21. Rock-Magnetism Reference List S Saad, A.H., Magnetic Properties Of Rock-Magnetis on experimental and theoretical research in magnetism, the properties and synthesis of new magnetic materials, and http://www.geo.umn.edu/orgs/irm/referencelist/refs-s.pdf

22. Network On Fundamental Magnetism And Properties Of Materials Translate this page http://www.fis.unipr.it/~derenzi/amoretti/amoret.html

23. NASAexplores 9-12 Lesson Properties Of Magnetism (Teacher Sheets Sling Shot to Space. properties of magnetism. Lesson 1 of 3. Grade Level 9 12. Sling Shot to Space. properties of magnetism. Teacher Sheets. Objective. http://www.nasaexplores.com/lessons/01-027/9-12_1-t.html

24. NASAexplores 9-12 Lesson Properties Of Magnetism (Student Sheets Sling Shot to Space. properties of magnetism. properties of magnetism. Student(s)Name _ Period _ Date . http://www.nasaexplores.com/lessons/01-027/9-12_1.html

25. Magnetism I: Structure And Magnetic Properties Of Materials Programme Session magnetism I Structure and Magnetic properties of Materials(MAGa). 21 December 1999 Chair tbc. Location New Building 1. http://www.iop.org/IOP/Confs/CMMP99/programme/MAGa.3_prog.html

www.iop.org Contact us Programme Index: IOP Home Session: Magnetism I: Structure and Magnetic Properties of Materials (MAGa) 21 December 1999 Chair: tbc Location: New Building 1 MAGa.1 (I) Effect of Stacking Faults on Magnetic Properties of Cobalt Alloy Thin Films H Laidler, L Holloway University of Exeter, UK University of Wales, Bangor, UK MAGa.2 (I) Modelling of Structural Effects in Magnetic Thin Films N. S. Walmsley University of Wales, U.K. MAGa.3 (I) Magnetism of rare-earth superlattices J P Goff, R S Sarthour , R C C Ward , M R Wells , D F McMorrow , F Yakhou , A Stunault University of Liverpool, UK University of Oxford, UK Risoe National Laboratory, Denmark European Synchrotron Radiation Facility, France MAGa.4 (I) A Quantitative Study of magnetic Domain Correlations in Antiferromagnetically Coupled Multilayers S Langridge, J Schmalian, C H Marrows , D J Dekadjevi, B J Hickey Rutherford Appleton Laboratory, UK University of Leeds, UK The Web site for physics and physicists from the Institute of Physics Sources Online services Journals Magazines Books ... Events Physics for...

26. Magnetism I: Structure And Magnetic Properties Of Materials Programme Home. Session magnetism I Structure and Magnetic properties of Materials(MAGa). 21 December 1999 Location Belvoir Cityside Suite. http://www.iop.org/IOP/Confs/CMMP99/programme/MAGa.P2_prog.html

www.iop.org Contact us Programme Index: IOP Home Session: Magnetism I: Structure and Magnetic Properties of Materials (MAGa) 21 December 1999 Location: Belvoir Cityside Suite MAGa.1 Using planar Hall effect for investigation of perpendicular anisotropy of a thin ferromagnetic film. F Y Ogrin, S L Lee University of St. Andrews, UK MAGa.2 Orientation Dependent Coercivity Mechanisms in Stressed Martensitic Steels G J Tomka, N Murray , P T Squire , J Gore, J Earl, M G Maylin DERA Farnborough, UK University of Bath, UK MAGa.3 Magnetoresistance of magnetic multilayers in the CPP mode: the effect of the mean free path D Bozec, M A Howson, B J Hickey, S Shatz , N Wiser University of Leeds, U.K. Bar-Ilan University, IL MAGa.4 Particle Size Dependence of the Complex Permeability in the MegaHertz Frequency Range of Soft Magnetic Ferrite/Resin Composites J H Paterson, S McVitie , A D R Phelps University of Strathclyde, UK University of Glasgow, UK MAGa.5 Oxidation of M-P Particles and Subsequent Effect on Switching Field Distribution J A Hutchings, K O'Grady

27. Mineral Gallery - The Magnetic Minerals magnetism as is a magnet on a string that might sway near the specimen. Theseare some of the more common minerals that demonstrate magnetic properties http://mineral.galleries.com/minerals/property/magnetis.htm

