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Lead reaction with

Storage stability Stable in glass, lead-lined, or enamel-lined containers reaction with iron may be explosive. Vigorous corrosive action on all common metals except lead reaction with iron may be explosive. [Pg.131]

Reactivity and Incompatibility Sodium azide should not be allowed to come into contact with heavy metals or their salts, because it may react to form heavy metal azides, which are notorious shock-sensitive explosives. Do not pour sodium azide solutions into a copper or lead drain. Sodium azide reacts violently with carbon disulfide, bromine, nitric acid, dimethyl sulfate, and a number of heavy metals, including copper and lead. Reaction with water and acids liberates highly toxic hydrazoic acid, which is a dangerous explosive. Sodium azide is reported to react with CH2CI2 in the presence of DMSO to form explosive products. [Pg.392]

Fast transient studies are largely focused on elementary kinetic processes in atoms and molecules, i.e., on unimolecular and bimolecular reactions with first and second order kinetics, respectively (although confonnational heterogeneity in macromolecules may lead to the observation of more complicated unimolecular kinetics). Examples of fast thennally activated unimolecular processes include dissociation reactions in molecules as simple as diatomics, and isomerization and tautomerization reactions in polyatomic molecules. A very rough estimate of the minimum time scale required for an elementary unimolecular reaction may be obtained from the Arrhenius expression for the reaction rate constant, k = A. The quantity /cg T//i from transition state theory provides... [Pg.2947]

The Turing mechanism requires that the diffusion coefficients of the activator and inlribitor be sufficiently different but the diffusion coefficients of small molecules in solution differ very little. The chemical Turing patterns seen in the CIMA reaction used starch as an indicator for iodine. The starch indicator complexes with iodide which is the activator species in the reaction. As a result, the complexing reaction with the immobilized starch molecules must be accounted for in the mechanism and leads to the possibility of Turing pattern fonnation even if the diffusion coefficients of the activator and inlribitor species are the same 62. [Pg.3069]

Any lead(II) sulphate formed in this process is converted to lead(II) silicate by reaction with the quartz. The oxide produced is then mixed with limestone and coke and heated in a blast furnace. The following reactions occur ... [Pg.167]

One of the reactions is projected in that part of the Kohonen network where mostly reactions leading to the preferred regioisomer pyrazole were projected. The other reaction was projected in neuron (7,7), which lies in a region where reactions with low yield are projected. [Pg.548]

An interesting coupling reaction with the diazonium salt derived from anthranilic acid leads to an excellent method for the preparation of dlphenic acid. The reaction occurs with cuprous salts in ammoniacal solution ... [Pg.596]

As with other rare-earth metals, except for lanthanum, europium ignites in air at about 150 to I8O0C. Europium is about as hard as lead and is quite ductile. It is the most reactive of the rare-earth metals, quickly oxidizing in air. It resembles calcium in its reaction with water. Bastnasite and monazite are the principal ores containing europium. [Pg.177]

The mechanism by which Lewis-acids can be expected to affect the rate of the Diels-Alder reaction in water is depicted in Scheme 2.6. The first step in the cycle comprises rapid and reversible coordination of the Lewis-acid to the dienophile, leading to a complex in which the dienophile is activated for reaction with the diene. After the irreversible Diels-Alder reaction, the product has to dissociate from the Lewis-acid in order to make the catalyst available for another cycle. The overall... [Pg.57]

Note 2. Introduction of gaseous chlorine may lead to an explosion, owing to reaction with the diethyl ether. [Pg.67]

Diethyl 3-oxoheptanedioate, for example, is clearly derived from giutaryl and acetic acid synthons (e.g. acetoacetic ester M. Guha, 1973 disconnection 1). Disconnection 2 leads to acrylic and acetoacetic esters as reagents. The dianion of acetoacetic ester could, in prin-ciple,be used as described for acetylacetone (p. 9f.), but the reaction with acrylic ester would inevitably yield by-products from aldol-type side-reactions. [Pg.207]

One route to o-nitrobenzyl ketones is by acylation of carbon nucleophiles by o-nitrophenylacetyl chloride. This reaction has been applied to such nucleophiles as diethyl malonatc[l], methyl acetoacetate[2], Meldrum s acid[3] and enamines[4]. The procedure given below for ethyl indole-2-acetate is a good example of this methodology. Acylation of u-nitrobenzyl anions, as illustrated by the reaction with diethyl oxalate in the classic Reissert procedure for preparing indolc-2-carboxylate esters[5], is another route to o-nitrobenzyl ketones. The o-nitrophenyl enamines generated in the first step of the Leimgruber-Batcho synthesis (see Section 2.1) are also potential substrates for C-acylation[6,7], Deformylation and reduction leads to 2-sub-stituted indoles. [Pg.14]

