Alkyl hahde reaction with

The reactivities of alkyl halides are in the sequence RI > RBr > RCl and MeX > EtX > PrX. Benzyl hahde reactions with tin do not require catalysts (equation 2). For less reactive halides, the catalysts and promoters employed include metals (sodium, magnesium, zinc, or copper), Lewis bases (amines, triorganophosphines and -stibines, alcohols, or ethers), iodides, and onium salts (R4MX). The use of tin-sodimn alloys can result in tri- or tetraorganotin products. Electrochemical synthesis has also been reported, e.g. the formation of R2SnX2 from the oxidation of anodic tin by RX in benzene solution and the formation of ILtSn from RI (R = Me or NCCH2CH2) and cathodic tin. 

Another similar example concerns the alkylation of enamines. This reaction works well with reactive a-halocarbonyl compounds (frames 175ff) but simple alkyl hahdes often react on nitrogen ... 

Nitdles may be prepared by several methods (1). The first nitrile to be prepared was propionitdle, which was obtained in 1834 by distilling barium ethyl sulfate with potassium cyanide. This is a general preparation of nitriles from sulfonate salts and is referred to as the Pelou2e reaction (2). Although not commonly practiced today, dehydration of amides has been widely used to produce nitriles and was the first commercial synthesis of a nitrile. The reaction of alkyl hahdes with sodium cyanide to produce nitriles (eq. 1) also is a general reaction with wide appHcabiUty ... 

The direct reaction of other alkyl chlorides, such as butyl chloride, results in unacceptably low overall product yields along with the by-product butene resulting from dehydrochlorination. AH alkyl haHdes having a hydrogen atom in a P- position to the chlorine atom are subject to this complication. 

Alkyl hahdes in the presence of silver oxide react with alkyl malates to yield alkoxy derivatives of succinic acid, eg, 2-ethoxysuccinic acid, H00CCH2CH(0C2H )C00H (12,13). A synthetic approach to produce ethers of malic acid is the reaction of malic esters and sodium alkoxides which affords 2-alkoxysuccinic esters (14). 

Isopropylnaphthalenes produced by alkylation of naphthalene with propjdene have gained commercial importance as chemical intermediates, eg, 2-isopropylnaphthalene [2027-17-OJ, and as multipurpose solvents, eg, mixed isopropylnaphthalenes. Alkylation of naphthalene with alkyl haUdes (except methyl hahdes), acid chlorides, and acid anhydrides proceeds in the presence of anhydrous aluminum chloride by Friedel-Crafts reactions (qv). The products are alkylnaphthalenes or alkyl naphthyl ketones, respectively (see Alkylation). 

Method 7. Alkyl haHde amination reaction of ammonia or alkylamine with an alkyl haHde. 

A number of 2eohtic materials have been claimed to cataly2e this reaction and reaction temperatures are on the order of 200—350°C with pressures as high as 18000 kPa (2600 psi) reported. This is a low conversion process and recycle of the unconverted starting materials is necessary to provide an economical process. Amination of ethylene to produce ethylamines cataly2ed by ammonium iodide is reported, but not beheved to be practiced commercially (15,16). Alkyl Halide Amination (Method 7). The oldest technology for pioducing amines is the reaction of ammonia with an alkyl hahde. This... 

Nitriles. Nitriles can be prepared by a number of methods, including ( /) the reaction of alkyl haHdes with alkaH metal cyanides, (2) addition of hydrogen cyanide to a carbon—carbon, carbon—oxygen, or carbon—nitrogen multiple bond, (2) reaction of hydrogen cyanide with a carboxyHc acid over a dehydration catalyst, and (4) ammoxidation of hydrocarbons containing an activated methyl group. For reviews on the preparation of nitriles see references 14 and 15. 

Reaction with Alkyl Halide. The active methylene group of an Al-acylamino-malonic acid ester or Ai-acylamino cyanoacetic acid ester condenses readily with primary alkyl hahdes. 

The esters of sahcyhc acid account for an increasing fraction of the sahcyhc acid produced, about 15% in the 1990s. Typically, the esters are commercially produced by esterification of sahcyhc acid with the appropriate alcohol using a strong mineral acid such as sulfuric as a catalyst. To complete the esterification, the excess alcohol and water are distilled away and recovered. The cmde product is further purified, generally by distillation. For the manufacture of higher esters of sahcyhc acid, transestetification of methyl sahcylate with the appropriate alcohol is the usual route of choice. However, another reaction method uses sodium sahcylate and the corresponding alkyl hahde to form the desired ester. 

