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Elements electronic properties

In addition, all of the process raw materials must be clean and not iatroduce contaminants. The raw materials and temporary coatings must also be defect-free, and these have to be manufactured under similar conditions so that no contaminants are iatroduced. The solvents used to clean the substrate and develop the resists must be filtered and pure. Care must also be taken to ensure that no trace compounds or elements are present that may affect the electronic properties. The specific type of coating aid, the type of functional coating, and the process used to apply the functional coating are all widely varied ia actual practice. [Pg.124]

The chemical and electronic properties of elements at the interfaces between very thin films and bulk substrates are important in several technological areas, particularly microelectronics, sensors, catalysis, metal protection, and solar cells. To study conditions at an interface, depth profiling by ion bombardment is inadvisable, because both composition and chemical state can be altered by interaction with energetic positive ions. The normal procedure is, therefore, to start with a clean or other well-characterized substrate and deposit the thin film on to it slowly at a chosen temperature while XPS is used to monitor the composition and chemical state by recording selected characteristic spectra. The procedure continues until no further spectral changes occur, as a function of film thickness, of time elapsed since deposition, or of changes in substrate temperature. [Pg.30]

Next, let us look at modification of CNTs. There are many approaches to modifying the electronic structure of CNTs oxidation [39], doping (intercalation) [69], filling [70] and substitution by hetero elements like boron and nitrogen atoms [71,72]. There have been few studies on the application of these CNTs but it will be interesting to study applications as well as electronic properties. [Pg.180]

A photovoltaic cell (often called a solar cell) consists of layers of semiconductor materials with different electronic properties. In most of today s solar cells the semiconductor is silicon, an abundant element in the earth s crust. By doping (i.e., chemically introducing impurity elements) most of the silicon with boron to give it a positive or p-type electrical character, and doping a thin layer on the front of the cell with phosphorus to give it a negative or n-type character, a transition region between the two types... [Pg.1058]

With all these advantages one might well wonder why the left-step table has not attracted more attention and indeed why it has not been widely adopted. The answer to this question lies in the placement of one crucial element, helium. In the left-step table, helium is placed among the alkaline earth metals as mentioned above. To most chemists this is completely abhorrent since helium is regarded as the noble gas par excellence. Meanwhile, to a physicist or somebody who emphasizes electronic properties, helium falls rather naturally into the alkaline earths since it has two outer-shell electrons. [Pg.9]

The known oxidation states of plutonium present a 5f -series, starting from f1 [Pu(VII)] up to f5 [Pu(III)]. But contrary to the 4f - and 5f series across the period table, where the properties can be described by some smooth varying parameters, changing of the oxidation states influences the electronic properties drastically. Due to the large range of available oxidation states plutonium represents a favorable element among the actinides to study these effects. [Pg.31]

The many possible combinations of II-V and II-VI compounds allow the tailoring of electronic and opto-electronic properties to suit specific applications. Of particular importance is the control of the stoichiometry of the element involved. This is achieved by the proper handling of the MOCVD reactions. Being able to tailor the bandgap imparts great flexibility in the design of transistors and optoelectronic devices. [Pg.358]

The change in the electronic properties of Ru particles upon modification with Se was investigated recently by electrochemical nuclear magnetic resonance (EC-NMR) and XPS [28]. In this work, it was established for the first time that Se, which is a p-type semiconductor in elemental form, becomes metallic when interacting with Ru, due to charge transfer from Ru to Se. On the basis of this and previous results, the authors emphasized that the combination of two or more elements to induce electronic alterations on a major catalytic component, as exemplified by Se addition on Ru, is quite a promising method to design stable and potent fuel cell electrocatalysts. [Pg.316]

The periodic table orders the elements in a way that helps chemists understand why atoms behave as they do. What makes fluorine react violently with cesium while its nearest neighbor neon is reluctant to react with anything In other words, what gives the elements their properties and what order lies below the surface of their seemingly random nature Scientists know now that the periodicity of the elements is due largely to recurring patterns in their electron configurations. [Pg.58]

In addition to the establishment and understanding of activity trends on nanosegregated surfaces, it has been anticipated that finding relationships between chemical and electronic properties of thin metal films of Pt group metals deposited over 3d and 5d elements has the potential to open up new opportunities in the quest to... [Pg.263]

The representation of the periodic system in this book shows yet another perspective. Each element has not only its own history but also its own identity. This is determined by the number of protons in the nucleus (the atomic number) and the corresponding number of electrons in the atomic shell. These electrons, in turn, give each element their properties, their "personalities", so to speak. There are relationships, but each element is unique in the sum of its properties. The text describes the particularities of each element, and the chosen picture indicates a scene from everyday life where we would encounter... [Pg.5]

In this chapter, a brief review of quantum mechanical methods and the arrangement of electrons in atoms has been presented. These topics form the basis for understanding how quantum mechanics is applied to problems in molecular structure and the chemical behavior of the elements. The properties of atoms discussed in Chapter 1 are directly related to how the electrons are arranged in atoms. Although the presentation in this chapter is not exhaustive, it provides an adequate basis for the study of topics in inorganic chemistry. Further details can be found in the references. [Pg.62]

It was also found that both the Lewis acidity and basicity depend not only on specific electronic properties of the central group 13 and group 15 elements, but significantly on substituent effects.24 Electron-withdrawing substituents increase the Lewis acidity but decrease the Lewis basicity, whereas electron-donating substituents decrease the Lewis acidity and... [Pg.230]

See other pages where Elements electronic properties is mentioned: [Pg.398]    [Pg.87]    [Pg.1192]    [Pg.2391]    [Pg.393]    [Pg.309]    [Pg.445]    [Pg.359]    [Pg.154]    [Pg.78]    [Pg.69]    [Pg.325]    [Pg.185]    [Pg.342]    [Pg.123]    [Pg.124]    [Pg.16]    [Pg.293]    [Pg.132]    [Pg.228]    [Pg.267]    [Pg.312]    [Pg.53]    [Pg.3]    [Pg.3]    [Pg.441]    [Pg.8]    [Pg.152]    [Pg.97]    [Pg.34]    [Pg.19]    [Pg.622]    [Pg.129]    [Pg.269]    [Pg.357]    [Pg.474]    [Pg.137]    [Pg.646]   
See also in sourсe #XX -- [ Pg.48 ]

See also in sourсe #XX -- [ Pg.48 ]



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