Contact Us
Position:Home > News > Industry News >

Nanoparticles can promote better light-emitting diodes

2017-07-24 09:20 View:
In an advance that could boost the efficiency of LED lighting by 50 percent and even pave the way for invisibility cloaking devices, a team of University of Michigan researchers has developed a new technique that peppers metallic nanoparticles into semiconductors.
It's the first technique that can inexpensively grow metal nanoparticles both on and below the surface of semiconductors. The process adds virtually no cost during manufacturing and its improved efficiency could allow manufacturers to use fewer semiconductors in finished products, making them less expensive.
The metal nanoparticles can increase the efficiency of LEDs in several ways. They can act as tiny antennas that alter and redirect the electricity running through the semiconductor, turning more of it into light. They can also help reflect light out of the device, preventing it from being trapped inside and wasted.
The process can be used with the gallium nitride that's used in LED lighting and can also boost efficiency in other semiconductor products, including solar cells. It's detailed in a study published in the Journal of Applied Physics.
"This is a seamless addition to the manufacturing process, and that's what makes it so exciting," said Rachel Goldman, U-M professor of materials science and engineering, and physics. "The ability to make 3-D structures with these nanoparticles throughout is going to open a lot of possibilities."
 Nanoparticles could spur better LEDs, invisibility cloaks
Gallium arsenide nanoparticles forming on the surface of a semiconductor.Courtesy of Rachel S. Goldman, University of Michiganprofessor of materials science and engineering
The key innovation
The idea of adding nanoparticles to increase LED efficiency is not new. But previous efforts to incorporate them have been impractical for large-scale manufacturing. They focused on pricey metals like silver, gold and platinum. In addition, the size and spacing of the particles must be very precise; this required additional and expensive manufacturing steps. Furthermore, there was no cost-effective way to incorporate particles below the surface.
Goldman's team discovered a simpler way that integrates easily with the molecular beam epitaxy process used to make semiconductors. Molecular beam epitaxy sprays multiple layers of metallic elements onto a wafer. This creates exactly the right conductive properties for a given purpose.
The U-M researchers applied an ion beam between these layers—a step that pushes metal out of the semiconductor wafer and onto the surface. The metal forms nanoscale particles that serve the same purpose as the pricey gold and platinum flecks in earlier research. Their size and placement can be precisely controlled by varying the angle and intensity of the ion beam. And applying the ion beam over and over between each layer creates a semiconductor with the nanoparticles interspersed throughout.
 
 
"If you carefully tailor the size and spacing of nanoparticles and how deeply they're embedded, you can find a sweet spot that enhances light emissions," said Myungkoo Kang, a former graduate student in Goldman's lab and first author on the study. "This process gives us a much simpler and less expensive way to do that."
Researchers have known for years that metallic particles can collect on the surface of semiconductors during manufacturing. But they were always considered a nuisance, something that happened when the mix of elements was incorrect or the timing was off.
 Nanoparticles could spur better LEDs, invisibility cloaks
The main growth chamber of the molecular epitaxy beam apparatus used to make the nanoparticle-infused gallium nitride semiconductors. The semiconductors could boost LED efficiency by up to 50 percent, and even lead to invisibility cloaking devices. Credit: Photo by Joseph Xu, Michigan Engineering Communications & Marketing
"From the very early days of semiconductor manufacturing, the goal was always to spray a smooth layer of elements onto the surface. If the elements formed particles instead, it was considered a mistake," Goldman said. "But we realized that those 'mistakes' are very similar to the particles that manufacturers have been trying so hard to incorporate into LEDs. So we figured out a way to make lemonade out of lemons."
Toward invisibility cloaks
Because the technique allows precise control over the nanoparticle distribution, the researchers say it may one day be useful for cloaks that render objects partially invisible by inducing a phenomenon known as "reverse refraction."
Reverse refraction bends light waves backwards in a way that doesn't occur in nature, potentially directing them around an object or away from the eye. The researchers believe that by carefully sizing and spacing an array of nanoparticles, they may be able to induce and control reverse refraction in specific wavelengths of light.
"For invisibility cloaking, we need to both transmit and manipulate light in very precise ways, and that's very difficult today," Goldman said. "We believe that this process could give us the level of control we need to make it work."
The team is now working to adapt the ion beam process to the specific materials used in LEDs—they estimate that the higher-efficiency lighting devices could be ready for market within the next five years, with invisibility cloaking and other applications coming further in the future.
The study is titled "Formation of embedded plasmonic Ga nanoparticle arrays and their influence on GaAs photoluminescence."
Bio-magnetic beads, Sulfydryl modified
Huitong TM Samples mixed instrument|100%
Magnetic beads method glue recovery kit
Nano cerium oxide powder (CeO2 powder)
Nano Tungsten disulfide powder
Tungsten carbide nano powder (99.9% )
Nano Dy2O3 powder
Nano Cobalt powder (Nano Co powder)
Nano Aluminum oxide powder (Nano Al2O3Powder)
Nano Boron carbide powder (Nano CB4 Powder)
Tantalum carbide powder (nano particle size)
Nano titanium(Ti) Powder
Nano Titanium carbide powder (Nano TiC powder)
High purity Nano Manganese(Mn) powder
Nano SiO2 Powder
Nano Fe2O3 powder (99.9%)
Nano Aluminium Nitride powder (Nano AlN powder)
Nano Tungsten disulfide powder (Nano WS2 powder)
chitosan beads
aldehyde beads | aldehyde modified microsphere
Bio-magnetic beads, Carboxylic modified
Bio-magnetic beads, Amino modified
Bio-magnetic beads, Silicic modified
Magnetic fluid
Nano SiO2 dispersing agent
Nano Co dispersing agent
Nano oxidation zinc dispersing agent
Nano silver Soil antibacterial agent
Polyurethane release agents
Nano silver Powder (Nano Ag powder purity 99.99)
Thiadiazole-octyl mercaptan condensates(CAS No: 13539-13-4)
Dimercapto-thiadiazole dimerBis-DMTD
DMTD(2,5- dimercapto-1,3,4- thiadiazole)
Methylene bis (dibutyl dithio carbamate)
MoDTC Complexes (Solid MoDTC)
MoDTP (Liquid Molybdenum Dithiophosphate)
Nano Co dispersing agent
Water-based magnesium stearate
Polyurethane Internal Release Agent
Water-based zinc stearate (Vinyl lubricant )
Stearic acid amides emulsion for themal paper
Water-Based Calcium stearate
Coated with abrasive coating slurry