All lation. In alkylation, the dialkyl sulfates react much faster than do the alkyl haHdes, because the monoalkyl sulfate anion (ROSO ) is more effective as a leaving group than a haHde ion. The high rate is most apparent with small primary alkyl groups, eg, methyl and ethyl. Some leaving groups, such as the fluorinated sulfonate anion, eg, the triflate anion, CF SO, react even faster in ester form (4). Against phenoxide anion, the reaction rate is methyl triflate [333-27-7] dimethyl sulfate methyl toluenesulfonate [23373-38-8] (5). Dialkyl sulfates, as compared to alkyl chlorides, lack chloride ions in their products chloride corrodes and requires the use of a gas instead of a Hquid. The lower sulfates are much less expensive than lower bromides or iodides, and they also alkylate quickly. 

The reactions of these nucleophilic processes are usually S 2 rather than S l. The reaction rate is methyl > ethyl > isopropyl, as with the alkyl hahdes. As the species to be alkylated becomes more nucleophilic, alkylation becomes faster, eg, a sulfur-containing anion alkylates more quickly than a phenohc anion. 

Examples are given of common operations such as absorption of ammonia to make fertihzers and of carbon dioxide to make soda ash. Also of recoveiy of phosphine from offgases of phosphorous plants recoveiy of HE oxidation, halogenation, and hydrogenation of various organics hydration of olefins to alcohols oxo reaction for higher aldehydes and alcohols ozonolysis of oleic acid absorption of carbon monoxide to make sodium formate alkylation of acetic acid with isobutylene to make teti-h ty acetate, absorption of olefins to make various products HCl and HBr plus higher alcohols to make alkyl hahdes and so on. 

For example, the sensitive imidoyl chloride moiety at the C-3 position of the pyrazinone scaffold is known to vmdergo Stille reactions with a variety of tetraaryltin reagents, generating the corresponding 3-substituted pyrazi-nones (Scheme 10) [26]. Furthermore, the transition-metal-catalyzed stannyl-ation at the C-3 position is also documented in the hterature, in view of cross-couphng with a variety of alkyl and (hetero)aryl hahdes [26]. However, this strategy is completely restricted to the C-3 position, while the Cl atom of C-5 position was found to be inert under these conditions. 

We discovered a complementary procedure for conversion of OMen to other functional groups. The ester P-OMen bond was shown to be cleaved in a stereoselective manner reductively [85,86]. The cleavage takes place with almost complete preservation of stereochemical integrity at phosphorus. The reducing agents are usually sodium or Hthium naphthalenide, lithium biphenyUde, and Hthium 4,4 -di-fert-butylbiphenyl (LDBB). The species produced is then quenched with an alkyl hahde or methanol to afford tertiary or secondary phosphines, respectively (Scheme 5b). Overall, the displacement reaction proceeds with retention of configuration. 

Two principle strategies have been employed for the synthesis of siloxide-containing molecular precursors. The first involves a silanolysis, or condensation, reaction of the Si - OH groups with a metal amido, alkyl, hahde, or alkoxide complex. The second method involves salt metathesis reactions of an alkali metal siloxide with a metal hahde. Much of our work has been focused on formation of tris(tert-butoxy)siloxide derivatives of the early transition metals and main group elements. The largely imexplored regions of the periodic table include the lanthanides and later transition metals. 

Dialkyl ditellurides (general procedure A mixture of powdered Te (3.58 g, 28 mmol), Na chips (0.65 g, 28 mmol) and naphthalene (0.36 g, 2.8 mmol) in anhydrous THF (25 mL) is refluxed under Nj and stirred for 1 h. During this time all the sodium is consumed and the mixture turns a light brown colour. The solution is stirred for an additional 3 h to ensure the complete reduction of Te, the temperature is then lowered to 10°C and the alkyl hahde (28 mmol) is added dropwise for 30 min with stirring. After an additional hour of stirring at room temperature, the reaction mixture is filtered, the solvent evaporated and the residue distilled under vacuum, giving the pure ditelluride (R=Et (85%), n-Pr (90%), n-Bu (90%), MeOCHjCHj (60%)). 

