Tin IV Chloride

Solubility reacts violently with water sol cold HjO dec hot H2O  

Form Supplied in colorless liquid 1 M soln in CH2CI2 or heptane widely available. 

Purification reflux with mercury or P2O5 for several hours, then distill under reduced nitrogen pressure into receiver with P2O5. Redistill. Typical impurities hydrates. 

Handling, Storage, and Precautions hygroscopic should be stored in a glove box or over P2O5 to minimize exposure to moisture. Containers should be flushed with N2 or Ar and tightly sealed. Perform all manipulations under N2 or Ar. Solvating with H2O liberates much heat. Use in a fume hood. 

SnCU is also the principal source for alkyltin chlorides, RnSnCU-n- Allyltrialkyltin reagents react with SnCU to produce allyltrichlorotin species through an Se2 pathway (eq 1). Silyl enol ethers react with SnCU to give a-trichlorotin ketones (eq 2). Transmetalation or metathesis reactions of this type are competing pathways to nucleophilic addition reactions where SnCU is present as an external Lewis acid. As a consequence, four important experimental variables must be considered when using SnCU as a promoter (1) the stoichiometry between the substrate and the Lewis acid (2) the reaction temperatnre (3) the nature of the Lewis base site(s) in the substrate and (4) the order of addition. These variables influence the reaction pathway and product distribution.  

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Tin IV) chloride, SnCU, stannic chloride. M.p. — 33" C, b.p. 1I4°C. Colourless fuming liquid (Sn plus CI2) hydrolysed in water but forms SnCl4,5H20 and [SnCl p" from acid solutions, soluble in organic solvents. Used as a mordant. 

This reaction has been used to recover tin from scrap tinplate.) Tin(IV) chloride is a colourless liquid, which fumes in air due to hydrolysis ... 

Give brief experimental details to indicate how you could prepare in the laboratory a sample of either tin(IV) chloride or tin(IV) iodide. How far does the chemistry of the oxides and chlorides of carbon support the statement that the head element of a group in the Periodic Table is not typical of that group (JMB, A)... 

Tin(ll) chloride, in presence of hydrochloric acid, is oxidised to tin(IV) chloride, the nitrate ion in this case being reduced to hydroxylamine and ammonia. 

Chlorine reacts with most elements, both metals and non-metals except carbon, oxygen and nitrogen, forming chlorides. Sometimes the reaction is catalysed by a trace of water (such as in the case of copper and zinc). If the element attacked exhibits several oxidation states, chlorine, like fluorine, forms compounds of high oxidation state, for example iron forms iron(III) chloride and tin forms tin(IV) chloride. Phosphorus, however, forms first the trichloride, PCI3, and (if excess chlorine is present) the pentachloride PCI5. 

With the catalysis of strong Lewis acids, such as tin(IV) chloride, dipyrromethenes may aiso be alkylated. A very successful porphyrin synthesis involves 5-bromo-S -bromomethyl and 5 -unsubstituted 5-methyl-dipyrromethenes. In the first alkylation step a tetrapyrrolic intermediate is formed which cyclizes to produce the porphyrin in DMSO in the presence of pyridine. This reaction sequence is useful for the synthesis of completely unsymmetrical porphyrins (K.M. Smith, 1975). 

Alkyltin Intermedia.tes, For the most part, organotin stabilizers are produced commercially from the respective alkyl tin chloride intermediates. There are several processes used to manufacture these intermediates. The desired ratio of monoalkyl tin trichloride to dialkyltin dichloride is generally achieved by a redistribution reaction involving a second-step reaction with stannic chloride (tin(IV) chloride). By far, the most easily synthesized alkyltin chloride intermediates are the methyltin chlorides because methyl chloride reacts directiy with tin metal in the presence of a catalyst to form dimethyl tin dichloride cleanly in high yields (21). Coaddition of stannic chloride to the reactor leads directiy to almost any desired mixture of mono- and dimethyl tin chloride intermediates ... 

