Search for tag: "characteristic energy"

2017 REU Jacob Waelder PARADIM REU Nano-Convocation

From  James Overhiser on February 18th, 2019 4 plays

2017 REU Morgan Grandon 2017 PARADIM REU Nano-Convocation

From  James Overhiser on February 18th, 2019 4 plays

2017 REU Daniel Bouman 2017 PARADIM REU Nano-Convocation

From  James Overhiser on February 18th, 2019 6 plays

Valence EELS, High Energy Resolution

2017 PARADIM SUMMER SCHOOL Low loss EELS David Muller

optical spectroscopyformal sciencesconcepts in physicssilicon richsilicon dioxidechemical elementsband gapscatteringelectron densitylowest energy featurereducing agentsvalence electronsquick rulepyrotechnic fuelselectron microscopewaveguide modenuclear physicspercent radiuselectronreal troubledielectric boundary conditionsnice bigfactorial and binomial topicstightly boundelectric fieldspatial resolutionsingle scatteringopticssample thicknessinterface plasmanano particlesoptical gapdirect bandgapphosphatesparticle physicsfluid dynamicshigh energy electronatomic physicsdielectric responsesbiology and pharmacology of chemical elementsliquid cellmultiple scatteringelectron beamenergy resolutiontiny signalsingle particle transitioncherenkov radiationelectron gasfree electron gasoptical transitionenergy lossenergy lostcharacteristic anglefree electronicenergy filterlow energycharge oscillationsvalence regionsurface plasmatoxicologyfree pathsilicon oxideoptical spectrabulk materialexit haitiancall auspexfourier analysisquantum mechanicsbig backgroundimage chargeelectrostaticslastic scatteringnice thinginteresting standing wavebessel functionboundary conditionsion imagesingle particlestanding wave modesfunny featureelectron statesscattering eventdirect gapgood free electronphysical quantitiesenergy loss functionvector calculusdietary mineralsabsorption and radiative transfer (optics)electrical engineeringthick samplefield lineslength scaleelectronics terminologyelectrodynamicsphoria transformradiation sensitivecaption completehofplasma frequencylog scaleexperimental particle physicshof epsilonsemiconductor materialshigher energyhigh frequencyatomic resolutioninterface modegood newsharmonic oscillatorspecial relativitydielectric functiondiverges logarithmicallyshine lightcouple 100 voltt.m.incredibly complicatedbad newselectromagnetismenergy rangecherenkov modes100 voltspherical modeslinear operators in calculuschemistrybulk plasma
From  James Overhiser on February 15th, 2019 14 plays

Schrodinger equation and mean-field approximation - Lecture 1.2

2016 PARADIM SUMMER SCHOOL Feliciano Giustino - Lecture 1.2

concepts in physicschemical elementssimple equationsolutionscharacteristic energybody wave functionelectronic structurecorrelation potentialelectron densityarchitectural elementssquare divided1st principleselectronegyptian artefact typesgrammarparticle equationelectron chargeforcekinetic energy potentialenergyphilosophical terminologyprinciplesnuclear masshydrogen physics1st electronparticle physicsquantum chemistrychemical propertiesbody problemstarting pointcool interactionbiology and pharmacology of chemical elementsspintronicsf.t.environmental sciencepeople talkatomsindependent particlefunctions and mappingspotential exactedchemical processesexclusion principlehelium atomconservation lawsmechanicsextra potentialelectronic structure methodselectron basicallycommunicationforms of energyreference frametomorrow morningexperimental parameterelectrostaticscomplex numberquantum mechanicshydrogen wave functionscompletely ignoresingle particleminus $13.00quantum modelsairship technology100 yearspotential energy comingphysical quantitiesbasically minuscondensed matter physicspotential energyhydrogen atomindependent eventsnuclear potentialpretty tablecolumn interactionstate functions40000 pointstakes caremathematical terminologysquare modelheliumphysical principlecaption completesingle particle equationhydrogensemiconductor materialskinetic energyexchange potentialtotal energyindependent electrongood newspartial differential equationselectron mass1st stephuman communicationelectromagnetismelectronic variablesatomic numbermasswave function
From  James Overhiser on February 15th, 2019 40 plays

