Sentences with phrase «in imaging application»
«Our proposed devices can retain the terahertz frequency like other terahertz sources but with a much shorter wavelength for an improved spatial resolution in imaging application as well as a very wide frequency tuning range from a microwave to a terahertz wave,» said Iurov.
https://www.sciencedaily.com/ Not exact matches
Now introduce smartphone technology and applications that let the information exchange, virtual examination, and imaging happen in multiple directions — between patient and physician and hospital — and you've made a doctor's visit smarter, faster, and cheaper.
Geographic information system and mapping capabilities that go hand - in - hand with UAVs have many applications across multiple industries, from bridge, road and pipeline mapping to tracking the path of wildfires and identifying hotspots to assist firefighters, crop monitoring and insect detection for farmers, and real - time imaging for search and rescue operations.
«Space - based applications, like imaging satellites, can help people more easily access important information, so we're excited to support SpaceX's growth as it develops new launch technologies,» Google said in a statement.
At Rafael they think outside the box concerning civilian applications too, and it was there that the revolutionary camera - in - a-pill of Given Imaging Ltd. (Nasdaq: GIVN; TASE: GIVN) was born.
The team who made the discovery say masers could be used in a range of applications such as medical imaging and airport security scanning.
Extending far beyond on either side of the visible wavelengths are the longer and shorter wavelengths of light that are exploited for myriad applications in communication, sensing, navigation, and imaging.
«It includes both a traditional one - year fellowship program open to UCLA graduate students, and a two - week immersive summer course in advanced magnetic resonance imaging methods and applications.»
The time resolution would ideally be improved from 0.5 frames per second (fps) to 30 fps for telecommunication, but many potential applications in medical and industrial imaging could use the lower rates already achieved, said Peyghambarian.
The researchers say this advance in nanoscience opens vast opportunities for a wide range of applications that includes catalysis (the acceleration of a chemical reaction by a catalyst), energy storage (batteries or supercapacitors), and bio / plasmonic imaging, among others.
Quantum dots, which have use in diverse applications such as medical imaging, lighting, display technologies, solar cells, photocatalysts, renewable energy and optoelectronics, are typically expensive and complicated to manufacture.
«Studying the formation and evolution of jets in metals and, more generally, how materials at extreme conditions respond using X-ray phase contrast imaging is relevant to such things as meteorite impacts, the performance of explosives and detonators, understanding crack nucleation and propagation in materials, and the development of new materials with tailored properties whose applications include automotive and airplane components, lighter and more impact - resistant armor, and debris shields in space, to name a few.»
The discovery, which relies on the separation of right - and left - «handed» particles, points to a range of potential applications in energy, quantum computing, and medical imaging, and possibly even a new mechanism for inducing superconductivity — the ability of some materials to carry current with no energy loss.
He has been involved in the creation of application notes and technical white papers on established and emerging imaging applications, trends, and technologies.
Carbon nanodots are tiny particles of carbon that are useful in imaging, sensing, drug delivery and many other applications.
He has 15 years» expertise in a wide range of imaging applications for CCD, EMCCD, and CMOS cameras as well as diverse microscopy and image - data visualization systems.
Dr. Guanying Li and Professor Zhang worked with colleagues from OIST's Imaging and Instrument Analysis Section, as well as scientists in the SM Application Group of JEOL in Tokyo.
They also have applications in medical diagnostics, where they can help to speed up magnetic resonance imaging, for example; and in entertainment, to encode high - resolution films into files of manageable size.
«The future is bright for the application of imaging in infectious diseases,» said Bocan.
The device's ability to absorb electromagnetic energy without heating up has direct applications in imaging, sensing and lighting.
In addition to her research focus on microbial biofilms, bacterial motility, and pathogenicity, Dr. Turnbull is also the OMX Application Specialist for the Microbial Imaging Facility.
The new results, published in AIP Advances, from AIP Publishing, could also lead to skyrmion - based devices such as microwave nano - oscillators, used in a range of applications including wireless communication, imaging systems, radar and GPS.
«This characteristic makes gold nanorods attractive for use in catalysis, security materials and a range of biomedical applications, such as diagnostics, imaging, and cancer therapy,» says Joe Tracy, a materials science and engineering researcher at NC State who is senior author of a recent paper on the improved technique.
Interesting applications for such a power detector include wearable THz sensors for healthcare and flexible THz detector arrays for high resolution interferometric imaging to be used in biomedical and security imaging, remote process control, material inspection and profiling and packaging inspection.
