Wearable device makes memories and powers up with the flex of a finger
RMIT UniversityAustralian researchers have developed a wearable device that can generate power from a user's bending finger and store memories
Australian researchers have developed a wearable device that can generate power from a user's bending finger and store memories
The Korea Institute of Science and Technology (KIST) announced that have presented a new artificial intelligence-based catalyst screening methodology and succeeded in developing a new catalytic material based on a ternary element-based alloy (Cu-Au-Pt) that is cheaper and performs more than twice as well as pure platinum catalysts.
Irvine, Calif., Oct. 17, 2023 — TeamMADE, a sustainable home design and construction crew with student members from the University of California, Irvine and Orange Coast College, placed second overall in the Orange County Sustainability Decathlon, which was held Oct.
In APL Materials, researchers tested a molecular energy harvesting device that captures the energy from the natural motion of molecules in a liquid. Their work showed molecular motion can be used to generate a stable electric current. To create the device, they submerged nanoarrays of piezoelectric material in liquid, allowing the movement of the liquid to move the strands like seaweed waving in the ocean, except in this case the movement is on the molecular scale, and the strands are made of zinc oxide. When the zinc oxide material waves, bends, or deforms under motion, it generates electric potential.
New technique could be used in medical diagnostics and advanced manufacturing.
The Korea Institute of Science and Technology (KIST) announced that has developed a new zero-dimensional and two-dimensional (2D-0D) semiconductor artificial junction material and observed the effect of a next-generation memory powered by light.
Argonne National Laboratory to receive $9 million in funding from the Department of Energy for addressing challenges with scaling up quantum networks to national scales.
Nanozymes are synthetic materials that mimic the properties of natural enzymes for applications in biomedicine and chemical engineering. They are generally considered too toxic and expensive for use in agriculture and food science.
Lithium-ion batteries are useful for electric vehicles but use raw materials that are costly and face potential supply chain issues. The performance of one alternative, sodium-ion batteries, declines rapidly with repeated charges and discharges.
Researchers have long sought to understand locusts and their power of sensing, computing and locomotory capabilities. WashU engineers will study how the locust brain transforms sensory input into behavior with a four-year $4.3 million grant from the National Science Foundation.
Reservoir computing, a type of machine learning, to program a robot to move two arms on a 2D plane in a computer simulation, allows the robot to change trajectory between predefined paths with only partial knowledge of the surrounding environment.
Perovskite light-emitting diodes (PeLEDs) are one of the most promising new display technologies, while the performance of their blue devices is a key obstacle to practical applications. Scientists in China comprehensively summarized three main technical routes (compositional engineering, dimensional control, size confinement) towards blue perovskites and the latest progress of blue PeLED.
Argonne has partnered in the Midwest Alliance for Clean Hydrogen (MachH2) to ramp up clean hydrogen production in the Midwest. The DOE recently awarded up to $1 billion in funding to the initiative to launch a regional clean hydrogen hub in the Midwest.
Filterless light-ellipticity-sensitive optoelectronic response generally has low discrimination, thus severely hindering the development of monolithic polarization detectors.
The organization, which consists of state-wide partnerships between institutions of higher education, governmental bodies, and members of private industry, will help develop Utah’s semiconductor workforce and increase its access to key technological infrastructure.
Nadine Aubry, a professor in the Department of Mechanical Engineering, was recently elected as an international fellow of the United Kingdom’s Royal Academy of Engineering. This prestigious honor recognizes engineers who have made significant contributions to their respective fields.
The Urban Future Summit, now in its 7th year, is hosted by the Urban Future Lab (UFL) at NYU Tandon School of Engineering and sponsored by The New York Community Trust, MUFG Bank, and Keyframe Capital. It was held on October 12, 2023 at Dock 72. After an afternoon of pitches and panel discussions, the jury, comprised of industry experts from Fifth Wall, Energy Impact Partners, RA Capital Management, Aligned Climate Capital, and UFL, chose two winners that were awarded a $50,000 cash prize each and admission into the ACRE incubator.