Stannic Chloride. Stannic chloride is available commercially as anhydrous stannic chloride, SnCl (tin(IV) chloride) stannic chloride pentahydrate, SnCl 5H20 and in proprietary solutions for special appHcations. Anhydrous stannic chloride, a colorless Aiming Hquid, fumes only in moist air, with the subsequent hydrolysis producing finely divided hydrated tin oxide or basic chloride. It is soluble in water, carbon tetrachloride, benzene, toluene, kerosene, gasoline, methanol, and many other organic solvents. With water, it forms a number of hydrates, of which the most important is the pentahydrate. Although stannic chloride is an almost perfect electrical insulator, traces of water make it a weak conductor. 

The reactivity of five-membered rings with one heteroatom to electrophilic reagents has been quantitatively compared in a variety of substitution reactions. Table 2 shows the rates of substitution compared to thiophene for formylation by phosgene and iV,AT-dimethylfor-mamide, acetylation by acetic anhydride and tin(IV) chloride, and trifluoroacetylation with trifluoroacetic anhydride (71AHC(13)235). 

Section 5.10.3.2). Treatment of methyl 6-phthalimido penicillinate (jR)-sulfoxide (40) with JV-chlorosuccinimide in refluxing carbon tetrachloride gives an epimeric mixture of sulfinyl chlorides (41) which are ring closed to epimeric 3-methylenecepham sulfoxides (42a) using tin(IV) chloride. Reduction with phosphorus tribromide gives the desired methyl 7-phthalimido-3-methylenecepham 4-carboxylate (42b). 

The first large-scale use of chlorine was for bleaching paper and cotton textiles it also is widely used as a germicide for public water supplies. Presently it is used principally in production of the chemical compounds sulfur chloride, thionyl chloride, phosgene, aluminum chloride, iron(ni) chloride, titaniura(IV) chloride, tin(IV) chloride, and potassium chlorate. 

Stannj.. stannic, stanni-. tin(IV). -azetat, n. stannic acetate, tin(IV) acetate, -chlorid, n. stannic chloride, tin(IV) chloride, -chlor-wasserstoffsaure, /. chlorostannic acid, -hydroxyd, n. stannic hydroxide, tin(IV) hydroxide, -jodid, n. stannic iodide, tin (IV) iodide. 

Zinn-bromwasserstoffsaure, /. bromostannic acid, -butter, /. (Old Chem.) butter of tin (stannic chloride), -charge, /. (Textiles) tin weighting, -chlorammonium, n. ammonium chlorostannate, (Dyeing) pink salt, -chlorid, n. tin chloride, specif, stannic chloride, tin (IV) chloride, -chloriir, n. stannous chloride, tin(II) chloride. 

Ethyl 3-ethoxy-4-oxo-l,7-diphenyl-2-azabicyclo[3.2.0]hept-2-ene-5-carboxylate (8) with tin(IV) chloride in dichloromethane undergoes ring expansion to the 4/7-azepine 9.48... 

Treatment of tricarbonylh4-1-(ethoxycarbonyl)-l//-azepine]iron(0) (30) with acetic anhydride and tetrafluoroboric acid at 0 C (Method A) yields the 3-acetyl derivative 31.226 The acetyl derivative is also formed, but in lower yield, by the action of acetic anhydride and tin(IV) chloride (Method B) on complex 30. The 3-propanoyl derivative (20% mp 95-96 C) can be prepared similarly, whereas formylation to give aldehyde 32 is successful under Vilsmeier conditions. 

Tin phthalocyanines can be prepared using tin(II)110 or -(IV)154 chlorides. The reaction can be performed in 1-chloro-1 10,1 37,1 55 or 1-bromonaphthalene,154 starting from phthalonitrile110137154,155 or phthalic anhydride. In the second case, urea and ammonium molyb-date(VI) arc added.137 The central tin atom can also be introduced into metal-free phthalocyanine by the reaction with tin(IV) chloride in dimethylformamide.141 Treatment of PcSnCl2 with disodium phthalocyanine in refluxing 1-chloronaphthalenc forms a sandwich-like bis-(phthalocyanine) Pc2Sn.154... 

