Like a high - powered magnet at Tallahassee's High
Magnetic Field Laboratory, Florida's capital city has been sucking in new residents by the droves.
Like a high - powered magnet at Tallahassee's High
Magnetic Field Laboratory, Florida's capital city has been sucking in new residents by the droves.
Presenter: Thierry Dubroca, Ph.D., Postdoctoral Associate, National High
Magnetic Field Laboratory and Florida State University
Abstract: Oxford Instruments is delighted to congratulate our partners at the National High
Magnetic Field Laboratory (NHMFL) on the successful demonstration of a 32 Tesla all - superconducting user magnet on 8th of December 2017.
Scott Crooker from the Los Alamos National Laboratory's National High
Magnetic Field Laboratory demonstrates magnetic principles to students from Santa Fe Indian School at the recent STEM Mentoring Café at Bradbury Science Museum in Los Alamos, N.M..
A team of materials scientists and physicists from the DOE's Argonne National Laboratory, the National High
Magnetic Field Laboratory and the National...
Following a PhD in transmission electron microscopy at Cambridge, she spent three years at the National High
Magnetic Field Laboratory at Los Alamos looking at the behaviour of the low temperature phases of strongly correlated electron systems.
Research underway at the National High
Magnetic Field Laboratory may one day answer those questions — and perhaps even help pave the way for future colonization of the Red Planet.
National High
Magnetic Field Laboratory and Department of Biological Science, Florida State University, Tallahassee, FL 32310, USA.
Through experiments involving almost two dozen researchers across the FSU campus and the FSU - headquartered National High
Magnetic Field Laboratory, Albrecht - Schmitt made compounds out of berkelium that started exhibiting unusual chemistry.
The electrical measurements revealing the signature half - integer quantum Hall effect were performed at the National Science Foundation's National High
Magnetic Field Laboratory.
Robert Bossio is currently working on his Ph.D. in analytical chemistry / high resolution - high mass accuracy mass spectrometry at Florida State University under Alan Marshall at the National High
Magnetic Field Laboratory.
Yan - Yan Hu, PhD Florida State University Department of Chemistry and Biochemistry National High
Magnetic Field Laboratory Website
The team measured the hardness of the beta form of the crystal in conjunction with colleagues at Texas A&M University's Turbomachinery Laboratory and at the National High
Magnetic Field Laboratory at Florida State University, Morosan and Svanidze also performed other comparisons with titanium.
Etched and imaged in a FESEM by Maxime Matras; color processing by Peter J. Lee, National High
Magnetic Field Laboratory Applied Superconductivity Center
Not exact matches
Developed turbulence and nonlinear amplification of
magnetic fields in
laboratory and astrophysical plasmas
When Earth's
magnetic field will flip remains uncertain (Image: G. Glatzmaier, Los Alamos National
Laboratory / P. Roberts, UCLA / SPL)
The Axion Dark Matter eXperiment, started at Lawrence Livermore National
Laboratory before moving to the University of Washington, seeks the subtle signatures — just a trillionth of a trillionth of a watt — left by axions as they're snagged by a strong
magnetic field.
The MN - induced force propelling the spacecraft has been demonstrated in
laboratory experiments and originates in the plasma inducing the
magnetic field in the opposite direction to the one applied.
By contrast, scientists in terrestrial
laboratories often see the
magnetic field decreased by the plasma due to its diamagnetism.
It is not currently possible to reproduce this distinctive turbulence either by
laboratory experiments or by computer simulations.2 Until now, it was therefore impossible for geophysicists to determine its role with regard to the
magnetic field.
For about a minute, running on half a hair dryer's worth of power, the orbiter - cum - probe beamed direct measures of the planet's atmosphere, along with final probes of its gravity and
magnetic field, to mission control at the Jet Propulsion
Laboratory (JPL) in Pasadena, California.
To do so, they heated the samples up, then cooled them down again in a
laboratory - controlled
magnetic field.
The way reconnection disturbs terrestrial power grids is complex but, in essence, the process mimics what happens in electric generators, where a fluctuating
magnetic field (usually a moving magnet) produces a current in a coil of wire, says Adam Szabo, director of NASA's Heliophysics
Laboratory.
