Skip to main content

Nanoworld in Color: Tiny Lens Arrays Can Record or Project Sharp Images


Microscopically small nanostructured arrays of lenses that can record or project amazingly sharp images in brilliant colors Lights off -- projector on. Lecture theaters, conference halls and seminar rooms currently have to be darkened if the speaker wants to project a presentation on screen. Unfortunately, the attention of the listeners goes off with the lights, and tiredness takes over. A new technique promises to remedy this situation. The projectors of the futur will not only be small and easy to use but also shine so brightly that the images appear sharp and clear, even in a sun-filled room.

The image illuminating the wall of the Fraunhofer exhibition stand at nano tech 2011 will be produced by a luminous cube. The prototype of the new projector consists of an optical system just eleven millimeters square and three millimeters thick through which a powerful LED lamp shines. The images are amazingly sharp, the colors brilliant -- all thanks to micro and nanotechnology. "The special thing about the new projection technology is that the image is already integrated in the microoptics. The pixels measuring just a hundred nanometers or so are stored in a chromium layer under the lens array. Such a microarray has around 250 microlenses, and under each lens there is a microimage. When all of them are projected onto the wall together, a high-quality complete image is produced from an extremely small projector," explains Marcel Sieler, physicist at the Fraunhofer Institute for Applied Optics and Precision Engineering IOF in Jena.

This pocket-sized technology has the potential to replace not only overhead and digital projectors but also cameras. "The commercial prospects for ultra-flat microoptical systems are excellent because they open up numerous new applications -- like minicameras or miniprojectors" enthuses Dr. Michael Popall from the the Fraunhofer Institute for Silicate Research ISC. He adds: "The leap in manufacturing quality achieved in recent months can be compared to the advance in television from the cathode ray tube to HDTV." The IOF scientists have also developed a projector that is not much bigger than a box of matches. It can project presentations, video clips and movies from a cell phone or laptop onto any wall -- at home, in the office or out and about. Ultra-flat cameras that are ideal for area or production monitoring in exposed locations are another application which will be demonstrated in Tokyo.

A special material composition has been developed by researchers at ISC for the manufacture of the microlens arrays used in all these applications. Organic carbon-hydrogen and oxygen compounds are enveloped in an inorganic matrix of silicon oxide or titanium oxide. This prevents the embedded plastics from changing chemically over the course of time. Such ORMOCER®s are insensitive to mechanical and thermal loadings. Incidentally, the formula for stabilizing sensitive compounds is very old: The ancient Mayas mixed their natural indigo dye, which normally bleaches quickly in the sun, with a clay mineral to render it fast. As a result, the blue dye they used to decorate the walls of their houses and temples lasted for more than a thousand years.

The method employed by the Mayas was very effective but rather crude compared with modern techniques. "Today we can control the chemical bonding of the inorganic and organic substances with nanometer precision," states Popall. "Development of the material, however, is only one part of the puzzle. The shaping process and the technology needed to control it play a crucial role in lens manufacture. It was only through close cooperation between chemists and physicists at Fraunhofer that we succeeded in producing the arrays, substrates and components needed for extremely flat, high-quality optics." The resolution attainable is now almost as high as that of high-quality glass optics -- but using significantly less material and space. What's more, the new material can be mass produced, which keeps the costs much lower.

Comments

Popular posts from this blog

Evolution Of Computer Virus [infographic]

4 Free Apps For Discovering Great Content On the Go

1. StumbleUpon The granddaddy of discovering random cool stuff online, StumbleUpon will celebrate its 10th anniversary later this year — but its mobile app is less than a year old. On the web, its eight million users have spent the last decade recommending (or disliking) millions of webpages with a thumbs up / thumbs down system on a specially installed browser bar. The StumbleUpon engine then passes on recommendations from users whose interests seem similar to yours. Hit the Stumble button and you’ll get a random page that the engine thinks you’ll like. The more you like or dislike its recommendations, the more these random pages will surprise and delight. Device : iPhone , iPad , Android 2. iReddit Reddit is a self-described social news website where users vote for their favorite stories, pictures or posts from other users, then argue vehemently over their meaning in the comments section. In recent years, it has gained readers as its competitor Digg has lost them.

‘Wireless’ humans could backbone new mobile networks

People could form the backbone of powerful new mobile internet networks by carrying wearable sensors. The sensors could create new ultra high bandwidth mobile internet infrastructures and reduce the density of mobile phone base stations.Engineers from Queen’s Institute of Electronics, Communications and Information Technology are working on a new project based on the rapidly developing science of body-centric communications.Social benefits could include vast improvements in mobile gaming and remote healthcare, along with new precision monitoring of athletes and real-time tactical training in team sports, an institute release said.The researchers are investigating how small sensors carried by members of the public, in items such as next generation smartphones, could communicate with each other to create potentially vast body-to-body networks.The new sensors would interact to transmit data, providing ‘anytime, anywhere’ mobile network connectivity.Simon Cotton from the i