THE MAGNETIC MINERALS MINERALS By Name A list of minerals in alphabetical order By Class Elements, Oxides, Carbonates, etc. Interesting Groupings Gemstones, Birthstones, etc. Physical Properties Keys to identifying minerals The Great Localities Places that have made a name for themselves with mineral collectors Full Text Search Mineral identification by keyword searching OTHER PROPERTIES: Color Luster Diaphaneity Crystal Systems ... Striations radioactivity Magnetism Odor Feel Taste ... Solubility Electrical properties Reaction to acids Thermal properties Associated Minerals Notable Localities Phantoms Inclusions ... Pseudomorphs Meteoritic Minerals The minerals that show this property are few. But the property is important because of this fact. Once a specimen is established as magnetic, identification becomes a rather routine exercise. Magnetism occurs when there is an imbalance in the structural arrangement of the iron ions. Iron is found in two principle ionic states called ferrous and ferric ions. The ferrous ion has charge of positive two, ( ); the ferric ion has a charge of positive three, (

28. DANCING WITH ELECTRONS Magnetic Properties Of Thin Films electrons, magnetic moment, surface atomic layer, superconductivity, solid stateproperties, computational materials science, thinlayer magnetism, bulk metals http://www.psc.edu/science/Freeman/Freeman.html

29. Institutional Research Plan A - 7. Magnetism Of Transition Metals, Their Alloys Z. Arnold, magnetism of solid under high pressure, 40 papers, 76.8 impact points,284 citations L. Kraus, magnetic and transport properties of amorphous http://www.fzu.cz/research/cond_systA7.html

Institutional Research Plan A 7. Magnetism of Transition Metals, their Alloys and Compounds Current status Magnetic materials based on transition metals attract world-wide scientific and technical interest both for their unique physical properties and for the constantly increasing number and variety of their recent applications as sensors, attenuators, storage and control elements, etc. This subject will be investigated by a concerted effort of six research groups, from several angles, with various emphasis, and at a number of material structures. The basic common denominator of the general approach will be the experimental and theoretical investigation of magnetic properties of the materials and, in particular, the connection and possibiblity of optimisation of their magnetic properties with the structural, transport, optical, thermal and volume attributes of the studied samples. Methods and equipment used (in the Institute) solid state reaction in defined atmosphere for oxide samples preparation, single crystals by the flux method, nanogranular magnetic films will be deposited in the high vacuum plasma jet reactor

30. Research In Department Of Magnetism magnetism of surfaces and interfaces FMR. Z. Frait, D. Fraitova, Research ofmagnetic properties of surfaces and interfaces of thin films, multilayers and http://www.fzu.cz/departments/magnetism/research.php3

D e p a r t m e n t o f M a g n e t i s m Magnetism of surfaces and interfaces - FMR Z. Frait , D. Fraitova, Research of magnetic properties of surfaces and interfaces of thin films, multilayers and layered structures of metallic ferromagnets. Main aim: to understand the microphysical properties and origin of surface and volume magnetic excitations, interlayer exchange interaction and surface and interface anisotropic energy and their connection to volume parameters. These properties are studied at first place by the method of low-energy spin-wave spectroscopy (ferromagnetic resonance), ferromagnetic antiresonance and topographic spin-electron resonance. Amorphous, nanocrystalline and nanocomposite materials L. Kraus , F. Fendrych, O. Chayka 1. Magnetic and magneto-elastic properties of amorphous and nanocrystalline soft magnetic materials. The connection between magnetic properties (magnetic anisotropy, magnetostriction, hysteresis losses, (delta)E-effect, giant magneto-impedance, etc.) and the microstructure of materials is investigated. 2. Magnetic and electron transport properties of nanogranular composite films prepared by plasma jet technique.

31. Materials, Methods, Microstructure, And Magnetism problems involving microstructure (independent of magnetism), magnetism (independentof microstructure), giant magnetoresistance, and thermal properties. http://www.nersc.gov/research/annrep98/stocks.html

