Articles tagged with Instrumentation
Researchers from Adelaide University have developed a new portable atomic clock that can operate in challenging real-world conditions. The device uses laser-cooled atoms to keep time with extreme precision and has been successfully tested at sea on a naval vessel.
The journal focuses on advancing scientific understanding and expanding engineering horizons through rigorous peer-reviewed, open-access research. ASI aims to be the preeminent hub for pioneering next-generation scientific tools and fostering global collaboration.
Oliver Zielinski's contributions to oceanography have significantly advanced understanding and stewardship of the ocean through innovative research and leadership. He has led applications of artificial intelligence for environmental monitoring and mentored early-career scientists.
Dr. Michael Davis, an astrophysicist at Southwest Research Institute, has been recognized by SPIE as a Fellow for his work on space instruments and UV imaging. He is the optics and detector scientist for NASA's Lunar Reconnaissance Orbiter and Juno mission to Jupiter.
Michael Blanton will lead the Carnegie Science Observatories as its 12th director, focusing on large-scale astronomical surveys to constrain cosmological history. The new director brings a deep well of knowledge of instrumentation and data collection to oversee research at Pasadena's campus and Las Campanas Observatory.
Researchers developed a non-destructive testing system using bubble wrap bursts, detecting objects within a 2% error margin without electricity or heavy equipment. The system harnesses the acoustic characteristics of bubble wrap bursts to identify internal obstructions in pipes.
A UNF chemistry professor has been awarded a NSF grant to build a custom LIBS system and develop new calibration strategies. The project aims to improve trace-level analyte detection and transform not only LIBS but also other analytical technologies.
UC Riverside-developed FROSTI system allows precise control of laser wavefronts at extreme power levels, opening a new pathway for gravitational-wave astronomy. This technology expands the universe's view by a factor of 10, potentially detecting millions of black hole and neutron star mergers with unmatched fidelity.
The £250 million investment will create an Advanced Marine Technology Hub at the University of Plymouth, leveraging its expertise in autonomous marine systems, maritime cyber security, and renewable energy. This initiative aims to boost the city's economy and enhance UK's national resilience.
Dr. Karen I. Perez joins the SETI Institute as the inaugural recipient of the William J. Welch Postdoctoral Fellowship, developing real-time analysis pipelines for detecting signals from intelligent life. Her research will advance radio astronomy and contribute to shaping the next generation of SETI instrumentation.
Quaise Energy has successfully demonstrated its novel drilling technique on a full-scale oil rig, aiming to prove that clean, renewable geothermal energy can power the world. The company's three-tier approach involves replacing conventional drill bits with millimeter-wave energy to create deeper holes and access supercritical water.
Researchers developed quantum sensors capable of precisely detecting single particles, improving time and spatial resolution. The sensors demonstrated efficiency in detecting high-energy beams of protons, electrons, and pions.
The Shimadzu – DxD Hub Diagnomics Centre aims to accelerate the development of high-quality, cost-effective diagnostic solutions. It focuses on three key areas: infectious diseases, cancer, and metabolic disorders, with efforts to develop solutions for early disease detection and precision medicine approaches.
Ben Jones, a UTA physicist, has been recognized for his contributions to developing advanced instruments used in particle physics research. His work focuses on uncovering the origin of neutrino mass and sheds light on fundamental physics at extremely small scales.
Researchers developed a highly sensitive hydrogen detection system using tunable diode laser absorption spectroscopy (TDLAS) with high selectivity and rapid response. The new method achieved accurate measurements of hydrogen concentrations from 0.01% to 100%, improving the detection limit at longer integration times.
A groundbreaking quantum sensor capable of detecting minute magnetic fields has been developed through international scientific collaboration. The sensor utilizes a single molecule to sense electric and magnetic properties of atoms, offering spatial resolution on the order of a tenth of an angstrom.
Researchers from SLAC, Stanford and other institutions have developed a technique to improve time resolution for the MeV-UED electron camera and trained an artificial intelligence model to tune the beam for various experimental needs. This enables unprecedented precision in exploring novel effects in materials and chemistry.
Researchers at the University of Malaga have developed an instruction manual to understand the operating limits of phantom motion, allowing for cost-effective and lighter haptic devices. The study found that individuals can perceive phantom sensation when a vibrating point travels at least 20% of the separation between actuators.
Researchers have introduced iso-propagation vortices, offering a solution to increasing information processing capacity while overcoming traditional vortex beam limitations. IPVs exhibit OAM-independent propagation, allowing for consistent beam size during free-space propagation.
A $161 million grant from the DOD will support research into tunable thermal conductivity and latent heat storage effects in materials. The new equipment enables analysis across a wide temperature range and various pressures and humidity levels, paving the way for adaptive materials with dynamically tunable phase change properties.
