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6 Posts tagged with the oled tag
Cabe Atwell
0

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QLEDs producing 168,000 candelas/square meter. (via Jeonghun Kwak & American Chemical Society)

 

Within time every product meets its predecessor. While quantum dot LEDs (QLEDs) are nothing new, they have taken the back burner to their organic counter parts (OLEDs) for quite some time. Quantum dots are small crystal shaped particles only a few nanometers wide, that behave similarly to semiconductors. They are readily excited by light and their small size and composition give them extraordinary fluorescent optical properties, which are easily adjusted by changing the size or physical composition. Recently, research teams at Seoul University, South Korea, have found a way to improve the color, efficiency, and costs to produce QLEDs.

 

 

Seoul National University's Changhee Lee stated that QLEDs suffer from problems due to a large energy barrier between the injected holes from the anode and the transport layer holes. The result is low quantum efficiency, and in turn, low maximum brightness, leakage current, and device degradation. His goal was to correct these issues.

 

 

The researchers compensated for this setback by using the usual anode, indium tin oxide, as the electron transport layer, to create a more reliable conductive, efficient product. The new composition of the QLEDs give a greater performance that can be competitive towards the OLEDs.

 

 

However, the QLEDs at this time have a much shorter lifespan than OLEDs. They do possess some qualities that make them worth researching further into though. They have a shorter bandwidth which can produce deeper colors and higher contrast ratios. In addition, the ease of adjusting fluorescent properties of quantum dots also make them an appealing product along with their low cost to manufacture, they can be printed easily on a large-area substrate. A breakthrough in QLEDs may soon pave the way for next generation electronic displays and solid-state lighting applications.

 

Cabe

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141 Views 0 Comments Permalink Tags: design, led, lighting, industry, innovation, prototyping, university, research, oled, on_campus, cabeatwell, qled
Cabe Atwell
0

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Engineering On Friday Down on the organic-LED farm by Cabe Atwell.jpg

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We are not  talking about food here, it is the "organic electronics" that are  finding their way into our electrical lives. It is not just a label, but  a growing industry with potential to bring us new-age efficiency and  creativity. Organic electronics do not grow from the earth. Instead, the  components involve a lot of chemistry, generally stemming from carbon  based compounds, and how it bonds with oxygen and hydrogen to create  unique substances like conductive polymers. Carbon-based (Organic)  molecules are not generally known for their conductivity, but rather  their properties such as low cost to produce, flexibility, and light  weight.


Flexible_display.jpgFlexibleOrganicElectronicsdisplay.jpg

Prototype flixible organic displays, showing the potential of organically derived electronics.

 

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"Melanin" switch, an active organic polymer voltage-controlled device (circa 1974 in the Smithsonian collection)

 

Organic compounds used in electronics dates back to 1862. Henry Letheby made a partly conductive material, polyaniline, by anodic oxidation of aniline in sulfuric acid. The 1950s and 60s brought more experimentation in conductive compounds. In 1973, the journal Science reported that a organic-polymer electrical device was possible. Flash forward to the year 2000,a group of researchers were awarded the Nobel Prize in Chemistry for the "discovery and development" of conductive polymers. It seems the team may have been riding on the shoulders of generations that proceeded. Their compound was an oxidized and iodine-doped polyacetylene.

 

 

Currently, organic materials are being used to create electronics such as LEDs, semiconductors, transistors, and solar cell products. OLEDs, organic light emitting diodes, consist of thin layers of organic compounds placed between two electrodes. OLEDs remove the need for backlighting, achieving deeper colors and higher contrast ratios. Many new televisions, monitors, and smart phone displays currently use them. Additionally, semiconductors created from organic materials create a more energy efficient product. A combination of p-type positive charge carriers or holes and n-type negative charge carriers or electrons transmit a current only when their bits are flipping. Organic semiconductors also possess similar characteristics as non organic semiconductors which allow for doping by an oxidization-reduction process.

 

 

The future of organic electronics will lead to many innovations to sustainably meet consumer demands. Affordable costs will lead to the development of everyday products with smart functionality. The more immediate applications we may see include photovoltaics (solar cells), radio frequency identification tags (RFID), and printed electronics. One thing we can count on is organic technologies bringing people together in hopes to extend the planet's resources while making a profit.

 

 

In order to progress in this field chemists, electrical engineers, material engineers, and others within the electrical design and fabrication communities have to work together.

 

Cabe

http://twitter.com/Cabe_e14

 

See more Engineering On Friday comics in the Engineering Life group.

186 Views 0 Comments Permalink Tags: design, industry, innovation, measurement, sensor, prototyping, university, research, energy, solar, oled, photovoltaic, organic, amoled, on_campus, cabeatwell, organic_electronics, conductive_polymers
Cabe Atwell
4

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Solar Decathlon grounds (via DOE)

 

An innovation-stirring biennial competition is travelling to the west coast in 2013 for the first time in its decade-long existence. The Solar Decathlon will be in California this year for the 20+ college teams participating from all parts of the globe. (Normally held in Washington DC) Competition organizers hope to engage a new audience with innovations of technology and design from the 20 U.S. universities competing to make the best solar powered home.

 

The Decathlon put teams of students from all over the country against each other to compete in 10 categories. Using solar energy to power the home is only part of the challenge. The houses must be functionally and cost effective as well as incorporate a modern design. Solar technology progress is made yearly. Increases in efficiency, innovative applications, and the use of organic materials will make the biennial competition exciting.