1998 Annual Report Grand Challenge Projects Materials, Methods, Microstructure, and Magnetism G. Malcolm Stocks, Oak Ridge National Laboratory Bruce N. Harmon, Ames Laboratory/Iowa State University Michael Weinert, Brookhaven National Laboratory Figure 1. 512-atom base-centered cubic iron system. The left frame shows the self-consistent field magnetic moments for the atoms, while the right frame shows the corresponding constraining fields. Atom positions are denoted by spheres, magnetic moments by arrows, and constraining fields by cones. (Click either image for larger version.) Research Objectives To develop first-principles quantum mechanical methods for addressing materials problems microscopically, especially the relationship between technical magnetic properties and microstructure. Towards this goal are major problems involving microstructure (independent of magnetism), magnetism (independent of microstructure), giant magneto-resistance, and thermal properties. Computational Approach Accomplishments A new constrained local moment (CLM) theory of non-equilibrium states in metallic magnets has been developed that places a recent proposal of our co-workers at Ames Laboratory for first-principles spin dynamics (SD) on firm theoretical foundations. In SD, non-equilibrium "local moments" (for example, in magnets above the Curie temperature, or in the presence of an external field) evolve from one time step to the next according to a classical equation of motion. As originally formulated, the instantaneous magnetization states that are being evolved were not properly defined within density functional theory. The CLM theory properly formulates SD within constrained density functional theory. Local constraining fields are introduced, the purpose of which is to force the local moments to point in directions required at a particular time step of SD. A general algorithm for finding the constraining fields has been developed.

32. Magnetism - Basic Properties And Quantities Previous slide, Next slide, Back to the first slide, View text version. http://www.eng.abdn.ac.uk/~eng489/eg2558/topic4a/sld004.htm

33. NYU-STEM: Exploring Magnets And Magnetism strategies employed to study magnets and magnetism in these activities provide inquiryopportunities for the student to investigate the properties of magnets http://www.nyu.edu/projects/mstep/lessons/magnets.html

EXPLORING MAGNETS AND MAGNETISM Primary Target Audience: Elementary school teachers, grades 1-5 Secondary Target Audience: Elementary school students, grades 1-5 Workshop Objectives This workshop will introduce the teacher to the an inquiry-based exploration of magnets and magnetism. The primary goal will be to show how students can discover the properties of magnets and magnetic fields. This activity will allow participants to use the science process skills of observation, data collection and recording. Through inference, they will make generalizations based upon their results. At the conclusion of the workshop, participants will be able to: understand that some materials are magnetic and some are not; identify natural magnets and manufactured magnets; test a sample to determine if it is magnetic; understand that magnets contain two opposite poles; understand the concept of the magnetic forces of attraction and repulsion; understand magnetic fields; make a temporary magnet; record data; and infer the magnetic properties of a material. Learning Styles Accommodated by the Workshop Visual: Visual learners will be stimulated by observation of the testing of materials and the magnetic field patterns.

34. Magnetism Research At Trinity College, Dublin magnetism and Spin Electronics at Trinity College, Dublin. Rhian Mari Thomas, Ph.D.Barclay's Capital, London. Magnetic properties of Mixed Valence Manganites, http://www.tcd.ie/Physics/Magnetism/people.html

Magnetism and Spin Electronics at Trinity College, Dublin Home The Group Research Recent ... CINSE Recent Summer Students and Project Students Billy Healy Ireland TCD Kit Perkin Ireland TCD Cormac Toher Ireland TCD Matt Crofton Ireland TCD Sonia Lioret France SUPELEC Paris Sylvain Moreggia France INP Grenoble Sebastien Saint Martino France INSA Toulouse Vytautas Petrauskas Lithuania Vilnius University Lia Costiner USA Somerville High School, Boston Stefan Nawka Germany TU Dresden Robbie Gunning Ireland TCD Jonathan Dudley Ireland TCD Michael Metcalf Ireland TCD David McGovern Ireland TCD Andrew Ireland TCD Aymeric Lai France INP Grenoble Anne Le Gouil France INP Grenoble Christophe De Nardi France INSA Toulouse Guenole Jan France INP Grenoble Sandrine Lhostis France LMGP Grenoble Delphine Gilabert France INSA Toulouse Aoife Hurley Ireland TCD Brendan Doggett Ireland TCD Cian Cullinan Ireland TCD Ryan Gallagher U.S.A. CMU, Pittsburgh Virginie Loup France INP Grenoble Wiebke Hasch Germany INP Grenoble Catherine Tardin France Cachan Germany TU Dresden Thierry Leichle France INSA Toulouse Sandrine Barberan France INP Grenoble Pierre Jubert France INP Grenoble Thomas Brunhes France ENS Paris Claire Tonon France INSA Toulouse Caroline Naty-Duffin France INSA Toulouse John Patchell Ireland TCD Stephanie Corre France UJF Grenoble Alain Marie France INP Grenoble Gareth Hinds Ireland TCD Stephen Cass Ireland TCD Recent M.Sc. and Ph.D. Graduates