A study using Google Street View cars found hyper-local air pollution hotspots in the Salt Lake Valley, revealing spatial variability and environmental justice issues. The research identified pollution emission sources off-road from traffic and industrial areas.
Researchers have developed a high-resolution MRI microscope capable of capturing human embryos with a resolution of one-hundredth of a millimeter. This breakthrough enables detailed visualization and analysis of brain development and organ growth, paving the way for a high-resolution atlas of brain and other organs.
Researchers found microorganisms in Martian rocks that are difficult to detect with current instrumentation. The team suggests more powerful tools or bringing samples to Earth to conclusively address whether life existed on Mars. A European Mars rover expected to launch in 2028 will carry a drill capable of analyzing sediments deeper, ...
Researchers developed BrightEyes-TTM, an open-source stopwatch to study molecular interactions inside living cells. The platform records the lifetime of fluorescent molecules, providing insights into cellular structure and function.
Researchers at the University of Maryland successfully guided a 45-meter-long beam of light through an unremarkable hallway, pushing the limits of an innovative technique. The team utilized ultra-short laser pulses to create a plasma that heated air, forming a high-density core and enabling efficient light delivery.
Researchers at UMD successfully guided light in a 45-meter-long air waveguide, creating a high-density core to guide a laser. The technique utilizes ultra-short laser pulses to create a plasma that heats the air, expanding it and leaving a low-density path behind.
The Energy Loss Optical Scintillation System (ELOSS) represents a significant advancement in experimental nuclear physics instrumentation. Researchers can now study isotopes at high beam rates and performance, with the new detector offering nearly three times better resolution and counting rates compared to conventional charge readout ...
Researchers at Lehigh University have received a $1.2 million NSF grant to purchase a new plasma focused ion beam system for studying material deformation at the nanoscale. The system enables in situ mechanical testing and EBSD analysis, allowing for detailed study of microstructural elements and
The Global Jukebox, an online tool for exploring music and performing arts from around the world, has made its dataset and data available to the public. The database includes 5,776 recordings representing 1,026 societies, with detailed musical style categorization data and additional features such as breath management and instrumentation.
A study by Colorado State University found that indoor air contains more known human toxins than outdoor air, particularly when cooking or cleaning. The research, called HOMEChem, identified compounds like benzene, formaldehyde, and acrolein as potential health risks.
A team of researchers uses mirrors to gather more light and views of an object from different angles, allowing them to reconstruct a three-dimensional model of an atom cloud. This technique enables 'light-field imaging', capturing not just intensity but also direction of light rays.
Researchers developed a novel method to monitor oxygen levels in the placenta using optical measurements and ultrasound, providing insights into its function and structure. The device showed promise in detecting placental dysfunction and differentiating between healthy and diseased placentas.
A recent study combined elevation data of the Antarctic ice sheet from two different satellites, CryoSat-2 and Sentinel-3, to obtain a more accurate map of latest elevation changes. The results showed that the average elevation of the ice sheets had decreased at a rate of 4.3 cm/year during 2016-2019.
The study compares the behavior of flat (1D), cylindrical (2D) and spherical (3D) micromirrors for free-space light coupling. Silicon micromirrors were fabricated and used to experimentally validate the coupling efficiency in visible and near infrared wavelengths.
Researchers developed a novel frequency-domain method to selectively suppress background noise in STED microscopy, achieving higher spatial resolution and improved signal-to-noise ratio. The approach has potential applications in various dual-beam point-scanning techniques.
Researchers developed autohaem devices to automate blood smears, increasing accuracy and efficiency in malaria diagnosis. The devices can produce high-quality smears equivalent to those created by human experts, reducing errors and improving patient outcomes.
A $3.7 million multicampus grant will train 32 graduate students in high-energy physics instrumentation, addressing a long-standing workforce training deficit in the field. The program, led by UC Davis, aims to prepare students for careers in academia, industry, or national laboratories.
Quaise Inc.'s new geothermal drilling technology uses millimeter waves to melt and vaporize rock, allowing for deeper access to hot resources. The company's test campaign aims to drill holes with increasing aspect ratios, simulating the full drilling process.
Scientists at Tokyo University of Science develop a new methodology to investigate the elusive electric double layer (EDL) effect in all-solid-state batteries. The study reveals that the EDL effect is dominated by the electrolyte's composition and can be suppressed through charge compensation, leading to improved performance.
The NIST-developed emberometer uses digital cameras to track embers in mid-air and reconstruct their 3D shapes. This tool helps researchers understand the behavior of embers, which can aid in developing better protection for structures during wildfires.
