The Flash of the Tech World: A Sensor That Blinks Faster Than a Superhero
A futuristic glimpse into the ultra-fast world of multispectral sensing.
Imagine you are trying to win a staring contest against a beam of light. Spoiler alert: you’re going to lose. But while most of us are stuck in the slow lane of biology, scientists at Duke University have been busy building a speed demon that would make even the fastest superhero jealous. They have cooked up a brand-new, ultrathin photodetector that doesn’t just see the world—it captures it at a pace that is frankly hard to wrap our human brains around. This little gadget is the fastest "pyroelectric" detector ever created, and it’s about to change how we see everything from our doctor’s office to the furthest reaches of the galaxy.
To understand how cool this is, we first have to talk about speed. Most of us think a "blink of an eye" is fast. In the world of high-tech sensors, a blink is basically an eternity. This new detector can generate a signal in just 125 picoseconds. How fast is a picosecond? Well, if you were to divide one second into a trillion pieces, a picosecond is just one of those tiny slices. It’s so fast that in the time it takes for this sensor to react, a beam of light has only traveled about an inch. It’s the Usain Bolt of the electronics world, but without the cool yellow jersey.
But wait, there’s more! Not only is it incredibly fast, but it’s also a master of disguise. Most sensors are picky eaters; they only want to "see" certain types of light, like visible light or infrared. This new Duke invention is more like a "see-it-all" buffet. It can sense light across the entire electromagnetic spectrum. We’re talking about everything from the heat radiating off your morning coffee to the ultraviolet rays that give you a sunburn. Because it is so versatile, it’s being called a multispectral powerhouse. It’s like having X-ray vision, heat-vision, and regular vision all packed into a tiny, ultrathin chip.
So, how did they do it? The secret sauce lies in something called a "pyroelectric" material. These materials are like magic sponges that turn heat from light into electricity. Usually, these materials are a bit slow and clunky, but the team at Duke figured out how to make them into a sort of "nano-sandwich." They used tiny cubes of gold to trap the light, squeezing it into a super-thin layer of material. This creates a massive amount of heat in a tiny space very, very quickly. Because the setup is so small—literally thinner than a fraction of a human hair—the heat doesn't have far to travel, allowing the sensor to reset and fire again in the blink of a... well, in 125 picoseconds.
Now, you might be wondering: "That’s great for the scientists, but what does it do for me?" The answer is: plenty! Let's start with the doctor’s office. Imagine a camera that can look at your skin and instantly tell the difference between a healthy mole and something more concerning by looking at light frequencies the human eye can't even dream of. Or, think about a surgeon who can see the exact edge of a tumor in real-time during an operation because their camera is so fast and sensitive it can distinguish between different types of tissue based on how they reflect heat. It’s like giving doctors a pair of super-powered goggles.
The fun doesn’t stop at medicine. Let’s talk about snacks! This technology could be a game-changer for agriculture. Farmers could use drones equipped with these "super-sensors" to fly over massive fields of corn or wheat. The cameras would be able to see exactly which plants are thirsty, which ones are getting sick, and which ones are perfectly happy, all by analyzing the subtle light signatures they give off. It’s like the plants are sending a text message directly to the farmer saying, "Hey, bring me some water over here!" This means more food for the world and less wasted water and fertilizer.
And for those who like to look up at the stars, the sky isn't even the limit. Space-based sensing is a huge deal. When we send satellites into orbit, they are usually weighed down by heavy, specialized cameras that can only see one thing. This ultrathin, lightweight sensor could replace those bulky tools. It could help us find water on distant planets, track weather patterns on Earth with pinpoint accuracy, or even spot asteroids that are trying to sneak up on us. Because it’s so thin and light, it saves room on the rocket for other important stuff—like extra fuel or more science experiments.
In the end, what the team at Duke University has created is more than just a piece of hardware; it’s a new way of interacting with the invisible world. We are surrounded by light that we can’t see and data that we can’t capture because our current technology is too slow or too limited. By breaking the speed record and opening up the entire spectrum, these researchers are handing us the keys to a whole new dimension of discovery. Whether it's saving lives in a hospital, saving crops on a farm, or exploring the cosmos, the future looks incredibly bright—and it’s arriving faster than ever before!
The future isn't just coming; it's already here, and it's traveling at 125 picoseconds per second!