The second important group of configuralionally stable bis-protected a-amino aldehydes are the V-dibenzvl derivatives 5, easily prepared from amino acids in a three-step procedure65. These aldehydes react with various nucleophiles to normally provide the nonchelation-con-trolled adducts in high diastereoselectivity. This anti selectivity is observed when diethyl ether or telrahydrofuran is used as reaction solvent. Certain Lewis acidic nucleophiles or additives, such as tin(IV) chloride, in dichloromethane as solvent force chelation and therefore provide the. syn-adducts, once again with a high diastereoselectivity. 

Allylsilanes or allylstannanes in the presence of a bidentate Lewis acid such as tin(IV) chloride, titanium(IV) chloride, zinc chloride, and magnesium bromide as well as diallylzinc, are promising choices (Table 1). 

The reaction between a-alkoxyaldehydes and allylsilanes is highly stereoselective in favor of chelation-controlled products if tin(IV) chloride is used as the Lewis acid, whereas boron trifluoride gives modest stereoselectivity in favor of the nonchelation-controlled product58. 

An interesting and stereoselective synthesis of 1,3-diols has been developed which is based on Lewis acid promoted reactions of /f-(2-propenylsilyloxy (aldehydes. Using titanium(IV) chloride intramolecular allyl transfer takes place to give predominantly Ag/r-l,3-diols, whereas anti-1,3-diols, formed via an / / /-molecular process, are obtained using tin(IV) chloride or boron trifluoride diethyl ether complex71. 

These observations were explained in terms of an SE reaction between the 2-butenyl-(tributyl)stannane and tin(IV) chloride, which competes with Lewis acid catalyzed carbonyl attack. The 1 -methyl-2-propenyltin trichloride so formed reacts with the aldehyde to give linear products, or isomerizes to give the more stable ( )- and (Z)-2-butenyltin trichlorides which then react74. Similar results were obtained with titanium(lV) chloride, except that the anti-ad-duct was the major product from the butenyltitanium intermediate74. 

The boron trifluoride-diethyl ether complex induced reaction of 2-butenyl(tributyl)-stannane and 3-(/er/-butyldimethylsilyloxy)-2-methylpropanal gave predominantly the nonchelation-controlled yyn-product93, whereas with the analogous 3-benzyloxyaldehyde, 2-propenyl-tin trichloride, generated in situ from tributyl(2-propenyl)stannanc and tin(IV) chloride, gave the chelation-controlled product93. 

Treatment of (5 )-4-benzyloxy-2-pentenyl(tributyl)stannane with tin(IV) chloride generates an intermediate which reacts with aldehydes to provide 1,5-diol derivatives with excellent stereoselectivity94. 

Incomplete simple diastereoselectivity. combined in at least some cases with lower induced stereoselectivity, is also found in the addition of silylketene acetals 1-alkoxy-l-trirnethylsilyloxy-l-propene to 2-benzyloxypropanal3. On the other hand, a single diastereomeric adduct results from the tin(IV) chloride mediated addition of the following enolsilane to (S )-2-benzyloxypropanal12. 

A -( 1-Chloro- or bromoalkyl)amides are generally moisture-sensitive, unstable compounds, which are often directly used without further purification. Standard Lewis acids such as boron trifluoride-diethyl ether, aluminum(lll) chloride, zinc(II) chloride, tin(IV) chloride and titani-um(IV) chloride are used to generate the /V-acyliminium ion, although sometimes a catalyst is not necessary. 

Optically active 2-allylpiperidines and -pyrrolidines arc obtained by treating hydroxylactams containing the l-[(S)-l-arylethyl]substituent as an auxiliary (see Appendix) with tin(IV) chloride and trimethyl(2-propenyl)silane46. Interestingly, the moderate diastereoselection when the aryl group is phenyl decreases when 2-chlorophenyl is used, whereas the sense of the stereoselectivity reverses for 2,6-dichlorophenyl or pentachlorophcnyl. These results are rationalized by application of molecular orbital theory and substrate conformational preferences46. 

All reactions were carried out following the typical procedure, entries 1-7 using tin(IV) chloride and entries 8-11 using titanium(IV) chloride as catalyst. 8 More examples can be found in refs 38-44. 

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