A-4-Thiazoline-2-thiones can be obtained directly from 2-thiazolyldiazonium tetrafiuoroborate by reaction with an excess of thiourea (9). When 1 1 stoichiometry is used, the adduct (7) can be isolated. Further treatment of 7 with an excess of thiourea leads to the 2-mercaptolhiazole (3) 9). 2-Iminothiazoles 81 when heated at 150°C with CSt sive N-substituted A-4-thiazofine-2-thiones (9) (Scheme 31... [Pg.371]

Like pyridines (334), thiazoles undergo addition reactions with dimethyl acetylenedicarboxylate leading to 2 1 molar adducts, the structure of which has been a matter of controversy (335-339). [Pg.95]

Reaction with arenediazonium salts Adding a phe nol to a solution of a diazonium salt formed from a primary aromatic amine leads to formation of an azo compound The reaction is carried out at a pH such that a significant portion of the phenol is pres ent as its phenoxide ion The diazonium ion acts as an electrophile toward the strongly activated ring of the phenoxide ion... [Pg.1004]

The sample cells for molecular fluorescence are similar to those for optical molecular absorption. Remote sensing with fiber-optic probes (see Figure 10.30) also can be adapted for use with either a fluorometer or spectrofluorometer. An analyte that is fluorescent can be monitored directly. For analytes that are not fluorescent, a suitable fluorescent probe molecule can be incorporated into the tip of the fiber-optic probe. The analyte s reaction with the probe molecule leads to an increase or decrease in fluorescence. [Pg.428]

Eig. 9. A typical sonochemical apparatus with dkect immersion ultrasonic horn. Ultrasound can be easily introduced into a chemical reaction with good control of temperature and ambient atmosphere. The usual pie2oelectric ceramic is PZT, a lead 2kconate titanate ceramic. Similar designs for sealed... [Pg.261]

Reactions with Aldehydes and Ketones. The base-catalyzed self-addition of acetaldehyde leads to formation of the dimer, acetaldol [107-89-1/, which can be hydrogenated to form 1,3-butanediol [107-88-0] or dehydrated to form crotonaldehyde [4170-30-3]. Crotonaldehyde can also be made directiy by the vapor-phase condensation of acetaldehyde over a catalyst (53). [Pg.50]


See other pages where Lead reaction with is mentioned: [Pg.411]    [Pg.411]    [Pg.448]    [Pg.477]    [Pg.907]    [Pg.123]    [Pg.18]    [Pg.96]    [Pg.79]    [Pg.168]    [Pg.266]    [Pg.127]    [Pg.139]    [Pg.164]    [Pg.69]    [Pg.94]    [Pg.151]    [Pg.351]    [Pg.5]    [Pg.207]    [Pg.321]    [Pg.298]    [Pg.400]    [Pg.515]    [Pg.558]    [Pg.386]    [Pg.386]   


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1- Aminotriazolopyridine, reaction with lead

1- Aminotriazolopyridine, reaction with lead tetraacetate

2- butanone, reaction with lead

Alkenes, reaction with lead tetraacetate

Ammonium sulfate reaction with lead nitrate

Aryl lead derivatives, reaction with 8-ketoesters

Dicarboxylic acids reaction with lead tetraacetate

Diols reaction with lead tetraacetate

Esters vinyl, reaction with lead

Ethers ethyl vinyl, reaction with lead

Formula reaction with lead nitrate

Hydrazones reaction with lead

Hydrazones reaction with lead tetraacetate

Lead complexes, reaction with peroxides

Lead halides reactions with

Lead halides reactions with transition metal anion

Lead hydroxide, reaction with sugars

Lead metal reactions with

Lead nitrate reaction with potassium iodide

Lead nitrate reaction with sodium chloride

Lead reaction with ketene

Lead sulfate, reaction with sodium

Lead sulfide reaction with, phosgene

Lead tetraacetate reaction with alcohols

Lead tetraacetate reaction with amines

Lead tetraacetate reaction with ketones

Lead tetraacetate reactions with styrene

Lead tetraacetate, assay for reaction with diphenyl disulfide

Lead tetrabenzoate reaction with silyl dienol ethers

Lead thiocyanate, reaction with acid

Lead, elemental reactions with

Lead-phosphorus bonds reactions with

Lead—carbon bonds reactions with

Lead—halogen bonds reactions with

Lead—manganese bonds reactions with

Lead—oxygen bonds reactions with

Lead—platinum bonds reactions with

Oximes reaction with lead

Reaction with lead tetraacetate

Reaction with pyrophoric lead

Reactions of alcohols with lead tetraacetate

Reactions with lead acetates

Reactions with lead oxides

Reactions with lead sulfides

Sodium sulfate, reaction with lead nitrate

Stille reactions with lead compounds

Subject lead, reaction with oxygen

Subject lead, reaction with ozone

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