Kabiller Prize recipients Joseph DeSimone (third from left) and Warren Chan (far right) were honored by Northwestern's International Institute for Nanotechnology (IIN) at a private dinner Sept. 29. Also pictured are Northwestern trustee and alumnus David G. Kabiller (far left), whose gift established the prizes; Dr. Eric Neilson (second from left), vice president for medical affairs and Lewis Landsberg Dean at Northwestern University Feinberg School of Medicine; and Chad Mirkin (second from right), IIN director and the George B. Rathmann Professor of Chemistry. "These awards were established not only to recognize the people who are designing the technologies that will drive innovation in nanomedicine, but also to educate and shine a light on the great promises of nanomedicine," said Kabiller, co-founder of AQR Capital Management, a global investment management firm in Greenwich, Connecticut. The Kabiller Prize is among the largest monetary awards in the U.S. for outstanding achievement in the field of nanotechnology and its application to medicine and biology. "The world needs more people like David Kabiller," said Chad A. Mirkin, IIN director and the George B. Rathmann Professor of Chemistry in Northwestern's Weinberg College of Arts and Sciences. "He is dedicated to making a difference and to improving the world through advances in science." DeSimone's innovative research applying nanotechnology to medicine captures the vision of the Kabiller Prize. "Joe is a Renaissance scientist, who has made some of the most important advances in the field of nanomedicine," Mirkin said. One of those advances is PRINT (Particle Replication in Non-wetting Templates) technology, invented by DeSimone in 2005. The technology enables the fabrication of precisely defined, shape-specific nanoparticles for advances in disease treatment and prevention. Nanoparticles made with PRINT technology are being used to develop new cancer treatments, inhalable therapeutics for treating pulmonary diseases, such as cystic fibrosis and asthma, and next-generation vaccines for malaria, pneumonia and dengue. "I'm thrilled and humbled to be recognized with the inaugural Kabiller Prize by such a world-class institution as Northwestern's International Institute for Nanotechnology," DeSimone said. "The PRINT technology invented in my laboratory continues to be developed for many different applications to improve human health, and my students are leading that charge. This recognition is really a testament to their brilliant efforts." DeSimone is the Chancellor's Eminent Professor of Chemistry at the University of North Carolina at Chapel Hill (UNC-Chapel Hill). He also is the William R. Kenan Jr. Distinguished Professor of Chemical Engineering at North Carolina State University and of chemistry at UNC-Chapel Hill. DeSimone founded a startup company based on PRINT called Liquidia Technologies that is building on the promise of vaccine clinical trial results. The company already has spun out two more companies to use PRINT to improve human health, one in ophthalmology and one in oral health. "The invention of PRINT technology and its application toward improvements in human health will shape the field of nanomedicine for decades to come and improve the quality of life for many," said Dr. Eric Neilson, vice president for medical affairs and Lewis Landsberg Dean at Northwestern University Feinberg School of Medicine. The International Institute for Nanotechnology also announced that Warren Chan, a professor at the Institute of Biomaterials and Biomedical Engineering at the University of Toronto, is the recipient of the inaugural Kabiller Young Investigator Award. The award recognizes young researchers who have made a recent groundbreaking discovery with the potential to make a lasting impact in the same arena. Chan and his research group have developed an infectious disease diagnostic device for point-of-care use that can differentiate symptoms. A diagnosis occurs when a patient pricks his or her finger, the sample is amplified, and a disease is detected using a smartphone app. (More than one disease can be detected.) Results for patients infected with HIV and hepatitis B are available in less than one hour at 90 percent accuracy, and the diagnostic device costs less than $100. The device currently is being commercialized and could change the way diseases are diagnosed and tracked globally. "I am very honored to receive the Kabiller Young Investigator Award in Nanoscience and Nanomedicine, and I hope this recognition helps to inspire other young people in the field of nanotechnology," Chan said. DeSimone and Chan were celebrated at a private dinner last night in Chicago. The two will be publicly recognized and present their research Oct. 1 at the 2015 IIN Symposium, which will include talks from other prestigious speakers, including 2014 Nobel Prize in Chemistry winner William E. Moerner.
Quantum dots make it possible to display any color in full brilliance. (Image: Fraunhofer IAP) The landscape is breathtaking. Because it is so real, you forget for a moment that the eagle circling the sky is not outside your window, but is instead on your television. Such deceptively realistic images are not only a result of the high resolution displays available on modern devices; the colors play a role as well, and they are becoming ever brighter and richer. This is possible thanks to tiny crystals known as quantum dots (QDs), which have a thickness of merely a few atoms. These nanoparticles located in the backlight units of QD LCD displays offer a cornucopia of colors, but also they possess another extraordinary characteristic. “One big advantage of quantum dots is that their optical properties can be selectively modified by changing their size,” explains Dr. Armin Wedel of the Fraunhofer Institute for Applied Polymer Research IAP in Potsdam, Germany. “This means you no longer have to manufacture three separate materials for the colors red, green and blue; now it is possible to do the job with just one.” This saves both time and money. Over the last several years, Fraunhofer IAP researchers in Potsdam have been developing quantum dots for customers in a wide range of industry sectors. They manufacture the nanoparticles using chemical synthesis and customize them for each application. This initially results in very small particles that radiate blue light. At sizes above approximately 2 nanometers, the color changes to green. The largest of the quantum particles, at 7 nanometers in size, emit within the red spectral range. Currently, Wedel and his team are developing quantum dots for display backlighting on behalf of Dutch company NDF Special Light Products B.V. These quantum dots will improve the color rendering and color realism of the displays. Here, the crystals are manufactured for the different emission colors and embedded in plastics. These plastics are subsequently processed into films and built into the display as a conversion film. Alternative materials based on indium phosphide With this task, researchers are facing a new challenge. The EU Commission is currently considering a ban on cadmium in consumer goods by 2017, because of its damaging effect on the environment. However, it is also considered to be the ideal material for manufacturing the crystals – cadmium-based quantum dots can achieve a narrowband spectrum sharpness of just 20 to 25 nanometers. Display manufacturers around the world are now looking for suitable replacement materials with similar characteristics. Against this backdrop, Fraunhofer IAP looks to be on a promising path. “We are testing quantum dots based on indium phosphide together with NDF Special Light Products,” says Wedel. His team has already managed to achieve a spectral sharpness of 40 nanometers. At first glance, that does not seem too far away from the quality achievable with cadmium-based quantum dots, but the differences in color fidelity are still present. “We see this as a good first milestone, but we are still striving for further improvement,” says Wedel. This effort is set to pay off, as television manufacturers are not the only ones who covet these little color wonders. There is also great market potential for special applications such as medical or aeronautical equipment displays. Furthermore, quantum dots can also increase the efficiency of solar cells, or can be employed in bioanalytics. For such special cases, the optical characteristics of the quantum dots must be precisely configured to the specific application requirements. “We’re in a good position thanks to our extensive experience in manufacturing quantum dots to meet specific customer requirements,” says Wedel.