The Urban Future Summit, now in its 7th year, is hosted by the Urban Future Lab (UFL) at NYU Tandon School of Engineering and sponsored by The New York Community Trust, MUFG Bank, and Keyframe Capital. It was held on October 12, 2023 at Dock 72. After an afternoon of pitches and panel discussions, the jury, comprised of industry experts from Fifth Wall, Energy Impact Partners, RA Capital Management, Aligned Climate Capital, and UFL, chose two winners that were awarded a $50,000 cash prize each and admission into the ACRE incubator.
RUDN University scientists have found the most accurate way to determine the spatial structure of urban confinement using satellite images. It will help create precise maps and monitor the microclimate of the urban environment, support sustainable development and even make weather forecasts.
A research team led by Dr. Oh, Si Hyoung of the Energy Storage Research Center at the Korea Institute of Science and Technology (KIST) has developed a highly safe aqueous rechargeable battery that can offer a timely substitute that meets the cost and safety needs.
A research team led by Dr. Oh, Si Hyoung of the Energy Storage Research Center at the Korea Institute of Science and Technology (KIST) has developed a highly safe aqueous rechargeable battery that can offer a timely substitute that meets the cost and safety needs.
New pharmaceuticals, cleaner fuels, biodegradable plastics: in order to meet society’s needs, chemists have to develop new synthesis methods to obtain new products that do not exist in their natural state.
Quantum computers promise to reach speeds and efficiencies impossible for even the fastest supercomputers of today. Yet the technology hasn’t seen much scale-up and commercialization largely due to its inability to self-correct.
Synthetic biologists at Columbia Engineering report today a new approach to attacking tumors. They have engineered tumor-colonizing bacteria (probiotics) to produce synthetic targets in tumors that direct CAR-T cells to destroy the newly highlighted cancer cells.
Research by the U.S. Department of Energy's Argonne National Laboratory reveals that recycling post-use plastic through pyrolysis can reduce GHG emissions by 18-23%. Approach can potentially enhance sustainability by minimizing waste and fossil resource reliance.
The Korea Institute of Science and Technology (KIST) announced that Dr. Jiwon Lee and Dr. Youngtak Oh from the Center for Sustainable Environment Research have developed a new adsorbent technology that can efficiently adsorb amphiphilic VOCs, which have both hydrophilic and hydrophobic properties and are difficult to remove with existing activated carbon technology.
Rubin Observatory’s Legacy Survey of Space and Time will help scientists map the large-scale structure of the Universe with finer precision than ever before. With Rubin’s wide field of view and high resolution, the subtle distortions of galaxy shapes caused by dark matter will be detectable, allowing scientists to map dark matter and explore its cosmic tug of war with dark energy.
The nuclear reactions that power stellar explosions involve short-lived nuclei that are hard to study in the laboratory. Researchers used a combination of methods to measure a reaction where a neutron from a deuterium target is exchanged with a proton from a radioactive projectile, a reaction equivalent to a process in exploding stars.
Jefferson Lab joins four other scientific research institutions in a collaborative research project that aims to measure the lifetime of spin polarization in particles used to fuel nuclear fusion. Here’s a look at Jefferson Lab’s role in the joint venture.
Researchers modeled the performance of hypothetical floating wind farms off the coast of southern Oregon and northern California, showing multiple futures in which the benefits outweigh the cost of development.
Scientists at Berkeley Lab have created multi-sensor systems that can map nuclear radiation in 3D in real-time. Researchers are now testing how to integrate their system with robots that can autonomously investigate radiation areas.
By: Tisha Keller | Published: October 11, 2023 | 2:41 pm | SHARE: The 2023 Nobel Prize in Chemistry was recently awarded to three renowned scientists for the development of quantum dots — nanoparticles so small that their properties are determined by quantum phenomena. Quantum dots are used to illuminate televisions and computer screens, LED lamps, and help guide surgeons in removal of tumor tissue.
Transition metal dichalcogenide (TMD) semiconductors are special materials that have long fascinated researchers with their unique properties.