Step into a
laboratory where scientists toss out their instruments after a single use, where a tissue will block
magnetic fields, and where drinking a sulfur and champagne mixture called «sulphagne» lets you shoot deadly lasers from your eyes.
Physicists at the U.S. Department of Energy's Ames
Laboratory compared similar materials and returned to a long - established rule of electron movement in their quest to explain the phenomenon of extremely large magnetoresistance (XMR), in which the application of a
magnetic field to a material results in a remarkably large change in electrical resistance.
In a
laboratory at Tohoku University, researchers Kazunori Takahashi, Christine Charles, Rod W Boswell and Akira Ando have performed a specially designed experiment, which allows the electric
field - trapping electrons in the system to be removed resulting in the electrons solely interacting with the expanding
magnetic field.
But on an early fly - by in February 2005, the spacecraft's magnetometer «sensed something unusual going on with its
magnetic field», says Cassini project scientist Linda Spilker of the Jet Propulsion
Laboratory (JPL) in Pasadena, California.
Ruth Bamford of the Rutherford Appleton
Laboratory, UK, and colleagues have now shown how such
magnetic fields might work, which could help spaceship builders devise
magnetic shielding to protect astronauts from harmful radiation.
A team of scientists working at the U.S. Department of Energy's (DOE) Argonne National
Laboratory and led by Northern Illinois University physicist and Argonne materials scientist Zhili Xiao has created a new material, called «rewritable
magnetic charge ice,» that permits an unprecedented degree of control over local
magnetic fields and could pave the way for new computing technologies.
g (acceleration due to gravity) G (gravitational constant) G star G1.9 +0.3 gabbro Gabor, Dennis (1900 — 1979) Gabriel's Horn Gacrux (Gamma Crucis) gadolinium Gagarin, Yuri Alexeyevich (1934 — 1968) Gagarin Cosmonaut Training Center GAIA Gaia Hypothesis galactic anticenter galactic bulge galactic center Galactic Club galactic coordinates galactic disk galactic empire galactic equator galactic habitable zone galactic halo galactic
magnetic field galactic noise galactic plane galactic rotation galactose Galatea GALAXIES galaxy galaxy cannibalism galaxy classification galaxy formation galaxy interaction galaxy merger Galaxy, The Galaxy satellite series Gale Crater Galen (c. AD 129 — c. 216) galena GALEX (Galaxy Evolution Explorer) Galilean satellites Galilean telescope Galileo (Galilei, Galileo)(1564 — 1642) Galileo (spacecraft) Galileo Europa Mission (GEM) Galileo satellite navigation system gall gall bladder Galle, Johann Gottfried (1812 — 1910) gallic acid gallium gallon gallstone Galois, Évariste (1811 — 1832) Galois theory Galton, Francis (1822 — 1911) Galvani, Luigi (1737 — 1798) galvanizing galvanometer game game theory GAMES AND PUZZLES gamete gametophyte Gamma (Soviet orbiting telescope) Gamma Cassiopeiae Gamma Cassiopeiae star gamma function gamma globulin gamma rays Gamma Velorum gamma - ray burst gamma - ray satellites Gamow, George (1904 — 1968) ganglion gangrene Ganswindt, Hermann (1856 — 1934) Ganymede «garbage theory», of the origin of life Gardner, Martin (1914 — 2010) Garneau, Marc (1949 ---RRB- garnet Garnet Star (Mu Cephei) Garnet Star Nebula (IC 1396) garnierite Garriott, Owen K. (1930 ---RRB- Garuda gas gas chromatography gas constant gas giant gas laws gas - bounded nebula gaseous nebula gaseous propellant gaseous - propellant rocket engine gasoline Gaspra (minor planet 951) Gassendi, Pierre (1592 — 1655) gastric juice gastrin gastrocnemius gastroenteritis gastrointestinal tract gastropod gastrulation Gatewood, George D. (1940 ---RRB- Gauer - Henry reflex gauge boson gauge theory