Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Generation of hydride

Chemical ingenuity in using the properties of the elements and their compounds has allowed analyses to be carried out by processes analogous to the generation of hydrides. Osmium tetroxide is very volatile and can be formed easily by oxidation of osmium compounds. Some metals form volatile acetylacetonates (acac), such as iron, zinc, cobalt, chromium, and manganese (Figure 15.4). Iodides can be oxidized easily to iodine (another volatile element in itself), and carbonates or bicarbonates can be examined as COj after reaction with acid. [Pg.100]

Silane -for C VD [THIN FILMS - FILM FORMATION TECHNIQUES] (Vol 23) -hydndesm generation of [HYDRIDES] (Vol 13) -lithium hydride mprdn of [LITHIUM AND LITHIUM COMPOUNDS] (Vol 15) -use m silicon purification [SILICON AND SILICON ALLOYS - PURE SILICON] (Vol 21)... [Pg.885]

Standing Committee of Analysts (DoE) (1987) Selenium and Arsenic Sludges, Soils and Related Material A Note on the Generation of Hydride Generator Kits, HMSO, London, UK. [Pg.70]

For elements such as bromine, phosphorus, germanium, lead and others, reactions for the generation of hydrides or of similar volatile species can also be found. [Pg.108]

Fig. 4.8 FIA assembly for continuous generation of hydrides and transport to the quartz cell of the atomic absorption spectrometer, designed for the determination of bismuth traces. (Reproduced from [4] with permission of the American Chemical Society). Fig. 4.8 FIA assembly for continuous generation of hydrides and transport to the quartz cell of the atomic absorption spectrometer, designed for the determination of bismuth traces. (Reproduced from [4] with permission of the American Chemical Society).
Thermochemical generation of hydrides appears feasible and has been utilized for the determination of arsenic species in the effluent from a liquid chromatograph. It is based on the injection of a thermospray aerosol into a methanol/oxygen flame where pyrolysis of the eluate occurs with subsequent thermochemical derivatization of the analytes and their transfer to a cool hydrogen-rich H2/O2 diffusion flame for atomization/AAS detection. [Pg.192]

Fundamentally, introduction of a gaseous sample is the easiest option for ICP/MS because all of the sample can be passed efficiently along the inlet tube and into the center of the flame. Unfortunately, gases are mainly confined to low-molecular-mass compounds, and many of the samples that need to be examined cannot be vaporized easily. Nevertheless, there are some key analyses that are carried out in this fashion the major one i.s the generation of volatile hydrides. Other methods for volatiles are discussed below. An important method of analysis uses lasers to vaporize nonvolatile samples such as bone or ceramics. With a laser, ablated (vaporized) sample material is swept into the plasma flame before it can condense out again. Similarly, electrically heated filaments or ovens are also used to volatilize solids, the vapor of which is then swept by argon makeup gas into the plasma torch. However, for convenience, the methods of introducing solid samples are discussed fully in Part C (Chapter 17). [Pg.98]

A major advantage of this hydride approach lies in the separation of the remaining elements of the analyte solution from the element to be determined. Because the volatile hydrides are swept out of the analyte solution, the latter can be simply diverted to waste and not sent through the plasma flame Itself. Consequently potential interference from. sample-preparation constituents and by-products is reduced to very low levels. For example, a major interference for arsenic analysis arises from ions ArCE having m/z 75,77, which have the same integral m/z value as that of As+ ions themselves. Thus, any chlorides in the analyte solution (for example, from sea water) could produce serious interference in the accurate analysis of arsenic. The option of diverting the used analyte solution away from the plasma flame facilitates accurate, sensitive analysis of isotope concentrations. Inlet systems for generation of volatile hydrides can operate continuously or batchwise. [Pg.99]

Quahtative insight can, however, be obtained by focusing on the reactions with water, the extent and vigor of which can vary widely. In general, however, hydrides react exothermically with water, resulting in the generation of hydrogen. [Pg.306]

A AlI lation. 1-Substitution is favored when the indole ring is deprotonated and the reaction medium promotes the nucleophilicity of the resulting indole anion. Conditions which typically result in A/-alkylation are generation of the sodium salt by sodium amide in Hquid ammonia, use of sodium hydride or a similar strong base in /V, /V- dim ethyl form am i de or dimethyl sulfoxide, or the use of phase-transfer conditions. [Pg.85]