CNF NanoCourses 2004 – Section 3.2: Thin Film Properties,

cubic mineralsseparation processesphysical phenomenaenvironmental sciencepyrotechnic fuelsaccountancyconfectionerysteelatmospheric thermodynamicscrystallographycharge carrierspropertynuclear physicssemiconductor device fabricationtransformationssupply chain management termselectronics terminologybodies of watertopologyelectromagnetic radiationalgebrasedimentary rocksaquatic ecologyproperty lawmetal platingwatersnow removalliquidscorrosionconcepts in physicsmanufacturingphysical objectsatomic physicsfuelsnatural philosophyfluid dynamicstemperaturepressureplasma processingphilosophical terminologygeomorphologychemical compoundseducational psychologyphase transitionsfluvial landformschemical engineeringdistributionphilosophy of lawphotographycell biologycoppervolume ratiosystems scienceerosion landformsforms of watersandtechnologygrain boundaryphases of mattermetalshistorical scientific instrumentsfluid mechanicssuperhard materialscarbidessnowpedologyoxidescharacteristiccommunicationtransition metalslaboratory equipmentsolid-state chemistrybiology and pharmacology of chemical elementsnonmetalsconstructionbiomoleculesdiffusionmaterials scienceproduction and manufacturingsemiconductormaterialelectronicsgaseschemical kineticschemistryenergycaption completeelectric and magnetic fields in mattersystems theoryinformationsedimentologydielectricsglasscompound semiconductorscrystalplasma physicssurface chemistryreducing agentsphysiologythermodynamiceconomic anthropologycondensed matter physicsindustrial processeselectric fieldmemoryicecoatingsthermodynamicssemiconductorsprecipitationchemical propertiescontaminationpackaging materialsheat transferbuilding materialsdietary mineralsgrainthin filmnitridesphysical chemistrysurfacecrystalselectricityfilmsmineralogymicroscopesstate functionsmarketingelectromagnetismlogisticspolitical philosophysolutionspoly crystalinformation scienceelectrical conductorsvolumemetallurgydepositionnerve gascomputer sciencevacuumgeometrymolecular physicsmeteorologythin-film cellsindustrysolvents
From  David Botsch on January 20th, 2012 119 plays

CNF NanoCourses 2004 – Section 4.4: Auger and Thin Film An

metalloidschemical elementsmultinational companiesthermodynamicsbuilding materialselectrical conductorsmeasuring instrumentsopticsphysical chemistrymaterialgroup theoryionstransition metalsmicroscopysystems sciencegeochemistrycarboncartographyoncologynative element mineralssensitivityspectroscopyenergy levelsgallium arsenidecarbon formsmicroscopescondensed matter physicsproblem solvingchemical propertiesiarc group 2b carcinogensmaintenanceergonomicskinematicsquantum chemistryscientific techniquesmass spectrometryanalytical chemistryphases of matterlaboratory techniquessoil contaminationcobolatomic physicsstatistical terminologymaterials sciencereliability engineeringdifferential calculusrefractory materialsobject-oriented programming languagescompound semiconductorsmetallurgycharacteristicvacuumfailureclassical mechanicsmoleculesphysical objectsfood coloringsiarc group 1 carcinogensprecious metalselectronicscoatingsdensityelementary algebrasemiconductor materialsbusiness termsspectrumconcepts in physicselectromagnetismheat transferphilosophical terminologyhouse typescharacterizationdietary mineralsenergy (physics)c.h.f.occupational safety and healthnonmetalsmolecular biologyscientific terminologytransitionpyrotechnic fuelsquantum electrodynamicsmeasurementelectromagnetic radiationtoxicologyteratogensparticle physicssampleindustrial processescontinuum mechanicschemical reactionscharge carrierscaption completeelectronquantum mechanicsforms of energygeographynuclear physicspnictogenschemistryenergy conversionscatteringthin filmsmolecular physicssystems theoryreducing agentscomputer programmingprogramming languageselectrodes
From  David Botsch on January 20th, 2012 55 plays