Hydrogen peroxide undergoes substitution reactions with alkyl hahdes forming an organic peroxy acid or peroxide, depending on reaction conditions and molar ratios of reactants. The mechanism of such reactions are very complex. These reactions may be represented in the following equations ... 

It is a reaction of wide scope both the phosphite 1 and the alkyl hahde 2 can be varied. Most often used are primary alkyl halides iodides react better than chlorides or bromides. With secondary alkyl halides side reactions such as elimination of HX can be observed. Aryl halides are unreactive. 

The alkyl complexes mentioned above are very electron rich, and thus their susceptibility to reaction with O2 is not a great surprise, though the formation of stable organometallic oxidation products may be. Somewhat more unusual is the reaction of metal(III) hahdes with O2. Relatively recent results in this area begin with the report by Morse et al. of the oxidative addition of O2 to [Cp CrBr( ji- Br)]2, see Eq. 9 [23]. 

Reversible redox reactions can initiate radical chemistry without a follow-up reduction or oxidation reaction. In successful reactions of this type, the redox step that produces the radical is thermodynamically disfavored. For example, Cu(I) complexes react reversibly with alkyl hahdes to give Cu(II) hahde complexes and an alkyl radical. The alkyl radical can react in, for example, an addition reaction, and the product radical will react with the Cu(II) hahde to give a new alkyl halide. This type of reaction sequence, which has been apphed in living radical polymerizations, is in the general family of nonchain radical reactions discussed earlier. ... 

The aspects of the preparation and reactions of chiral Grignard reagents were reviewed . Exchange of alkyl hahdes is synthetically useful mostly if a-halogen or a-acyloxy substituents are present. The resulting Grignard reagents react smoothly with various electrophiles (equation 43) . ... 

Diels-Alder reaction (Scheme 1.2) is used for the formation of six-membered ring systems, and treatment of alkyl hahdes with reagents such as tributyltin hydride (Scheme 1.3) results in removal of the associated hahdes. However, by presenting these reactions as illustrated in Schemes 1.1, 1.2, and 1.3, no explanation is provided as to how the starting materials end up as their respective products. 

The reaction of (CH,i ,CBr with K O looks analogous to Ihi reaction of CHaBr with OH, and we might therefore expect to ohserve second-order kinetics. In fact, we do not. We find instead that the reaction rate is dependent only on the alkyl hahde conoentrntian and is independent of the 11 concentration. In ether words, the reaction is a ftrsi-order process Only... 

The reactivity of 02 - with alkyl halides in aprotic solvents occurs via nucleophilic substitution. Kinetic studies confirm that the reaction order is primary > secondary > tertiary and I > Br > Cl > F for alkyl hahdes, and that the attack by 02 - results in inversion of configuration (Sn2). Superoxide ion also reacts with CCI4, Br(CH2)2Br, CeCle, and esters in aprotic media. The reactions are via nucleophilic attack by 02 on carbon, or on chlorine with a concerted reductive displacement of chloride ion or alkoxide ion. As with all oxyanions, water suppresses the nucleophilicity of 02 (hydration energy, lOOkcalmoL ) and promotes its rapid hydrolysis and disproportionation. The reaction pathways for these compounds produce peroxy radical and peroxide ion intermediates (ROO and ROO ). 

This reaction gives good results for a variety of activated and unactivated alkyl hahdes [112] Oxidation of 2-bromoketones with N-phenyltriflaimde was used in a one pot synthesis of pyrazmes by the sequence of reactions shown m equaUon 57 [113] The procedure was successfully applied to the synthesis of deoxyaspergillic acid [ I14 ... 

Historicahy, among the most important reactions of sihcon hahdes are those occurring with metal alkyls and metal alkyl hahdes. The Grignard reaction, for example, was the first commercial process for manufacturing organosihcon compounds, which were later converted to sihcones (19). 

We have now considered two different kinds of reactions (substitution and elimination) and four different mechanisms (SnI, Sn2, El, and E2) that begin with one class of compounds (aUcyl halides). How do we know if a given alkyl hahde will undergo substitution or elimination with a given base or nucleophile, and by what mechanism ... 

HASS-BENDER CartJonylSynthesis or ketone synthesis by reaction o( an alkyl haHde with the sodum salt of 2-nitroalkanss. 

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