35. Division Of Material Physics Home Page systems. *Suzukigrp (Th) (N.Suzuki, M.Shirai, J.Hama) magnetism.properties of systems at extreme conditions. Experimental http://www.mp.es.osaka-u.ac.jp/index-e.html

Division of Material Physics School of Engineering Science, and Graduate School of Engineering Science, Osaka University former "Department of Material Physics, Faculty of Engineering Science, Osaka University" News and Events ! COE Workshop International Workshop on High Resolution Photoemission Spectroscopy of Correlated Electron Systems * WWW-servers of Introducing Research Groups in our Division (Some of the pages are in Japanese. All are experimental operations) Home Pages:(Alphabetial order) [(Ex) : Experimental, (Th) : Theoretical] ====================================================================== Group name (Members of the Group) (see the pages inside for the students) [Study fields ] ====================================================================== Theoretical: Cho-grp (Th) (K.Cho, H.Ishihara, H.Ajiki) [Physics of mesoscopic systems: Interaction between radiation and matters.] *

36. Cat 6: Magnetism Rippard. Cat6.11.4, Session A30. DCOMP/DMP/GMAG Focus Session Theory and Simulationof magnetism and Spin Dependent properties I. Gyorffy. Cat6.11.1, http://www.physics.ohio-state.edu/~wilkins/dcmp/mar03/cat6.html

Cat 6: Magnetism Invited Contributed Monday Invited Contributed Room 18B Contributed Room 18C Contributed Room 18D Contributed Room 19A Contributed Room 11A/B Session A28. GMAG: Focus Session: Magnetic Nanoparticles I. Deshmukh. Session A29. GMAG/DMP: Focus Session: Current-Induced Spin Excitations. Rippard. Session A30. DCOMP/DMP/GMAG: Focus Session: Theory and Simulation of Magnetism and Spin Dependent Properties I. Gyorffy. Session B6. Blrm G. DCMP: Spin-Dependent Transport. Ciorga, Kouwenhoven, Petta, Folk, Pustilnik. Session B7. Room 17A DCMP: Cooperative Phenomena Frustrated Magnets. Shastry, Radaelli, Lee, Takagi, Tchernyshyov. Session B28. GMAG: Focus Session: Surface and Interface Phenomena in Magnetic Films. Egelhoff. Session B29. GMAG/DMP: Focus Session: Magnetic Oxides: X-Ray and Neutron. Hill, Dai. Session B30. DCMP/GMAG: Correlated Electron Systems. Note: Room 11AB Session B19. DCMP/GMAG: Magnetic Phase Transitions I. Cat6.1 (where is II?) Session D6. Ballroom G, GMAG/DCMP: Spin-Transfer Torques in Magnetic Nanostructures. Stiles, Albert, Arne, Heinrich, Siegmann. Session D28.

37. Session E28 - Metallic Surfaces: Magnetism, Electron-ion Interaction. tool to investigate the magnetic properties of surfaces and thin films. For 3d metaloxides, there are relatively few studies of the surface magnetism in spite http://www.aps.org/BAPSMAR98/abs/S1030.html

Previous session Next session Session E28 - Metallic Surfaces: Magnetism, Electron-ion Interaction. MIXED session, Monday afternoon, March 16 506, Los Angeles Convention Center Magnetic Properties of Cobalt Thin Films Grown by Molecular Beam Epitaxy on Si(110) Mike T. Umlor, Olga V. Koshkina, Stefan Maat, Gary J. Mankey (MINT Center, University of Alabama) An H-Si(110) surface is prepared by etching in a dilute HF solution. The unreconstructed LEED pattern is obtained for the substrate and Auger electron spectroscopy is employed to check for surface contamination. A textured seed layer of Cu(111) is deposited on the substrate at room temperature in UHV. We found that layers as thin as 3-4 nm produce a good hexagonal LEED pattern. The surface roughness of the Cu on Si(110) is measured ex-situ with an atomic force microscope. The seed layer roughness is found to increase with increasing thickness of the deposited Cu layer. Both uncapped Co layers and samples capped with Cu are then deposited on the seed layers. The coercivities of the Co thin films are measured using an alternating gradient magnetometer and the magneto-optical Kerr effect. The magnetic domain structures of the films are studied using magnetic force microscopy. Oxidation of the Co layer greatly increases the measured coercivity and produces stripe domains. Ag Overlayer Effects on Magnetization of Ultra-thin Fe films on Ag(100) A. K. Swan, C. Hwang (Oak Ridge National Laboratory)