 

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From transparent to a light source, the OLED solar cell (via Phillips)


One example of a possible contender in the event comes in the form of solar cells and light bulbs, combined. Lumiblade organic LEDs (OLEDs) are emerging technologies being developed by Philips and the chemical company BASF. These light sources produce light by running a current through a thin layer of organic semiconductor material. The collaboration of Philips and BASF has produced Lumiblade OLEDs of just 1.8 mm thickness, with materials and dyes that become transparent when light is not being emitted. Furthermore, this OLED can be put between solar cells to capture solar energy. The applications for transparent panels that capture solar energy and emit light can be used through out the modern solar home.

 

Dr. Felix Görth, OLED and Photovoltaics head at BASF, described the tech best, " This combination allows the driver to enjoy a unique open-space feeling while it generates electricity during the day and pleasantly suffuses the interior with the warm light of the transparent, highly efficient OLEDs at night."

 

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Solar OLED (via Phillips)

 

Innovations similar to the Lumiblade will surely be showcased in the 2013 Solar Decathlon. The Department of Energy’s Secretary, Steven Chu, explained what we can expect, “The Solar Decathlon will unleash the ingenuity, creativity and drive from these talented students to demonstrate new ideas for how families and businesses can reduce energy use and save money with clean energy products and efficient building design.”

 

Cabe

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193 Views 4 Comments Permalink Tags: embedded, industry, innovation, prototyping, university, research, energy, hmi, solar, oled, alternative_energy, phillips, doe, on_campus, cabeatwell, solar_decathlon, solar_oled
Cabe Atwell
0

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Printed circuit on flexible Kapton (via UCLA)

 

The big brains at the California NanoSystems Institute (CNSI) started the "technology incubator" two years ago for  bringing new development at the University of Southern California (UCLA) to the commercial market. They are poised to release one that is sure to have a major influence on countless electrical engineers, a low-cost ink-jet carbon-nanotube based circuit printer.

 

The startup company Aneeve Nanotechnologies (AN) from within CNSI will be the driving force behind the new offering. Co-founder, and adjunct professor of materials science at UCLA, Kos Galatsis explained the general system, "This is the first practical demonstration of carbon nanotube–based printed circuits for display backplane applications... We have demonstrated carbon nanotubes' viable candidacy as a competing technology alongside amorphous silicon and metal-oxide semiconductor solution as a low-cost and scalable backplane option."

 

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OLED display control circuit made by Aneeve Nanotechnologies (via UCLA)

 

The team at AN are already boasting the major advantages circuits made with their printer. Since they are using carbon-nanotubes, high electron mobility and a large band-gap (on-off ratio) are the de-facto pluses. Eliminating the need for expensive vacuum equipment and traditional silicon printing machines comes without question. A nano-based ink solution and a new cleaning process lets the end user have a scalable "roll-to-roll" printing of their devices. (Perhaps outsourcing will stop being an issue for the competitive electronics market.)

 

Release date, price, and what comes along such a process was not covered. The team at AN are banking on the quick uptake of their technology; we will have answers very soon. I like the idea of producing circuits on Kapton in-house. The flexibility of the substrate gives a lot of possibilities for circuit housing and shape. Too bad we cannot print the components as well.

 

Cabe

http://twitter.com/Cabe_e14

 

More printed technology:

Grow electronics by the molecule

Pen & ink for drawing conductive circuits

Inkjet printed solar panels

Bones made with a 3D printer

401 Views 0 Comments Permalink Tags: design, innovation, manufacture, sensor, prototyping, university, oled, fabrication, ucla, transistor, printing, on_campus, cabeatwell, circuit_printing, ink_jet_printing, aneevenanotechnologies, inkjet_circuit
Eavesdropper
2

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SA Photonics Have released their High Resolution Night Vision System (HRNVS) to replace the decades old technology being used today. Former night vision systems gave airforce pilots a total field of view of 40 degrees, horizontally. SA Photonics HRNVS over doubles that to 82.5 degrees. 4 individual Intevac Model 11 EBAPS digital night vision cameras make up the system, capturing 1600 x 1200 pixels per. High speed digital image processing comes via Rockwell Collins Display Systems "Microcore" platform. The HRNVS also topples various other common issues with night-vision. The Halo Effect is completely reduced using proprietary technology. Each eyepiece of the HRNVS is a seamless panoramic display, that can be individually stowed. Digital image enhancement of the images is also an option. The user views through two eMagin SXGA (1280 x 1024) displays, boasting almost 4 megapixels per eye. The HRNVS shows a panoramic view of 82.5 degrees using binocular overlap. Each eye piece shares about 27.5 degrees of view.

 

SA Photonics concludes their introduction with future predictions. Wait a little while longer and get the 100 degree field of view with color displays.

 

Eavesdropper

 

pic via SA Photonics

682 Views 2 Comments Permalink Tags: innovation, military, defense, research, optics, oled, eavesdropper:dit, dit, nightvision
Eavesdropper
1

OLED Mikrodisplay mit Eyetracking Funktion_Presse.jpgoled-microdisplay-hmd.jpg

 

Company Fraunhofer IPMS brings a wearable OLED screen that can sense where the user in looking. The Head-Mounted Display, or HMD, is a monochrome OLED screen that the company has labeled the first bidirectional microdisplay. Inside the active matrix OLED screen are integrated photodetectors that allow the system to detect where the eye is looking. Since this display is being promoted as a Augmented Reality (AR) device, the real world can be seen through the HMD. Fraunhofer states that actions could be sensed through the user's "Gaze," as in holding one's eye on a target to activate it. They also said joggers could watch movies while they are out, which is not a good idea on a busy street. But still, I would not mind retaining the option to do so some day.

 

 

Note: The HMD is monochrome. The second picture of a color screen is showing off the size of Fraunhofer's screens.                                             


 

Eavesdropper



pics via Fraunhofer IPMS

653 Views 1 Comments Permalink Tags: hmi, oled, movies, augmented_reality, eavesdropper:dit, dit, hmd, photodetector