electron mobility transistors (HEMTs) are appealing in this regard because they have the potential to replace bulkier, less
efficient transistors, and are also more tolerant of the harsh radiation environment of space.
Materials that flip from insulator to conductor could make more energy -
efficient transistors, although the metals are not yet close to competing with silicon
For several years, a team of researchers at The University of Texas at Dallas has investigated various materials in search of those whose electrical properties might make them suitable for small, energy -
efficient transistors to power next - generation electronic devices.
This behavior suggests a range of potential applications, from low - energy devices to
efficient transistors.
The reason it's better than SD 810 is that 7420 uses smaller and
efficient transistors.
Not exact matches
They range from highly
efficient detectors for optical and wireless communications to
transistors operating at very high speeds.
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 researchers plan to continue to develop the
transistor laser and explore its unique physics while also forming industry partnerships to commercialize the technology for energy -
efficient big data transfer.
Although circuits made with single - walled carbon nanotube are expected to be more energy -
efficient than silicon ones in future, their drawbacks in field - effect
transistors, such as high power dissipation and less stability, currently limit their applications in printed electronics, according to Dodabalapur.
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.
«The resulting materials could be useful for making faster
transistors that consume less power, or for creating
efficient light - emitting devices,» Duan said.
These advances could include more energy -
efficient field effect
transistors and photocatalysts that use visible light from the sun.
See also: Intel Announces Revolutionary 3D
Transistors, 50 % + More Energy
Efficient Than Previous Generation
Intel Announces Revolutionary 3D
Transistors, 50 % + More Energy
Efficient Than Previous Generation
Nehalem's PCU, 1 Million
Transistors Intel has announced at the Intel Developer Forum (IDF) that i7 a.k.a. Nehalem, its next generation CPU, will include a Power Control Unti (PCU) dedicated to making the chip more
efficient.
The processor is more
efficient than current 14nm processor as it includes more
transistors in a similar surface area on the chipset.
In the LCD space, the backlight has to pass through filters, which aren't 100 percent
efficient, and the pixel controlling
transistor also takes up a notable amount of space that blocks some light in every sub-pixel.
That means the tiny
transistors within each chip are ever so slightly closer together, making it more powerful and more power -
efficient.
It's faster and more power
efficient than its predecessor, thanks to a new 10 - nanometer manufacturing process that places all of its tiny
transistors closer together.
14nm fin field effect
transistors reduce power consumption by up to 35 %, making this smartphone highly
efficient at conserving energy.
This also means the
transistor switching performance is much more
efficient and power leakage decreases.