With new technology getting smaller and smaller, requiring lower power, University of Cincinnati physics research points to new robust electronic technologies using quantum nanowire structures. The semiconductor nanowires may lead to advances in sensitive electronic technology including heat detecting optical infrared sensors and biomedical testing, all of which can fit inside small electrical devices.

Supported by multiple National Science Foundation grants, the UC research team is working with a collaborative team of physicists, electronic materials engineers and doctoral students from around the world - all to perfect the growth and development of crystalline nanowires that could form the backbone of new nanotechnologies.

But to fully apply this technology to modern devices, UC researchers are first looking closely - on a fundamental level - at how energy is distributed and measured along thin-strand nanowires so small that thousands of them could theoretically fit inside a human hair.

"Now that we know the technology can be developed, we need to understand exactly how the electrical processes work inside the nanowire cores," say Howard Jackson and Leigh Smith, professors of physics at the University of Cincinnati. "After finally perfecting a standardized process for growing and developing crystalline nanowire fibers with our partners at the Australian National University in Canberra, we have been able to take it one step further.

"Using a combination of materials like indium gallium arsenide and indium phosphide, we can develop thin nanowire cores with protective outer shells."

It turns out that these unique nanowire materials have unusually large spin orbit interactions, which the researchers find can conduct electricity really well and may allow the use of spin to enable new computing paradigms.

Jackson and Smith are presenting these findings at the American Physical Society Conference, in Baltimore, March 16, titled, "Exploring Dynamics and Band Structure in Mid Infrared GaAsSb and GaAsSb/InP Nanowire Heterostructures."

Small Yet Mighty
The researchers claim the secret to the success of this multi-collaborative effort is in the combination of materials used to create the nanowires. Initially grown at the Australian National University in Canberra, the nanowires are sprouted from a combination of beads of molten gold scattered across a particular surface.

As the process is heated inside a chamber using indium gallium arsenide gases, long microscopically thin core fibers sprout up from between the controlled surface environment.

Other material combinations are then introduced to form an outer shell acting as a sheath around each core, resulting in quantum nanowire semiconducting heterostructures all uniform in size, shape and behavior.

After the fibers are shipped across the globe to Cincinnati, Jackson, Smith and their team of doctoral students are then able to use sophisticated equipment to measure the electrical and photovoltaic potentials of each fiber along its surface.

In earlier research, the collaborative team found extrinsic and intrinsic problems when the fiber cores did not have the outer sheath-like shells.

"If we don't have this outer sheath, the nanowires have a very short energy lifetime, says Jackson. "When we surround the core with this sheath, the energy lifetime can go up by an order or two orders of magnitude."

And while gallium arsenide alone is a very common semiconductor, its energy gap is large and in the visible range, which absorbs light. To achieve success in detecting optical heat or infrared, the team says using indium gallium arsenide fibers have smaller energy gaps that can be used successfully in optical detector devices. doctoral student in physics lab with laser lights

"The goal for one of our research equipment grants is to work with the local L3 Cincinnati Electronics Company, which makes infrared (small gap) detectors for night-vision imaging for military applications," says Smith. "Future direct applications for this type of technology also include medical devices that detect body heat, as well as remote sensors installed in iphones that can be used for environmental purposes that detect and measure heat loss in houses."

The researchers say this new nanowire technology is unique because it can turn different wavelengths of light into an electrical signal, and in this case it means turning an infrared light into an electric signal that can be measured.

Smith explains that with the geometry of the nanowires you can have a long axis running the length of the wire, which gives you lots of possibilities for absorption as the light comes down, but then you also have this very small diameter.

"When contacts are interspersed along either side, essentially then the electrons in the holes don't have to travel very far before they are collected," says Smith. "So in principle it can become a more effective detector as well as a more effective solar cell."

Small Dimension Nanowires
"When you get to very small dimensions in nanowires that are small in diameter, but are a few microns long, those properties then change and can show quantum properties and become almost one-dimensional," says Jackson. "The physics then changes as you change those sizes."

Jackson and Smith found that the nanowire's ultra-thin outer shells functioned best at widths of four to eight nanometers, which is 25,00 and 12,500 times smaller respectively, than the diameter of a human hair.

When looking at the overarching benefits of working with microscopic nanostructures the researchers see tremendous potential for its ability to pack much more high-energy efficiency into small devices with finite space. It's getting closer to a win-win for everyone, they're saying, especially when this research enters the next stage, bringing it closer to functioning inside electronic and optical sensor devices.

"Our fundamental investigation is still a step away from a direct optical device application," says Jackson. "But you can clearly see over time that this collaborative research has made an impact."

Additional contributors to the research are UC physics doctoral students, Nadeeka Wickramasuriya, Yuda Wang and Samuel Linser. Collaborators from the Australian National University in Canberra, Department of Electronic Materials Engineering, are Xiaoming Yuan, Philippe Caroff, Hoe Tan and Chennupati Jagadish.