Researchers have long recognized the therapeutic potential of using magnetoelectrics ⎯ materials that can turn magnetic fields into electric fields ⎯ to stimulate neural tissue in a minimally invasive way and help treat neurological disorders or nerve damage.
In Journal of Applied Physics, researchers describe an acoustic metasurface that uses pingpong balls, with small holes punctured in each, as Helmholtz resonators to create inexpensive but effective low-frequency sound insulation. The coupling between two resonators led to two resonance frequencies, and more resonant frequencies meant the device was able to absorb more sound. At the success of two coupled resonators, the researchers added more, until their device resembled a square sheet of punctured pingpong balls, multiplying the number of resonant frequencies that could be absorbed.
Cornell researchers took a novel approach to explore the way microstructure emerges in a 3D-printed metal alloy: They bombarded it with X-rays while the material was being printed.
UC San Diego engineers developed electronic “stickers” that measure the force exerted by one object upon another. The force stickers are wireless, run without batteries and fit in tight spaces, making them versatile for a wide range of applications, from surgical robots to smart implants and inventory tracking.
A team led by researchers at the Department of Energy’s Oak Ridge National Laboratory developed a framework for designing solid-state batteries, or SSBs, with mechanics in mind. Their paper, published in Science, reviewed how these factors change SSBs during their cycling.
Researchers at the Department of Energy’s Oak Ridge National Laboratory, in collaboration with NASA, are taking additive manufacturing to the final frontier by 3D printing the same kind of wheel as the design used by NASA for its robotic lunar rover, demonstrating the technology for specialized parts needed for space exploration.
Borrowing from neuroscience, researchers at the University of Pittsburgh will engineer neural networks for robots, giving them the ability to learn and improve their ability to navigate different terrains.
A pair of theoretical physicists are reporting that the same observations inspiring the hunt for a ninth planet might instead be evidence within the solar system of a modified law of gravity originally developed to understand the rotation of galaxies.
Gadgets and vehicles powered by the very materials they’re built from may soon be possible, thanks to a new structural supercapacitor developed by UC San Diego engineers. The device doubles as structural support and energy storage, potentially adding more energy capacity without adding weight.
Argonne researchers have tapped into the power of AI to create a new form of autonomous microscopy.
A research team has won a four-year, $14 million grant to design a national testing facility that will simulate tornadoes and other windstorms. Experiments will measure the loads that windstorms exert on structures and help researchers engineer building improvements that can reduce damage and save lives.
If West Virginia University research pays off, debris that litters the planet’s orbit and poses a threat to spacecraft and satellites could get nudged off potential collision courses by a coordinated network of space lasers.
Robots built by engineers at the University of California San Diego helped achieve a major breakthrough in understanding how insect flight evolved, described in the Oct. 4, 2023 issue of the journal Nature. The study is a result of a six-year long collaboration between roboticists at UC San Diego and biophysicists at the Georgia Institute of Technology.
An ideal holographic 3D display should offer large viewing angle, full color, and low speckle noise. A new holographic 3D display system with a large viewing angle of 73.4° has been proposed. The system uses spatial light modulators (SLMs) and liquid crystal grating to achieve maximum diffraction modulation, which allows for a larger hologram size and a wider viewing angle. The proposed system has potential applications in education, culture, and entertainment.
Quantitative phase imaging (QPI) is a label-free computational technique frequently used for imaging cells and tissue samples while facing challenges when diffusive media obstruct the optical path. UCLA researchers, led by Prof. Aydogan Ozcan, reported a diffractive optical network that perform QPI through random unknown phase diffusers. The potential integration of QPI diffractive networks onto image sensors may enable existing optical microscopes to perform all-optical phase recovery and image reconstruction on a chip.
Interests surrounding the development of on-chip nonlinear optical devices have grown consistently in the past decades due to their tremendous applications. Developing efficient on-chip nonlinear optical devices for these applications is needed to improve the existing photonic approaches. The combination of well-known photonic chip design platforms and different two-dimensional layered materials has opened the road for more versatile and efficient structures and devices, which has the great potential to unlock numerous new possibilities.