Amide, lithium sodium

Synthetically important alkali—metal amides Lithium, sodium, and potassium hexamethyldisilazides, diisopropylamides, and tetramethylpiper-idides 13AG(E)11470. 

In contrast to the reaction with lithium amide, the sodium amide suspension immediately settles out after stopping the stirring and the supernatant ammonia has a grey or black colour, due to colloidal iron. In some cases it took a long time before all of the sodium had been converted (note 4). A further 0.1 g of iron(III) nitrate was then added to accelerate the reaction and some liquid ammonia was introduced to compensate for the losses due to evaporation. 

The formation of the above anions ("enolate type) depend on equilibria between the carbon compounds, the base, and the solvent. To ensure a substantial concentration of the anionic synthons in solution the pA" of both the conjugated acid of the base and of the solvent must be higher than the pAT -value of the carbon compound. Alkali hydroxides in water (p/T, 16), alkoxides in the corresponding alcohols (pAT, 20), sodium amide in liquid ammonia (pATj 35), dimsyl sodium in dimethyl sulfoxide (pAT, = 35), sodium hydride, lithium amides, or lithium alkyls in ether or hydrocarbon solvents (pAT, > 40) are common combinations used in synthesis. Sometimes the bases (e.g. methoxides, amides, lithium alkyls) react as nucleophiles, in other words they do not abstract a proton, but their anion undergoes addition and substitution reactions with the carbon compound. If such is the case, sterically hindered bases are employed. A few examples are given below (H.O. House, 1972 I. Kuwajima, 1976). 

A number of compounds of the types RSbY2 and R2SbY, where Y is an anionic group other than halogen, have been prepared by the reaction of dihalo- or halostibines with lithium, sodium, or ammonium alkoxides (118,119), amides (120), azides (121), carboxylates (122), dithiocarbamates (123), mercaptides (124,125), or phenoxides (118). Dihalo- and halostibines can also be converted to compounds in which an antimony is linked to a main group (126) or transition metal (127). 

Ruthenium(III) catalyses the oxidative decarboxylation of butanoic and 2-methylpropanoic acid in aqueous sulfuric acid. ° Studies of alkaline earth (Ba, Sr) metal alkoxides in amide ethanolysis and of alkali metal alkoxide clusters as highly effective transesterification catalysts were covered earlier. Kinetic studies of the ethanolysis of 5-nitroquinol-8-yl benzoate (228) in the presence of lithium, sodium, or potassium ethoxide revealed that the highest catalytic activity is observed with Na+.iio... 

The key reagents for the deprotonation of esters, acids and carbonyl compounds in general are the hindered metal amides, such as lithium diisopropylamide (1), lithium cyclohexyliso-propylamide (2) and lithium, sodium and potassium hexamethyldisilazanides (3). 

S)-2-Amino-3-methylbutanol [(S)-valinol] derived oxazolidinones, i.e., (S)-3-acyl-4-iso-propyl-2-oxazolidinones 1, have been used extensively for the preparation of a-alkylated acids, aldehydes and alcohols. The enolates are formed by deprotonation with lithium diisopropyl-amide or sodium hexamethyldisilazanide at low temperature in tetrahydrofuran. Subsequent addition of a haloalkane gives alkylation, which occurs from the Si-face2. The diastereoselectivities are usually good (>90 10), and the products are usually purified by flash chromatography and/or recrystallization (see Table 10). Additional examples of alkylation of 1 have been published5 l0 12- 20 22-29 39.44.-47,49.57.70-78... 

The intervening years have seen huge growth in the number of well-characterized compounds, the vast majority of which are lithium, sodium or potassium salts. Their strucuiral chemistry has proven to be especially rich and the number of structures of alkali metal amides currently available exceeds 200. These involve a wide selection of structural motifs that were mostly unknown in 1980. 

The overall sequence of three steps may be called the Wittig reaction, or only the final step. Phosphonium salts are also prepared by addition of phosphines to Michael olefins (like 5-7) and in other ways. The phosphonium salts are most often converted to the ylides by treatment with a strong base such as butyllithium, sodium amide,640 sodium hydride, or a sodium alkoxide, though weaker bases can be used if the salt is acidic enough. For (PhjP CHj, sodium carbonate is a strong enough base.641 When the base used does not contain lithium, the ylide is said to be prepared under "salt-free conditions.642... 

Like lithium, sodium and its compounds have been studied extensively in solution in liquid NH3. Sodium metal in such solutions slowly or with catalysis forms the amide, NaNH2. The solution of the metal is a powerful... 

A comprehensive group of polyesters contains hindered piperidine or piperazine (HALS) moieties. Most of these stabilizers were prepared under transesterification conditions, using tetraalkyl titanates, lithium amide or sodium alkoxide as catalysts. Terminal HALS group was built in under these conditions into a polyether-polyester. Polyester 145 was prepared from a reactive diester derived from piperazinedione and fljco-alkylidenediol (n = 2-15) [188], A similar system contains 2,2,6,6-tetramethylpiperidine moiety [189]. 

