Sentences with phrase «ion technology for»

Wahl Clipper Corporation has a number of options for practical home grooming at a wide range of prices, including clippers intended for home use — from a rechargeable clipper using lithium ion technology for a 90 - minute run time to a cord / cordless version.

The foreign nature of the equipment explains why ion technology for quantum computing hasn't taken off yet, Monroe says.

Apple and other smartphone makers use a technology called lithium ion for their batteries.

For the power technology, he licensed a prototype and focused on developing software to keep the 6,831 lithium ion batteries cool at high speeds (thus avoiding the fate of an overheated Dell laptop).

The market for lithium ion batteries — the technology used in Tesla's Powerwall — is expected to exceed US$ 30 billion by 2020, according to Research and Markets.

Solid state batteries, which Dyson has been developing for years, are a step change beyond lithium ion technology, with the ability to drive further and charge faster.

Accion Systems is developing revolutionary ion beam propulsion technologies for satellites, that are light, powerful, and affordable.

For more than 50 years, Dow has been a leading supplier of ion exchange resins and resin technology, as well as advanced water purification and separation technologies.

CuTEC ® Copper Ion Technology is permanently incorporated into the fibers, providing exceptional ANTI-ODOR and ANTIBACTERIAL properties for healthier looking skin.

O - ion's B - 1000 uses powerful ionization technology to clean and sanitize the air in your home or office, making it a fantastic purifier for pet owners and anybody who wants to breathe fresh air.

The existing process for manufacturing lithium - ion batteries, he says, has hardly changed in the two decades since the technology was invented, and is inefficient, with more steps and components than are really needed.

Understanding the nature of radiation damage in materials is of paramount importance for controlling the safety of nuclear reactors, using ion implantation in semiconductor technology, and designing reliable devices in space.

«As far as we can tell, our technologies with both the silicon anode and sulfur cathode are among the most cost - effective solutions and therefore show promise for commercialization to make the next - generation of lithium - ion batteries to power portable electronics and electric vehicles,» said USC Viterbi graduate student Rong.

Louis Lanzerotti of the New Jersey Institute of Technology is principal investigator for the RBSPICE (Radiation Belt Ion Composition Experiment) instrument, and one of the pioneers of radiation belt physics research.

«Manufacturers of rechargeable batteries are building on the proven lithium - ion technology, which has been deployed in mobile devices like laptops and cell phones for many years,» reports TUM researcher Michael Metzger.

NREL's work was supported by the Energy Department's Vehicle Technology Office under the Battery for Advanced Transportation Technologies (BATT) program, which focuses on reducing the cost and improving the performance and durability of the lithium - ion batteries that power electric vehicles.

The new technology is designed for conventional lithium - ion batteries now used in billions of cellphones, laptops and other electronic devices, as well as a growing number of cars and airplanes.

Rechargeable lithium metal batteries have been known for four decades to offer energy storage capabilities far superior to today's workhorse lithium - ion technology that powers our smartphones and laptops.

Lithium - ion technologies make up a large part of the proceedings because energy storage is a crucial enabling technology for clean energy systems, such as powering electric vehicles and smoothing out electricity from wind and solar generators.

Scientists at the Massachusetts Institute of Technology (M.I.T.) report in Nature today that they devised a way for lithium ions in a battery to zip in and out about 100 times faster than previously demonstrated.

The research into quantum dots containing single magnetic ions was funded with grants from the Polish National Science Centre and the Polish National Centre for Research and Development, as well as project funds from the Centre for Preclinical Research and Technology.

Currently the most important technology for these applications is the lithium - ion battery technology: but the technology is expensive and contains a flammable liquid, which may represent a safety hazard, when the battery is abused.

They will also open new opportunities for the improvement of existing, and the design of new, lithium - ion technologies.»

James Greenberger, founder of the National Alliance for Advanced Transportation Batteries, which promotes lithium - ion battery technology, was «disappointed» that his own organization did not get funding, but says that the recipients are all «first - rate companies that can move this technology forward».

When we crunched the numbers, we found that electric propulsion — via an ion drive or related technologies — could dramatically reduce the launch mass required for human missions to asteroids and Mars.

These advantages make lithium - ion batteries a key technology for electromobility.

Researchers at the Massachusetts Institute of Technology have come one step closer to replacing the lithium - ion batteries that power phones, laptops and electric cars with a device that stores far more energy for the same weight.

Singapore's Agency for Science, Technology and Research (A * STAR) researchers have demonstrated that electrodes made from tellurium can improve the energy storage and power output of rechargeable lithium - ion batteries [1].

It measures glucose, lactate, potassium and sodium ions, and can transmit the data via Bluetooth wireless technology for more than an hour before it needs recharging.

This discovery could be a pivotal development for energy storage, water treatment and alternative energy production technologies, which all involve ions packing into nanoporous materials.

We will present the selected technologies that include silver nanowires transparent conductive films, silicon anode for Li - ion batteries and 3D micro batteries.

Grierson received the Kaul Foundation Prize for Excellence in Plasma Physics Research and Technology Development for his groundbreaking measurements of the flow of the main atomic nuclei, or ions, in the DIII - D tokamak.

Batteries with multivalent cathodes (which have multiple electrons per mobile ion available for charge transfer) are promising candidates for reducing cost and achieving higher energy density than that available with current lithium - ion technology.