This technology has revolutionised optics in recent years, with many applications in imaging and holography, adaptive optics and wavefront shaping of light through opaque media.
Recent advances in both imaging technology and high throughput automation have led to the development of high - content screening (HCS) and integrated liquid handling systems that have broad application in academia and industry.
«Our findings for this study provide important starting points for using small molecule imaging techniques to explore MAO - B further at the organism level, and in fact, opens up future prospects for non-invasive imaging - based diagnostic applications,» said Dr Li Lin, the first author of the paper and a post-doctoral fellow in Prof Yao's lab.
This strategy led to the discovery of NIR luminescence and also paves the way for other types of nanoparticle alloys that are useful not only in imaging, but in applications like catalysis for the industrial - scale conversion of fossil fuels into fine chemicals.
«This tiny device could have other exciting uses including in anti-counterfeit devices in bank notes, imaging cells for medical applications and holograms.»
While on one hand, there is significant potential in the application of nanoparticles in enhancing heat transfer for tumor ablation and targeted drug delivery, there is also much promise in improving imaging and diagnostic protocols using them.
Combining these two elements to make a compact frequency comb generating long - wavelength light in the terahertz range can produce a useful source of radiation for a variety of applications in imaging, diagnostics, remote sensing, and identifying molecular «fingerprints» of extremely complex molecules.
The technique is currently being tested in a number of clinical applications, including imaging breast tumors, detecting skin cancer, and tracking blood oxygenation in tissues.
This process could lead to a plethora of new devices with a wide variety of applications in optics and biomedical imaging, Sun said.
The easy - to - build lens could lead to improved photolithography, nanoscale manipulation and manufacturing, and even high - resolution three - dimensional imaging, as well as a number of as - yet - unimagined applications in a diverse range of fields.
The solitons form the extremely broadband laser light that is indispensable as a supercontinuum light source for applications in medical imaging, measurement technology, and spectroscopy.
Imaging at the nanoscale is important to a plethora of modern applications in materials science, physics, biology, medicine and other fields.
Moreover, because of limitations inherent in their design, metamaterials of this type designed for infrared and visible wavelengths have, so far, been shown to impart a negative index of refraction to light that is traveling only in a certain direction, making them hard to use for imaging and other applications that rely on refracted light.
The basic problem of separating signals is fundamental, appearing in a broad spectrum of applications ranging from brain imaging analysis to development of intelligent robots.
While the system will be subjected to further research to improve its performance towards the theoretical limit, it already shows considerable promise for use in a wide range of applications, including ultra-fast imaging with high - intensity X-rays and high - resolution full - field X-ray fluorescence imaging.
That plan is reflected in the title of a 26 February request for grant applications, from NICHD and the National Institute of Biomedical Imaging and Bioengineering (NIBIB), that calls for «Paradigm - Shifting Innovations» in how to assess the human placenta.
This mirror structure may also find use in other systems, with potential applications that include focusing and imaging optics for synchrotron radiation X-rays and X-ray-free electron lasers.
Specifically, the imaging agents developed in the laboratory for use in fluorescence molecular tomography, are now even being translated into the clinic for human diagnostic applications.
Magnets are used in many industrial and technological applications, including power generation in wind turbines, memory storage in hard disks and in medical imaging.
A novel metamaterial enables a fast, efficient and high - fidelity terahertz radiation imaging system capable of manipulating the stubborn electromagnetic waves, advancing a technology with potential applications in medical and security imaging, a team led by Boston College researchers reports in the online edition of the journal Nature Photonics.
CMIIT's mission is to engage the molecular imaging community and leverage the SNMMI infrastructure to advance the adoption of emerging molecular imaging technologies and probes in preclinical and clinical applications.
Among the nanomaterials under consideration for application in neuronal action potential imaging are quantum dots (QDs)-- crystalline semiconductor nanomaterials possessing a number of advantageous photophysical attributes.
His research interests include medicinal chemistry, nanotechnology, drug delivery, cell trafficking and molecular imaging for theranostic applications in cancer and Alzheimer's disease (AD).
Filling this gap holds promise for the translation of the high content information obtainable by molecular imaging in individual cells into functional imaging amenable to clinical applications.
Nolting DD, Gore JC and Pham W. Near - Infrared Dyes: Probe Development and Applications in Optical Molecular Imaging.
Dr. Gore's research program is focused on the development and application of imaging, especially magnetic resonance imaging and spectroscopy techniques, in clinical and basic science.