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New Spintronics Material for Next-Gen Chips

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LOS ANGELES, April 8, 2010 — As the electronics industry works toward developing smaller and more compact devices, the need to create new types of scaled-down semiconductors that are more efficient and use less power has become essential.

Researchers from UCLA's Henry Samueli School of Engineering and Applied Science have created a new material incorporating spintronics that could help usher in the next generation of smaller, more affordable and more power-efficient devices.

While conventional complementary metal-oxide semiconductors (CMOS), a technology used today in all types of electronics, rely on electrons' charge to power devices, the emerging field of spintronics exploits another aspect of electrons — their spin, which could be manipulated by electric and magnetic fields.

"With the use of nanoscaled magnetic materials, spintronics or electronic devices, when switched off, will not have a stand-by power dissipation problem. With this advantage, devices with much lower power consumption, known as non-volatile electronics, can become a reality," said the study's corresponding author, Kang L. Wang, Raytheon Professor of Electrical Engineering at UCLA Engineering, whose team carried out the research. "Our approach provides a possible solution to address the critical challenges facing today's microelectronics industry and sheds light on the future of spintronics."

"We've built a new class of material with magnetic properties in a dilute magnetic semiconductor (DMS) system," said Faxian Xiu, a UCLA senior researcher and lead author of the study. "Traditionally, it's been really difficult to enhance the ferromagnetism of this material above room temperature. However in our work, by using a type of quantum structure, we've been able to push the ferromagnetism above room temperature."

Ferromagnetism is the phenomenon by which certain materials form permanent magnets. In the past, the control of magnetic properties has been accomplished by applying an electric current. For example, passing an electric current will generate magnetic fields. Unfortunately, using electric currents poses significant challenges for reducing power consumption and for device miniaturization.

"You can think of a transformer, which passes a current to generate a magnetic field. This will have huge power dissipation (heat)," Xiu said. "In our study, we tried to modulate the magnetic properties of DMS without passing the current."

Ferromagnetic coupling in DMS systems, the researchers say, could lead to a new breed of magneto-electronic devices that alleviate the problems related to electric currents. The electric field–controlled ferromagnetism in this study shows that without passing an electric current, electronic devices could be operated and functioning based on the collective spin behavior of the carriers. This holds great promise for building next-generation nanoscaled integrated chips with much lower power consumption.

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To achieve the ferromagnetic properties, Kang's group grew germanium dots on a silicon p-type substrate, creating quantum dots on top of the substrate. Silicon and germanium are ideal candidates because of their excellent compatibility and ability to be incorporated within conventional CMOS technology. The quantum dots, which are themselves semiconductors, would then be utilized in building new devices.

"To demonstrate possible applications of these fantastic quantum dots, we fabricated metal-oxide semiconductor devices and used these dots as the channel layer. By applying an electric field, we are able to control the hole concentration inside the dots and thus modulate their ferromagnetism," Xiu said.

"This finding is significant in the sense that it opens up a completely new paradigm for next-generation microelectronics, which takes advantage of the spin properties of carriers, in addition to the existing charge transport as envisaged in the conventional CMOS technology."

The key is to be able to use this material at room temperature.

"The material is not very useful if it doesn't work at room temperature," Wang said. "We want to be able to use it anywhere. In this work, we've achieved success on electric field–controlled ferromagnetism at 100 degrees Kelvin and are moving towards room temperature. We feel strongly that we'll be able to accomplish this. Once we've achieved room-temperature controllability, we'll be able to start building real devices to demonstrate its viability in non-volatile electronic devices."

Study collaborators Jin Zou, professor of material engineering, and postdoctoral fellow Yong Wang, both from the University of Queensland, Australia, also contributed significantly to this work.

The study was funded by the Center for Functional Engineered Nano Architectronics (FENA), the Western Institute of Nanoelectronics (WIN) at UCLA Engineering, and in part by Intel Corp. and the Australian government.

For more information, visit:  www.ucla.edu 

Published: April 2010
Glossary
electronics
That branch of science involved in the study and utilization of the motion, emissions and behaviors of currents of electrical energy flowing through gases, vacuums, semiconductors and conductors, not to be confused with electrics, which deals primarily with the conduction of large currents of electricity through metals.
ferromagnetism
The properties of certain materials that cause them to have relative permeabilities that exceed unity. This permeability permits the materials to exhibit hysteresis.
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
quantum dots
A quantum dot is a nanoscale semiconductor structure, typically composed of materials like cadmium selenide or indium arsenide, that exhibits unique quantum mechanical properties. These properties arise from the confinement of electrons within the dot, leading to discrete energy levels, or "quantization" of energy, similar to the behavior of individual atoms or molecules. Quantum dots have a size on the order of a few nanometers and can emit or absorb photons (light) with precise wavelengths,...
Asia-PacificAustraliaCaliforniaCMOSDMS systemelectronicsFaxian XiuFENAferromagnetismintegrated chipsIntelJin ZouKang L. Wangmagnetic fieldsmetal-oxide semiconductorsmicroelectronicsnanonanoscale magnetic materialsquantum dotsquantum structureResearch & Technologysemiconductorssilicon p-type substratespintronicsUCLAYong Wang

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