The National Institute of Information and Communications Technology has developed a highly-accurate and wide-measurable band terahertz frequency counter. The counter's measurement uncertainty is less than 1 x 10^-16, making it suitable for various applications including high-resolution spectroscopy of ultracold molecules.
The Hayabusa2 mission successfully returned asteroid samples from Ryugu, a carbonaceous asteroid believed to contain organic materials. The return marks the second successful sample-return mission in history, offering insights into the origin of life and potential resource utilization for space exploration.
The journal's editorial board selected three papers for best paper awards, showcasing innovative work in interdisciplinary applications, theoretical innovation, and photo-optical instrumentation design. The honorees include a paper on deep-learning-based object detection for monitoring underwater ecosystems and marine debris.
Advanced Devices & Instrumentation, the fifth journal in AAAS's Science Partner Journal program, publishes high-impact breakthroughs in electronics, photonics, and artificial intelligence. The journal aims to provide a platform for valuable research outcomes in fields like sensor technology, internet-of-things and energy management.
The new focusing system overcomes the space charge effect, allowing for improved resolution and brighter diffraction data. The team's advanced design uses quadrupole magnets to tune the electron beam, enabling on-the-fly adjustments and optimal beam quality.
The DFG is funding 12 projects to develop new instrumentation technologies for basic research. A new X-ray system will be built at the Technical University of Kaiserslautern, enabling researchers to analyze reinforced concrete components in unprecedented detail.
A team of scientists at Ames Laboratory will develop a subdiffraction Raman imaging platform to analyze plant cell walls' chemical structures. This will enable better understanding of how to convert plant material into biofuels.
The Materials Innovation Platforms (MIPs) program aims to accelerate materials research and development, enabling the discovery of new materials, techniques, and instrumentation. The program focuses on crystal growth, oxide and 2D materials, and will advance a focused research area of national importance.
The Berkeley Lab team is developing electronics that will send data from the scanner's detectors to a computer, converting it into a three-dimensional image of the patient. This new scanner will have half a million detectors, reducing a patient's radiation dose by a factor of 40 and scanning time from 20 minutes to just 30 seconds.
David Nygren, a renowned physicist at UTA, has been awarded the Division of Particles and Fields Instrumentation Award for his pioneering work on the Time Projection Chamber. This technology has enabled accurate capture of results in high-energy particle collisions, leading to breakthroughs in particle detection and discovery.
New discoveries are being made on high-altitude balloons, which offer a space-like environment for various disciplines. The longest flight to date was SuperTIGER's 55-day journey to 39.6 km altitude, paving the way for longer flights and novel instrumentation.
Researchers at UT Dallas have won nearly $1 million in defense grants to develop high-frequency integrated circuit design equipment. The instrumentation, including a hybrid load pull system and a millimeter wave antenna measurement system, will be available for use by TxACE members and outside industrial users.
A month-long study by University of Houston aims to enhance air quality forecasting using satellite data and numerical models. The team collected extensive data from mobile labs, aircraft, and satellites to develop more accurate pollution sensors.
Researchers at LSU will utilize the SuperMIC cluster for various projects, including discovery of new drugs and modeling coastal processes. The project aims to train the next generation of researchers in high-performance computing and prepare students for the future.
Researchers have developed large area picosecond photodetectors that can measure particle speed with sub-picosecond resolution and spatial precision measured in micrometers. The detectors use Atomic Layer Deposition technique and have potential applications in high-energy physics, medical imaging, and homeland security.
A new low-cost, high-resolution desktop nanofabrication tool enables the rapid production of high-quality materials and devices at the nanoscale. The tool produces working devices and structures in a matter of hours, making it a game-changer for fields like gene chip development and electronic circuit creation.
The Air Force has announced 29 university researchers at 26 institutions will receive awards totaling $12.7 million for research instrumentation. These awards support the purchase of state-of-the-art equipment for cutting-edge defense research.
R. Graham Cooks receives the Dreyfus Prize for his groundbreaking work on mass spectrometry instrumentation, enabling remote deployment of analytical instruments and transforming fields like pharmaceuticals and biotechnology. This achievement showcases Cooks' innovative spirit and impact on modern science.
The Deutsche Forschungsgemeinschaft (DFG) has approved funding for ten additional core facilities to make existing research instrumentation more easily accessible to researchers. The facilities will provide state-of-the-art equipment and expertise, enabling researchers to conduct complex studies efficiently.
The University of Oklahoma has received nearly $2 million in National Science Foundation grants to enhance its research capabilities in meteorology, high energy physics, and bioengineering. The grants will enable OU faculty and students to conduct cutting-edge research with state-of-the-art equipment.