01881oam 2200601I 450 991071500360332120201203111749.0(CKB)5470000002507973(OCoLC)760838972(EXLCZ)99547000000250797320111113j196808 ua 0engur|||||||||||txtrdacontentcrdamediacrrdacarrierTensile properties of tantalum and tungsten 10-fiber bundles at 1000° F (812 K) /by Ruluff D. McIntyreWashington, D.C. :National Aeronautics and Space Administration,August 1968.1 online resource (ii, 21 pages) illustrationsNASA technical note ;TN D-4725"August 1968."Includes bibliographical references (page 15).Tensile properties of tantalum and tungsten 10-fiber bundles at 1000° F Strength of materialsTungstenTantalumFibersFibersfastStrength of materialsfastTantalumfastTungstenfastStrength of materials.Tungsten.Tantalum.Fibers.Fibers.Strength of materials.Tantalum.Tungsten.McIntyre Ruluff D.1422117United States.National Aeronautics and Space Administration,Lewis Research Center.OCLCEOCLCEOCLCQOCLCFOCLCOOCLCQGPOBOOK9910715003603321Tensile properties of tantalum and tungsten 10-fiber bundles at 1000° F (812 K)3545442UNINA03552nam 2201009z- 450 991055714680332120210501(CKB)5400000000040590(oapen)https://directory.doabooks.org/handle/20.500.12854/68674(oapen)doab68674(EXLCZ)99540000000004059020202105d2020 |y 0engurmn|---annantxtrdacontentcrdamediacrrdacarrier2D Materials and Van der Waals HeterostructuresPhysics and ApplicationsBasel, SwitzerlandMDPI - Multidisciplinary Digital Publishing Institute20201 online resource (170 p.)3-03928-768-0 3-03928-769-9 The advent of graphene and, more recently, two-dimensional materials has opened new perspectives in electronics, optoelectronics, energy harvesting, and sensing applications. This book, based on a Special Issue published in Nanomaterials - MDPI covers experimental, simulation, and theoretical research on 2D materials and their van der Waals heterojunctions. The emphasis is the physical properties and the applications of 2D materials in state-of-the-art sensors and electronic or optoelectronic devices.2D Materials and Van der Waals HeterostructuresTechnology: general issuesbicssc2D materialsadsorption energyand magnetic propertyCdS/g-C3N4copper vanadateCVDdensity functional theorydensity of statesdiodeelectronic propertieselectronic structurefield effect transistorsfirst principles calculationsfluorescence emissiongraphenegraphene oxidegraphene/MoS2 heterostructurehalf-metalloceneheterojunctionhybrid density functionalIndium Selenidelarge-areaLayer-dependentlight-harvesting performancemechanical behaviorsMOS (Metal Oxide Semiconductor) capacitorMXeneoptical propertiespalladium selenide monolayerphotoanodephotocatalysisphotocatalytic propertiesphotodetectionphotodetectorphotovoltaicsphysical propertiesPMMARaman mappingresponsivitySchottky barriersensitivityStone-Wales defected graphenestrain-tunablesurface plasmon resonanceTi3C2Txtransition metal dichalcogenidetransition metal dichalcogenidestungsten diselenidetype-II heterostructurevan der Waals heterostructurewater splittingwork functionWS2ZnO/WS2ZnO/WSe2Technology: general issuesBartolomeo Antonioedt1278672Bartolomeo AntonioothBOOK99105571468033212D Materials and Van der Waals Heterostructures3025700UNINA