A further improvement in the cuprate-based methodology for producing PGs utilizes a one-pot procedure (203). The CO-chain precursor (67) was first functionalized with zirconocene chloride hydride ia THF. The vinyl zirconium iatermediate was transmetalated direcdy by treatment with two equivalents of / -butyUithium or methyUithium at —30 to —70° C. Sequential addition of copper cyanide and methyUithium eUcited the /V situ generation of the higher order cyanocuprate which was then reacted with the protected enone to give the PG. [Pg.162]

To date, the most extensively studied polyboron hydride compounds in BNCT research have been the icosahedral mercaptoborane derivatives Na2[B22H22SH] and Na [(B22H22S)2], which have been used in human trials with some, albeit limited, success. New generations of tumor-localizing boronated compounds are being developed. The dose-selectivity problem of BNCT has been approached using boron hydride compounds in combination with a variety of deUvery vehicles including boronated polyclonal and monoclonal antibodies, porphyrins, amino acids, nucleotides, carbohydrates, and hposomes. Boron neutron capture therapy has been the subject of recent reviews (254). [Pg.253]

The chemical reduction of enamines by hydride again depends upon the prior generation of an imonium salt (111,225). Thus an equivalent of acid, such as perchloric acid, must be added to the enamine in reductions with lithium aluminum hydride. Studies of the steric course (537) of lithium aluminum hydride reductions of imonium salts indicate less stereoselectivity in comparison with the analogous carbonyl compounds, where an equatorial alcohol usually predominates in the reduction products of six-membered ring ketones. [Pg.428]

The familiar alkylation of -ketoesters followed by decarboxylation is still a useful route to a-alkyl ketones, although the alkylation of enamines is frequently the preferred route. Given below are two examples of alkylation of 2-carbethoxycycloalkanones (prepared in Chapter 10, Section I). In the first case, sodium ethoxide is the base employed to generate the enolate ion of 2-carbethoxycyclohexanone. In the second case, the less acidic 2-carbethoxycyclooctanone requires sodium hydride for the generation of the enolate ion. [Pg.99]

Although electrothermal atomisation methods can be applied to the determination of arsenic, antimony, and selenium, the alternative approach of hydride generation is often preferred. Compounds of the above three elements may be converted to their volatile hydrides by the use of sodium borohydride as reducing agent. The hydride can then be dissociated into an atomic vapour by the relatively moderate temperatures of an argon-hydrogen flame. [Pg.789]

There have been few satisfactory demonstrations that decompositions of hydrides, carbides and nitrides proceed by interface reactions, i.e. either nucleation and growth or contracting volume mechanisms. Kinetic studies have not usually been supplemented by microscopic observations and this approach is not easily applied to carbides, where the product is not volatile. The existence of a sigmoid a—time relation is not, by itself, a proof of the occurrence of a nucleation and growth process since an initial slow, or very slow, process may represent the generation of an active surface, e.g. poison removal, or the production of an equilibrium concentration of adsorbed intermediate. The reactions included below are, therefore, tentative classifications based on kinetic indications of interface-type processes, though in most instances this mechanistic interpretation would benefit from more direct experimental support. [Pg.155]

The synthetic applications have been reviewed (275). General developments have included the generation of the tin hydride in situ... [Pg.15]

See other pages where Generation of hydride is mentioned: [Pg.885]    [Pg.1004]    [Pg.216]    [Pg.568]    [Pg.535]    [Pg.1004]    [Pg.4458]    [Pg.185]    [Pg.885]    [Pg.1004]    [Pg.216]    [Pg.568]    [Pg.535]    [Pg.1004]    [Pg.4458]    [Pg.185]    [Pg.2]    [Pg.372]    [Pg.463]    [Pg.297]    [Pg.169]    [Pg.71]    [Pg.417]    [Pg.228]    [Pg.579]    [Pg.129]    [Pg.172]    [Pg.113]    [Pg.11]    [Pg.305]    [Pg.37]    [Pg.107]    [Pg.1387]    [Pg.311]    [Pg.288]    [Pg.155]   
See also in sourсe #XX -- [ Pg.108 ]

See also in sourсe #XX -- [ Pg.108 ]



SEARCH



Features of methods based on hydride or cold mercury vapour generation

Generator, hydride

Hydride generation

© 2024 chempedia.info