The Kynix Blog

It takes a very, very clean room to build a detector sensitive enough to see the light from the beginning of the universe.Work is underway at the U.S. Department of Energy's (DOE's) Argonne National Laboratory on a new "clean room." The new lab will be specially suited for building parts for ultra-sensitive detectors—such as those to carry out improved X-ray research, or for the South Pole Telescope to search for light from the early days of the universe."This will be a unique facility, and a wonderful investment for the future of the laboratory," said Supratik Guha, who heads the Center for Nanoscale Materials, a DOE Office of Science User Facility adjacent to where the new space will be located.Clean rooms are a special kind of laboratory that is heavily filtered and cleaned, so that no free-floating particles interfere with delicate work. Take a cube of air one foot on a side: In a normal room in your house or office, this cube contains about one million free-floating particles of dust, dirt and other materials. In the clean room, it's no more than 100.This environment is what you need to build detectors that can detect the tiniest amount of energy striking the surface."Even a few stray specks of dust in the niobium can throw off the design for these detectors," said Marcel Demarteau, who heads the High Energy Physics Division at Argonne and will be a key user of the new lab.One use for such detectors is in the South Pole Telescope in Antarctica, one of several telescopes searching for light waves that have traveled throughout the universe since the moments after the Big Bang. This kind of light is called the Cosmic Microwave Background radiation.Because the light has traveled across space for the 13.8 billion years since the universe began, it has encountered all sorts of obstacles that slightly change its power spectrum—galaxy clusters, patches of dark matter, even our own atmosphere. "We have to correct for these to map the Cosmic Microwave Background signature we're looking for, but these small perturbations themselves hold an enormous amount of very valuable information about the composition of the universe," Demarteau said.  The most sensitive instruments today to find such signals are detectors made from superconductors. Superconductors are extremely sensitive materials that change properties dramatically when their temperature is raised even a tiny bit, and scientists can build components that react to specific frequencies to detect the signature of the Cosmic Microwave Background. The new clean room should allow researchers to build even more sensitive detectors—think of a camera that takes 150-pixel pictures versus one that can take 500,000-pixel images.The same technology will also offer researchers a chance to get better close-ups of the atomic makeup of objects being studied at the Advanced Photon Source, a DOE Office of Science User Facility at Argonne where scientists use X-rays to study everything from car fuel injectors to proteins that play roles in disease.The Advanced Photon Source sends beams of high-energy X-rays at a sample of whatever scientists are studying: a new solar cell material, a sample of volcanic glass from Greenland, a protein involved in photosynthesis. The X-rays hit the sample and scatter off in all directions. Very sensitive detectors pick up that scatter and reveal the chemical and atomic layout of the sample. The better the detector, the more information you can get; so Advanced Photon Source scientists are always looking for new ways to improve those detectors."The type of detector we want to build, nobody makes commercially: so we have to build our own," said Thomas Cecil, an engineer with the Advanced Photon Source. The new clean room will allow them to experiment with new kinds of transition edge sensors, which he said they hope could eventually improve the sensitivity by one or even two orders of magnitude compared to traditional silicon-based detectors.Building such technology is an excruciatingly delicate process, in which they lay down multiple coatings just a few nanometers thick—less than a hundredth of the diameter of a human hair—of superconducting materials and etch patterns into them. Then they repeat the process all over again, for up to 15 layers.The detector itself is so precise that it's operated at temperatures colder than outer space to achieve maximum sensitivity. "It's an excellent opportunity for us to push the boundaries of what's possible," Cecil said.Other potential uses, Demarteau said, include quantum computing as well as homeland security: building detectors that can pick out the particular signature of a specific kind of radiation, to detect if terrorists are carrying a dirty bomb made out of, for example, cesium-137. 

A group of researchers at Osaka University, succeeded in producing nanostructured gas sensor devices for detecting volatile organic compounds (VOC) in breath for the purpose of healthcare in time equivalent to or shorter than one tenth of the time required for manufacturing conventional gas sensors. This group improved conventional complicated production methods, developing a simple production method of just sintering substrates applied with materials. This gas sensor's sensing response was comparable to the top-of-the-line sensors reported all over the world.Research leading detection of low concentrations of gas present in exhaled human breath to health checkups and early detection and treatment of serious diseases is being performed. As gas sensors using nanomaterials can detect various gases even at low concentrations, installing such sensors in electronic healthcare devices is sought after, and research and development are being actively conducted.Semiconductor gas sensors detect gas through reduced electrical resistance due to gas molecules attached to the surface of crystalline semiconductor materials. For this, gas sensors need a specific surface area of nanomaterials. In order to use nanomaterials for conventional gas sensors, a complicated flow was necessary, from nanomaterials synthesis to cleansing, uniform dispersion of solvent, applying on substrates, and sintering. Thus, there is a concern that manufacturing technology of such gas sensors requires significant time and labor, increasing cost.A group of researchers led by Assistant Professor Tohru Sugahara (SUGANUMA Lab.) at The Institute of Scientific and Industrial Research, Osaka University, succeeded in producing nanostructured gas sensor devices for detecting volatile organic compounds (VOC) in breath for the purpose of healthcare in time equivalent to or shorter than one tenth of the time required for manufacturing conventional gas sensors. This group improved conventional complicated production methods, developing a simple production method of just sintering substrates applied with materials. This gas sensor's sensing response was comparable to the top-of-the-line sensors reported all over the world.Since demand in healthcare products is on the rise, there is a lot of activity in research and development of sensors for checking health and disease by examining the gas components of a person's breath. Breathalyzers for finding out who is driving drunk have already been commercialized. Recently, breath sensors for early detection of life-style diseases such as cancer and diabetes have been developed, but most of them are large, bulky and expensive. If gas sensors with high sensitivity are produced thanks to this group's research results, portable breath sensors enabling early detection of diseases will gain popularity.Reference:KGZ10 KGZ10-SPGMS10RVS  