38. Session G20 - Nanocrystals IV: Magnetic And Magneto-Optic Properties (DMP Focuse G20.13 Magnetic properties of Colloidal Co Clusters. Nanoscale metal clusters areideal systems to understand the evolution of magnetism from atoms to the bulk http://www.aps.org/BAPSMAR98/abs/S1300.html

Previous session Next session Session G20 - Nanocrystals IV: Magnetic and Magneto-Optic Properties (DMP Focused Session). MIXED session, Tuesday morning, March 17 410, Los Angeles Convention Center Magnetic Transition in Small Mn_n Clusters Mark R. Pederson, David Patton (Complex Systems Theory Branch, Naval Research Laboratory, Washington, DC 20375), S. N. Khanna (Department of Physics, Virginia Commonwealth University, Richmond, VA 23284-2000), F. Reuse (IPE, EPFL, Switzerland) High-sensitivity EPR of Mn12-Acetate S. Hill (Dept. of Physics, Montana State University, Bozeman, MT 59717), N.S. Dalal, T. Hathaway (Chemistry Dept. and NHMFL, Florida State University, Tallahassee, FL 32310), T. Stalcup, J.S. Brooks (Dept. of Physics and NHMFL, Florida State University, Tallahassee, FL 32310) The energy level diagram of Mn_12-Acetate is probed close to the top of the anisotropy barrier using a novel, high-sensitivity, EPR technique. Multiple resonances, and their temperature dependence, are observed from 35 to 115 GHz, for a single high-quality crystal. The data are of sufficient detail to make extremely accurate comparisons with predictions based on a spin S = 10 Hamiltonian. The gross features of the EPR spectra confirm the strong axial symmetry, and show clear evidence for a significant fourth order term in the Hamiltonian. However, closer examination of the zero-field splittings close to the barrier indicate possible inadequacies of the spin S = 10 model. Several weak EPR transitions persist at low temperatures; we discuss the possibility that these transitions occur as a result of a finite population of levels other than the ground state. This work was supported under NSF-DMR 95-10427.

39. Relativistic Theory Of Magnetism W.Kohn the Nobel prize 1998). properties of interest is magnetism, including ultrahard permanent magnets as well as ultra soft magnets with low energy losses. http://www.fysik4.fysik.uu.se/Positions/ProjectOlle.html

Relativistic theory of magnetism Supervisor: Olle Eriksson, Docent, Department of Physics, Uppsala University 1. Project: The calculation of magneto optical properties is done by means of evaluation of inter band transitions for the imaginary part of the dielectric constant followed by a Kramers-Kronig transform to get the real part. Both the diagonal and off-diagonal elements of the dielectric tensor are calculated. Once the theories are developed one will have a unique position to reliably study magneto-optical properties of open packed crystal structures, artificially grown super lattices surfaces and so on. Since many of the technologically relevant systems form structures which are rather open, it has been hard to provide accurate theoretical data for them. This project attempts to cover this gap and derive theoretical data for technologically important systems such as MnBi, MnBiPt, tetragonally strained Fe, Co and Ni, and artificial structures (multi layers) involving Fe, Co and Ni. Other examples where relativistic electron theory and applications meet are hard respectively soft magnetic materials, both materials classes being used widely in car industry respectively power transformers and generators. In the Dirac equation the spin-orbit coupling connects spin-variables with real space properties, an effect that results in that the magnetization has preferred directions in a crystal, the so called easy direction. For certain applications on needs materials that require a large energy to rotate the magnetization direction out of the easy axis direction, so called hard magnets, whereas other materials used for instance in generators require a very small energy to rotate the magnetization. The fundamental physical interactions that lie behind this drastically different behavior for different materials is basically unknown, and the here proposed project attempts to address this issue, by means of the developed relativistic theory.

40. What Is Magnetism magnetism is a property of matter that is a result of the orbiting electrons T). Youwill run across four terms describing the magnetic properties of materials http://www.imagetechnology.net/what is magnatism.htm

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