Group 1: Materials, Resonators, & Resonator Circuits A. Fundamental Properties of Materials B. Micro - and Macro-Fabrication Technology for Resonators and Filters C. Theory, Design, and Performance of Resonators and Filters, including BAW, FBAR, MEMS, NEMS, SAW, and others D. Reconfigurable Frequency Control Circuits, e.g., Arrays, Channelizers Group 2: Oscillators, Synthesizers, Noise, & Circuit Techniques A. Oscillators — BAW, MEMS, and SAW B. Oscillators - Microwave to Optical C. Heterogeneously Integrated Miniature Oscillators, e.g., Single - Chip D. Synthesizers, Multi-Resonator Oscillators, and Other Circuitry E. Noise Phenomena and Aging F. Measurements and Specifications G. Timing Error in Digital Systems and Applications Group 3: Microwave Frequency Standards A. Microwave Atomic Frequency Standards B. Atomic Clocks for Space Applications C. Miniature and Chip Scale Atomic Clocks and other instrumentation D. Fundamental Physics, Fundamental Constants, & Other Applications Group 4: Sensors & Transducers A. Resonant Chemical Sensors B. Resonant Physical Sensors C. Vibratory and Atomic Gyroscopes & Magnetometers D. BAW, SAW, FBAR, and MEMS Sensors E. Transducers F. Sensor Instrumentation Group 5: Timekeeping, Time and Frequency Transfer, GNSS Applications A. TAI and Time Scales, Time and Frequency Transfer, and Algorithms B. Satellite Navigation (Galileo, GPS,...) C.Telecommunications Network Synchronization, RF Fiber Frequency Distribution D. All - optical fiber frequency transfer E. Optical free - space frequency transfer F. Frequency and Time Distribution and Calibration Services Group 6: Optical Frequency Standards and Applications A. Optical Ion and Neutral Atom Clocks B. Optical Frequency Combs and Frequency Measurements C. Ultrastable Laser Sources and Optical Frequency Distribution D. Ultrastable Optical to Microwave Conversion E. Fundamental Physics, Fundamental Constants, and Other Applications

«The Norwegian energy firm plans to deploy an onshore 1 megawatt - hour lithium - ion battery system («Batwind») in late 2018, to evaluate the potential for energy storage to complement the offshore wind technology.»

«In addition, we are proud to offer complementary technologies such as PacBio and Ion Torrent for diverse applications.»

«If we can maximize the cycling performance and efficiency of these low - cost and abundant iron fluoride lithium ion battery materials, we could advance large - scale renewable energy storage technologies for electric cars and microgrids,» he says.

We work with a wide variety of technologies, including NV centers in diamond, trapped ions and optical cavities, by developing theoretical proposals whose realization and application for example in biology we are pursuing in collaboration with national and international groups and interacting very closely with the experimental groups in Ulm.

Michael Roukes, a physicist developing nanoscale tools for bioscience and medicine, says «Room at the Bottom» anticipated a host of important technologies and scientific fields, including spin electronics («spintronics»), microelectromechanical systems (MEMS), electron - beam and ion - beam fabrication and much more.

Berkey Biofilm Drops work by incorporating multiple barrier processes for inhibiting the growth and regrowth of biofilms, utilizing natural mineral ions of copper and silver in an ion technology along with other additives and complexants to synergistically aid in the control and precipitation of calcium, iron, minerals and scale where biofilm bacteria attach, form, feed and breed.

The brand's patented T3 SoftAire technology ensures ion - enriched air to dry large sections quickly and efficiently, with a cool shot button for when things get heated.

Audi says it will produce the batteries itself, using «a newly developed lithium - ion technology» designed specifically for the sports car.

The Japanese auto maker is tiptoeing along in the electrification movement with its upcoming plug - in Prius hybrid but remains among the more cautious auto makers when it comes to lithium - ion battery technology and the outlook for EVs.

Pushing the boundaries of high - performance technology today means something very different from what that original car embodied, so the formula for the New Sports eXperience is considerably different in the 2017 Acura NSX: The basics include a hybrid powertrain made up of three electric motors, a lithium - ion battery pack, a mid-mounted twin - turbocharged V - 6 engine and a dual - clutch nine - speed automatic transmission.

Pushed on the potential use of a different battery type, Green said that he sees lithium - ion as the primary tech for the time being, though he sees emerging technologies such as solid - state batteries having potential in the distant future.

Kristensen also pointed out that while Audi and Toyota have both moved to lithium - ion hybrid systems for 2016, Porsche has had three years of development with the technology, and as a result, has the advantage of experience — as well as what appears to be the best pace.

Recently developed by a team of researchers at the Samsung Advanced Institute of Technology (SAIT), this «graphene ball» was utilized for both the anode protective layer and cathode materials in lithium - ion batteries and this ensured a 45 % increase in capacity and 5X faster charging speeds than standard lithium - ion batteries.

The new race car is still a hybrid that relies on diesel engine technology, but rather than stick with a mechanical flywheel for energy storage the R18 will switch over to lithium - ion batteries.

Moers went onto reveal that AMG is developing its own battery technology for its new powertrain that is lighter than conventional lithium - ion battery cells.

Those of you disappointed by the lack of PHEV option, read: MIT Technology Review Tuesday, January 13, 2009 Toyota to Deliver Plug - In Hybrids The new Prius is designed so that its battery pack can be swapped out for a plug - in lithium - ion battery.