New research by scientists from the University of Bristol has revealed that domestic LED lights are much less attractive to nuisance insects such as biting midges than traditional filament lamps.The team now highlights the urgent need for further research on other heat-seeking flies that transmit disease, including mosquitoes that are carriers of pathogens that cause damaging diseases such as malaria and Zika fever.The study, funded by the Natural Environment Research Council and UK lighting manufacturer Integral LED, used customised traps at 18 field test sites across south-west England, illuminated by a series of LED, filament and fluorescent light sources. Over 4,000 insects were carefully identified. The results showed that LEDs attracted four times fewer insects compared with the traditional incandescent lamps, and half as many as were attracted to a compact fluorescent lamp.Notably, for biting flies (midges in the genus Culicoides, some species of which are vectors of wildlife disease), 80 percent were attracted to the filament lamp, 15 percent to the compact fluorescent and only 2-3 percent to each of the two different LED lamps.Dr Andy Wakefield led the field research in a project supervised by Professors Gareth Jones and Stephen Harris from the University's School of Biological Sciences.  Dr Wakefield said: "We were surprised by the number of biting flies drawn to the traditional tungsten lights. We do not know why this is but we know that some insects use thermal cues to find warm-blooded hosts in the night, so perhaps they were attracted to the heat given off by the filament bulb."Co-sponsors of the study, Integral LED were instrumental in the commissioning of the project and provided technical and financial support.The UK company's Marketing Director Sanjiv Kotecha said: "As lighting manufacturers, we welcome that a link between LED lights and low attraction to insects has been proven. The energy saving advantages of solid-state lighting are well known, yet the benefits to well-being are only beginning to be revealed."Reference:ASMT-UYBG-NACJ8XRCWHT-L1-0000-004E6LUWCP7P-KTLP-5E8G-35-Z  

 A team of Harvard University researchers with expertise in 3D printing, mechanical engineering, and microfluidics has demonstrated the first autonomous, untethered, entirely soft robot. This small, 3D-printed robot—nicknamed the octobot—could pave the way for a new generation of completely soft, autonomous machines.Soft robotics could revolutionize how humans interact with machines. But researchers have struggled to build entirely compliant robots. Electric power and control systems—such as batteries and circuit boards—are rigid and until now soft-bodied robots have been either tethered to an off-board system or rigged with hard components.Robert Wood, the Charles River Professor of Engineering and Applied Sciences and Jennifer A. Lewis, the Hansjorg Wyss Professor of Biologically Inspired Engineering at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) led the research. Lewis and Wood are also core faculty members of the Wyss Institute for Biologically Inspired Engineering at Harvard University."One long-standing vision for the field of soft robotics has been to create robots that are entirely soft, but the struggle has always been in replacing rigid components like batteries and electronic controls with analogous soft systems and then putting it all together," said Wood. "This research demonstrates that we can easily manufacture the key components of a simple, entirely soft robot, which lays the foundation for more complex designs.""Through our hybrid assembly approach, we were able to 3D print each of the functional components required within the soft robot body, including the fuel storage, power and actuation, in a rapid manner," said Lewis. "The octobot is a simple embodiment designed to demonstrate our integrated design and additive fabrication strategy for embedding autonomous functionality."Octopuses have long been a source of inspiration in soft robotics. These curious creatures can perform incredible feats of strength and dexterity with no internal skeleton.Harvard's octobot is pneumatic-based, i.e., it is powered by gas under pressure. A reaction inside the bot transforms a small amount of liquid fuel into a large amount of gas, which flows into the octobot's arms and inflates them like a balloon."Fuel sources for soft robots have always relied on some type of rigid components," said Michael Wehner, a postdoctoral fellow in the Wood lab and co-first author of the paper. "The wonderful thing about hydrogen peroxide is that a simple reaction between the chemical and a catalyst—in this case platinum—allows us to replace rigid power sources."To control the reaction, the team used a microfluidic logic circuit based on pioneering work by co-author and chemist George Whitesides, the Woodford L. and Ann A. Flowers University Professor and core faculty member of the Wyss. The circuit, a soft analog of a simple electronic oscillator, controls when hydrogen peroxide decomposes to gas in the octobot."The entire system is simple to fabricate, by combining three fabrication methods—soft lithography, molding and 3D printing—we can quickly manufacture these devices," said Ryan Truby, a graduate student in the Lewis lab and co-first author of the paper.The simplicity of the assembly process paves the way for more complex designs. Next, the Harvard team hopes to design an octobot that can crawl, swim and interact with its environment."This research is a proof of concept," Truby said. "We hope that our approach for creating autonomous soft robots inspires roboticists, material scientists and researchers focused on advanced manufacturing."Reference:DS1260-50DS90340I-PCXM4Z28-BR00SH1 

