Search results for "Nonmetal"

showing 5 items of 5 documents

When are thin films of metals metallic? Part III

1996

Abstract A large amount of experimental information has indicated that very thin films of metallic elements can exhibit nonmetallic behavior, even on metal substrates. These films undergo a gradual nonmetal to metal transition with increasing film density or thickness. The nonmetallic behavior can be related to electron localization due to strong electron-electron correlation in low dimensional systems, as indicated by the strong enhancement of electron effective mass. The evolution in the electronic structure associated with the nonmetal to metal transition bears a striking resemblance to the behavior observed for free metal clusters. Part I [1], outlined the general concepts of a nonmetal…

Phase transitionMaterials scienceMetal K-edgeMechanical EngineeringElectronic structureCondensed Matter PhysicsElectron localization functionMetalEffective mass (solid-state physics)NonmetalMechanics of MaterialsChemical physicsvisual_artvisual_art.visual_art_mediumGeneral Materials ScienceThin filmMaterials Science and Engineering: A
researchProduct

Silver Sulfide Nanoclusters and the Superatom Model

2015

The superatom model of electron-shell closings has been widely used to explain the stability of noble-metal nanoclusters of few nanometers, including thiolate-protected Au and Ag nanoclusters. The presence of core sulfur atoms in silver sulfide (Ag–S) nanoclusters renders them a class of clusters with distinctive properties as compared to typical noble-metal clusters. Here, it is natural to ask whether the superatom model is still applicable for the Ag–S nanoclusters with mixed metal and nonmetal core atoms. To address this question, we applied density functional simulations to analyze a series of Ag–S nanoclusters: Ag14S(SPh)12(PPh3)8, Ag14(SC6H3F2)12(PPh3)8, Ag70S16(SPh)34(PhCO2)4(triphos…

optical propertiesElectron densitySilver sulfideInorganic chemistryNanoclusterschemistry.chemical_compoundAtomic orbitalNonmetalCluster (physics)Physical and Theoretical Chemistryta116electromagnetic wave absorptionconduction bandsatomsta114ChemistrySuperatomprecious metalsmolecular orbitalsTriphosSurfaces Coatings and FilmsElectronic Optical and Magnetic Materialsenergy gapCrystallographyGeneral Energysulfurlight absorptionThe Journal of Physical Chemistry C
researchProduct

Thermal activated carrier transfer between InAs quantum dots in very low density samples

2010

In this work we develop a detailed experimental study of the exciton recombination dynamics as a function of temperature on QD-ensembles and single QDs in two low density samples having 16.5 and 25 dots/¼m2. We corroborate at the single QD level the limitation of the exciton recombination time in the smallest QDs of the distribution by thermionic emission (electron emission in transient conditions). A portion of these emitted carriers is retrapped again in other (larger) QDs, but not very distant from those emitting the carriers, because the process is limited by the diffusion length at the considered temperature.

HistoryWork (thermodynamics)Condensed Matter::Otherbusiness.industryChemistryExcitonThermionic emissionElectron66.30.H- Self-diffusion and ionic conduction in nonmetals78.67.Hc Quantum dotsCondensed Matter::Mesoscopic Systems and Quantum Hall EffectMolecular physicsComputer Science ApplicationsEducationCondensed Matter::Materials Science78.55.Cr III-V semiconductorsQuantum dotThermalOptoelectronics71.35.-y Excitons and related phenomenaDiffusion (business)businessRecombination79.40.+z Thermionic emissionJournal of Physics: Conference Series
researchProduct

Photocatalytic and photothermocatalytic applications of cerium oxide-based materials

2020

Abstract Cerium dioxide (CeO2) presents unique properties as the special electronic and optical properties of the 4f electrons, the capacity to form nonstoichiometric oxygen-deficient CeO2 − x oxides, the high oxygen mobility, and the reversible transformation between Ce4 + and Ce3 + that make it interesting for photocatalytic applications. CeO2 is a wide bandgap semiconductor (3.0–3.4 eV), but different approaches as combination with oxides, deposition of noble metals, doping with metal and nonmetal species, and the formation of surface defects have been adopted to extend its absorption towards the visible region with the aim to improve its photocatalytic performance. Cerium oxide-based ma…

CeriumCerium oxideMaterials scienceNonmetalChemical engineeringchemistryDopingPhotocatalysisWater splittingchemistry.chemical_elementCeO2 photocatalysis photothermocatalysisRedoxCatalysis
researchProduct

Neorganiskā ķīmija:Teorētiskā daļa un nemetāli

1921

Docenta A. Janeka lekciju Latvijas Universitātē otrais pārstrādātais un papildinātais izdevums neorganiskajā ķīmijā.

ChemistryNeorganiskā ķīmijaNonmetalsNemetāli:NATURAL SCIENCES::Chemistry::Inorganic chemistry [Research Subject Categories]Ķīmija
researchProduct