gauss (unit) Gauss, Carl Friedrich (1777 — 1855) Gaussian distribution Gay - Lussac, Joseph Louis (1778 — 1850) GCOM (Global Change Observing Mission) Geber (c. 720 — 815) gegenschein Geiger, Hans Wilhelm (1882 — 1945) Geiger - Müller counter Giessler tube gel gelatin Gelfond's theorem Gell - Mann, Murray (1929 ---RRB- GEM «gemination,» of martian canals Geminga Gemini (constellation) Gemini Observatory Gemini Project Gemini - Titan II gemstone gene gene expression gene mapping gene pool gene therapy gene transfer General Catalogue of Variable Stars (GCVS) general precession general theory of relativity generation ship generator Genesis (inflatable orbiting module) Genesis (sample return probe) genetic code genetic counseling genetic disorder genetic drift genetic engineering genetic marker genetic material genetic pool genetic recombination genetics GENETICS AND HEREDITY Geneva Extrasolar Planet Search Program genome genome, interstellar transmission of genotype gentian violet genus geoboard geode geodesic geodesy geodesy satellites geodetic precession Geographos (minor planet 1620) geography GEOGRAPHY Geo - IK geologic time geology GEOLOGY AND PLANETARY SCIENCE geomagnetic
field geomagnetic storm geometric mean geometric sequence geometry GEOMETRY geometry puzzles geophysics GEOS (Geodetic Earth Orbiting Satellite) Geosat geostationary orbit geosynchronous orbit geosynchronous / geostationary transfer orbit (GTO) geosyncline Geotail (satellite) geotropism germ germ cells Germain, Sophie (1776 — 1831) German Rocket Society germanium germination Gesner, Konrad von (1516 — 1565) gestation Get Off the Earth puzzle Gettier problem geyser g - force GFO (Geosat Follow - On) GFZ - 1 (GeoForschungsZentrum) ghost crater Ghost Head Nebula (NGC 2080) ghost image Ghost of Jupiter (NGC 3242) Giacconi, Riccardo (1931 ---RRB- Giacobini - Zinner, Comet (Comet 21P /) Giaever, Ivar (1929 ---RRB- giant branch Giant Magellan Telescope giant molecular cloud giant planet giant star Giant's Causeway Giauque, William Francis (1895 — 1982) gibberellins Gibbs, Josiah Willard (1839 — 1903) Gibbs free energy Gibson, Edward G. (1936 ---RRB- Gilbert, William (1544 — 1603) gilbert (unit) Gilbreath's conjecture gilding gill gill (unit) Gilruth, Robert R. (1913 — 2000) gilsonite gimbal Ginga ginkgo Giotto (ESA Halley probe) GIRD (Gruppa Isutcheniya Reaktivnovo Dvisheniya) girder glacial drift glacial groove glacier gland Glaser, Donald Arthur (1926 — 2013) Glashow, Sheldon (1932 ---RRB- glass GLAST (Gamma - ray Large Area Space Telescope) Glauber, Johann Rudolf (1607 — 1670) glaucoma glauconite Glenn, John Herschel, Jr. (1921 ---RRB- Glenn Research Center Glennan, T (homas) Keith (1905 — 1995) glenoid cavity glia glial cell glider Gliese 229B Gliese 581 Gliese 67 (HD 10307, HIP 7918) Gliese 710 (HD 168442, HIP 89825) Gliese 86 Gliese 876 Gliese Catalogue glioma glissette glitch Global Astrometric Interferometer for Astrophysics (GAIA) Global Oscillation Network Group (GONG) Globalstar globe Globigerina globular cluster globular proteins globule globulin globus pallidus GLOMR (Global Low Orbiting Message Relay) GLONASS (Global Navigation Satellite System) glossopharyngeal nerve Gloster E. 28/39 glottis glow - worm glucagon glucocorticoid glucose glucoside gluon Glushko, Valentin Petrovitch (1908 — 1989) glutamic acid glutamine gluten gluteus maximus glycerol glycine glycogen glycol glycolysis glycoprotein glycosidic bond glycosuria glyoxysome GMS (Geosynchronous Meteorological Satellite) GMT (Greenwich Mean Time) Gnathostomata gneiss Go Go, No - go goblet cell GOCE (Gravity