Healthcare practitioners may one day be able to physically screen for breast cancer using pressure-sensitive rubber gloves to detect tumors, owing to a transparent, bendable and sensitive pressure sensor newly developed by Japanese and American teams.Conventional pressure sensors are flexible enough to fit to soft surfaces such as human skin, but they cannot measure pressure changes accurately once they are twisted or wrinkled, making them unsuitable for use on complex and moving surfaces. Additionally, it is difficult to reduce them below 100 micrometers thickness because of limitations in current production methods.To address these issues, an international team of researchers led by Dr. Sungwon Lee and Professor Takao Someya of the University of Tokyo's Graduate School of Engineering has developed a nanofiber-type pressure sensor that can measure pressure distribution of rounded surfaces such as an inflated balloon and maintain its sensing accuracy even when bent over a radius of 80 micrometers, equivalent to just twice the width of a human hair. The sensor is roughly 8 micrometers thick and can measure the pressure in 144 locations at once.The device demonstrated in this study consists of organic transistors, electronic switches made from carbon and oxygen based organic materials, and a pressure sensitive nanofiber structure. Carbon nanotubes and graphene were added to an elastic polymer to create nanofibers with a diameter of 300 to 700 nanometers, which were then entangled with each other to form a transparent, thin and light porous structure."We've also tested the performance of our pressure sensor with an artificial blood vessel and found that it could detect small pressure changes and speed of pressure propagation," says Lee. He continues, "Flexible electronics have great potential for implantable and wearable devices. I realized that many groups are developing flexible sensors that can measure pressure but none of them are suitable for measuring real objects since they are sensitive to distortion. That was my main motivation and I think we have proposed an effective solution to this problem."Reference:13C5000PA4K19C050PA4KMLH100PGM01B  

The world's smallest diode, the size of a single molecule, has been developed collaboratively by U.S. and Israeli researchers from the University of Georgia and Ben-Gurion University of the Negev (BGU).     "Creating and characterizing the world's smallest diode is a significant milestone in the development of molecular electronic devices," explains Dr. Yoni Dubi, a researcher in the BGU Department of Chemistry and Ilse Katz Institute for Nanoscale Science and Technology. "It gives us new insights into the electronic transport mechanism." Continuous demand for more computing power is pushing the limitations of present day methods. This need is driving researchers to look for molecules with interesting properties and find ways to establish reliable contacts between molecular components and bulk materials in an electrode, in order to mimic conventional electronic elements at the molecular scale. An example for such an element is the nanoscale diode (or molecular rectifier), which operates like a valve to facilitate electronic current flow in one direction. A collection of these nanoscale diodes, or molecules, has properties that resemble traditional electronic components such as a wire, transistor or rectifier. The emerging field of single molecule electronics may provide a way to overcome Moore's Law— the observation that over the history of computing hardware the number of transistors in a dense integrated circuit has doubled approximately every two years - beyond the limits of conventional silicon integrated circuits. Prof. Bingqian Xu's group at the College of Engineering at the University of Georgia took a single DNA molecule constructed from 11 base pairs and connected it to an electronic circuit only a few nanometers in size. When they measured the current through the molecule, it did not show any special behavior. However, when layers of a molecule called "coralyne," were inserted (or intercalated) between layers of DNA, the behavior of the circuit changed drastically. The current jumped to 15 times larger negative vs. positive voltages—a necessary feature for a nano diode. "In summary, we have constructed a molecular rectifier by intercalating specific, small molecules into designed DNA strands," explains Prof. Xu. Dr. Dubi and his student, Elinor Zerah-Harush, constructed a theoretical model of the DNA molecule inside the electric circuit to better understand the results of the experiment. "The model allowed us to identify the source of the diode-like feature, which originates from breaking spatial symmetry inside the DNA molecule after coralyne is inserted." Reference: CLCS145V0-G PACDN004SR  SLVU2.8.TCT