field and steady - state Ocean Circulation Explorer) God Goddard, Robert Hutchings (1882 — 1945) Goddard Institute for Space Studies Goddard Space Flight Center Gödel, Kurt (1906 — 1978) Gödel universe Godwin, Francis (1562 — 1633) GOES (Geostationary Operational Environmental Satellite) goethite goiter gold Gold, Thomas (1920 — 2004) Goldbach conjecture golden ratio (phi) Goldin, Daniel Saul (1940 ---RRB- gold - leaf electroscope Goldstone Tracking Facility Golgi, Camillo (1844 — 1926) Golgi apparatus Golomb, Solomon W. (1932 — 2016) golygon GOMS (Geostationary Operational Meteorological Satellite) gonad gonadotrophin - releasing hormone gonadotrophins Gondwanaland Gonets goniatite goniometer gonorrhea Goodricke, John (1764 — 1786) googol Gordian Knot Gordon, Richard Francis, Jr. (1929 — 2017) Gore, John Ellard (1845 — 1910) gorge gorilla Gorizont Gott loop Goudsmit, Samuel Abraham (1902 — 1978) Gould, Benjamin Apthorp (1824 — 1896) Gould, Stephen Jay (1941 — 2002) Gould Belt gout governor GPS (Global Positioning System) Graaf, Regnier de (1641 — 1673) Graafian follicle GRAB graben GRACE (Gravity Recovery and Climate Experiment) graceful graph gradient Graham, Ronald (1935 ---RRB- Graham, Thomas (1805 — 1869) Graham's law of diffusion Graham's number GRAIL (Gravity Recovery and Interior
Laboratory) grain (cereal) grain (unit) gram gram - atom Gramme, Zénobe Théophile (1826 — 1901) gramophone Gram's stain Gran Telescopio Canarias (GTC) Granat Grand Tour grand unified theory (GUT) Grandfather Paradox Granit, Ragnar Arthur (1900 — 1991) granite granulation granule granulocyte graph graph theory graphene graphite GRAPHS AND GRAPH THEORY graptolite grass grassland gravel graveyard orbit gravimeter gravimetric analysis Gravitational Biology Facility gravitational collapse gravitational constant (G) gravitational instability gravitational lens gravitational life gravitational lock gravitational microlensing GRAVITATIONAL PHYSICS gravitational slingshot effect gravitational waves graviton gravity gravity gradient gravity gradient stabilization Gravity Probe A Gravity Probe B gravity - assist gray (Gy) gray goo gray matter grazing - incidence telescope Great Annihilator Great Attractor great circle Great Comets Great Hercules Cluster (M13, NGC 6205) Great Monad Great Observatories Great Red Spot Great Rift (in Milky Way) Great Rift Valley Great Square of Pegasus Great Wall greater omentum greatest elongation Green, George (1793 — 1841) Green, Nathaniel E. Green, Thomas Hill (1836 — 1882) green algae Green Bank Green Bank conference (1961) Green Bank Telescope green flash greenhouse effect greenhouse gases Green's theorem Greg, Percy (1836 — 1889) Gregorian calendar Grelling's paradox Griffith, George (1857 — 1906) Griffith Observatory Grignard, François Auguste Victor (1871 — 1935) Grignard reagent grike Grimaldi, Francesco Maria (1618 — 1663) Grissom, Virgil (1926 — 1967) grit gritstone Groom Lake Groombridge 34 Groombridge Catalogue gross ground, electrical ground state ground - track group group theory GROUPS AND GROUP THEORY growing season growth growth hormone growth hormone - releasing hormone growth plate Grudge, Project Gruithuisen, Franz von Paula (1774 — 1852) Grus (constellation) Grus Quartet (NGC 7552, NGC 7582, NGC 7590, and NGC 7599) GSLV (Geosynchronous Satellite Launch Vehicle) g - suit G - type asteroid Guericke, Otto von (1602 — 1686) guanine Guiana Space Centre guidance, inertial Guide Star Catalog (GSC) guided missile guided missiles, postwar development Guillaume, Charles Édouard (1861 — 1938) Gulf Stream (ocean current) Gulfstream (jet plane) Gullstrand, Allvar (1862 — 1930) gum Gum Nebula gun metal gunpowder Gurwin Gusev Crater gut Gutenberg, Johann (c. 1400 — 1468) Guy, Richard Kenneth (1916 ---RRB- guyot Guzman Prize gymnosperm gynecology gynoecium gypsum gyrocompass gyrofrequency gyropilot gyroscope gyrostabilizer Gyulbudagian's Nebula (HH215)
We study quantum transport in our low temperature
laboratory where we can cool 2DEGs to T = 10mK at high
magnetic fields.
The Princeton Plasma Physics
Laboratory, funded by the U.S. Department of Energy and managed by Princeton University, is located at 100 Stellarator Road off Campus Drive on Princeton University's Forrestal Campus in Plainsboro, N.J. PPPL researchers collaborate with researchers around the globe in the
field of plasma science, the study of ultra-hot, charged gases, to develop practical solutions for the creation of
magnetic fusion energy as an energy source for the world.
The MRX device produces
laboratory studies of
magnetic reconnection, the convergence and violent separation of
magnetic field lines in plasma, the state of matter that consists of free electrons and atomic nuclei.
Physicist Sam Lazerson of the US Department of Energy's Princeton Plasma Physics
Laboratory has teamed with German scientists to confirm that the Wendelstein 7 - X fusion energy device called a stellarator in Greifswald, Germany, produces high - quality
magnetic fields that are consistent with their complex design.
The cause, according to a theory advanced by PPPL physicist David Gates and colleagues at the
Laboratory, lies in the tendency of bubble - like islands that form in the plasma that fuels fusion reactions to shed heat and grow exponentially — a runaway growth that disrupts the crucial current that completes the
magnetic field that holds the plasma together.
PPPL studies how to recreate this process in the
laboratory by heating plasma to tens of millions of degrees Celsius and confining it in powerful
magnetic fields.
Importantly, this probe could then be removed from the
magnetic field where it was created, stored anywhere in the
laboratory before being transported back into the magnet where its strong signals can be observed.
«Nature has created a unique
laboratory where there are
magnetic fields far stronger than anything that can be created here on Earth.
The method contrasts with the research done at PPPL and other
laboratories, which controls plasma with
magnetic fields and heats it to fusion temperatures in doughnut - shaped devices called tokamaks.
The paper by Goldston, a top scientist at the U.S. Department of Energy's Princeton Plasma Physics
Laboratory (PPPL) and former director of the
Laboratory, showed that the width of the scrape - off layer depends on how rapidly plasma moves across the
magnetic field — due to well - understood classical «drifts» — as it flows into the divertor chamber.
Technologies available in our hospital include but are not limited to: high
field magnetic resonance imaging (MRI), computerized tomography (CT), digital radiography, ultrasonography, complete endoscopy services, cardiac catheterization
laboratory, on - site diagnostic
laboratory services and full service surgical suites.
For the work's presentation at SFMOMA, Kubisch compiled a sequence of recordings of
magnetic fields from various sites, including a security room in the basement of the museum; nearby locations such as Yerba Buena Gardens, a parking garage on Natoma Street, and Epicenter, a city - run space devoted to seismic safety; the Hoover Dam in Nevada; a power plant in Finland; server rooms in Austria, Germany, and Hong Kong; a Louis Vuitton store in Paris; and the
Laboratory for Antiquated Video Systems at ZKM Center for Art and Media in Karlsruhe, Germany.
Early this year I came across this: Jean Dickey of NASA's Jet Propulsion
Laboratory, Pasadena: One possibility is the movements of Earth's core (where Earth's
magnetic field originates) might disturb Earth's
magnetic shielding of charged - particle (i.e., cosmic ray) fluxes that have been hypothesized to affect the formation of clouds.
A large number of such data have been produced over the past decades in paleomagnetic
laboratories around the world, so that the amount of available data is getting large enough to allow for global inversion models of the Holocene
magnetic field.
Information about the
magnetic field evolution prior to the times of direct observations is determined in
laboratory procedures from archeo - and paleomagnetic material.
[23]... [T] he evidence is that much of this equipment is commonly used in university science
laboratories and in other settings involving the production of
magnetic fields using electric currents through coiled wires.