Liquid ammonia (b.p. -33°C) is a solvent which is not encountered frequendy, but which does have several important general uses, in particular dissolving metal reductions ("Birch" type reductions) and most reactions involving lithium amide or sodium amide as bases. Ammonia gas from a cylinder is condensed directly into the flask (Fig. 14.5). 

Typically, nonstabilized ylides are utilized for the synthesis of (Z)-alkenes. In 1986, Schlosser published a paper summarizing the factors that enhance (Z)-selectivity. Salt effects have historically been defined as the response to the presence of soluble lithium salts. Any soluble salt will compromise the (Z)-selectivity of the reaction, and typically this issue has been resolved by the use of sodium amide or sodium or potassium hexamethyldisilazane (NaHMDS or KHMDS) as the base. Solvent effects are also vital to the stereoselectivity. In general, ethereal solvents such as THF, diethyl ether, DME and t-butyl methyl ether are the solvents of choice." In cases where competitive enolate fomnation is problematic, toluene may be utilized. Protic solvents, such as alcohols, as well as DMSO, should be avoided in attempts to maximize (Z)-selectivity. Finally, the dropwise addition of the carbonyl to the ylide should be carried out at low temperature (-78 C). Recent applications of phosphonium ylides in natural product synthesis have been extensively reviewed by Maryanoff and Reitz. 

Metal amides can be added to ordinary nitriles e.g. lithium, sodium or magnesium amides), thus forming amide imide salts, which on addition of water or alcohol afford amidines. Some recent results demonstrate the wide applicability of the method, e.g. from metal amides and trialkoxyacetonitriles, tri-alkoxyacetamidines (319 Scheme 52) were prepared and from lithium imides and nitriles A -alkylide-neamidines (320) could be synthesized. 

Other bases may be employed, e.g. lithium hydride, sodium hydride, sodium amide or sodium in ethylene glycol with sodium in ethylene glycol, the reaction is called the Bamford-Stevens reaction. Aldehyde tosylhydrazones (200) do not form dianions with organolithiums, but the reagent adds to the carbon-nitrogen double bond to give the dilithium derivative (201) which decomposes to the organolithium compound (202). 

DABCO). 1,5-Diazabicy do [5,4,0 ] undec-ene-5 (DBU). Diethylamine. Ethylene-diamine. Lithio propylidene-f-buty limine. Lithium bis(trimethylsilyl)amide. Lithium f-butoxide. Lithium diethylamide. Lithium diisopropylamide. Lithium N-isopro-pylcyclohexylamide. Lithium orthophosphate. Lithium 2,2,6,6-tetramethylpiper-ide. Lithium triethylcarboxide. 1,2,2,6,6-Pentamethylpiperidine. Piperazine. Potassium f-butoxide. Potassium hexamethyldi-silaznae. Potassium hydride. Potassium hydroxide. Pyridine. 4-Pyrrolidopyridine. Quinuclidine. Sodium ethoxide. Sodium methoxide. Sodium thioethoxide. Tetra-methylguanidine. Thallous ethoxide. Tri-ethylamine. 

Phosgene reacts, sometimes violently, with a large number of common inorganic (Chapter 9) and organic (Chapter 10) substances. Hazardous reactions with lithium, sodium, potassium, aluminium, lithium amide, hexa-2,4-diyn-l, 6-diol, propan-2-ol, and hexafluoropropene have been mentioned specifically [1787]. Mixtures of potassium and phosgene are reported to explode when subjected to shock [1913a]. In addition, phosgene... 

Cyclopropene itself is readily metalated by treatment with lithium, sodium or potassium amide in liquid ammonia. On standing, the solutions are slowly converted into mixtures of products containing two or three three-membered rings. ... 

Deprotonation of carbonyl compounds by lithium dialkylamide bases is the single most common method of forming alkali enolates. Four excellent reviews have already been published. " Sterically hindered amide bases are employed to retard nucleophilic attack on the carbonyl group. The most common and generally useful bases are (i) lithium diisopropylamide (LDA 5) (ii) lithium isopropylcyclo-hexylamide (LICA 6) (iii) lithium 2,2,6,6-tetramethylpiperidide (LITMP 7) (iv) lithium hexamethyldisilylamide (LHMDS 8) and (v) lithium tetramethyldiphenyldisilylamide (LTDDS 9). Bases that are not amides include sodium hydride, potassium hydride and triphenylmethyllithium. 

Thermodynamic control. Note that it is also possible for the aldolate adduct to revert to aldehyde and enolate, and equilibration to the thermodynamic product may afford a different diastereomer (the anti aldolate is often the more stable). The tendency for aldolates to undergo the retro aldol addition increases with the acidity of the enolate amides < esters < ketones (the more stable enolates are more likely to fragment), and with the steric bulk of the substituents (bulky substituents tend to destabilize the aldolate and promote fragmentation). On the other hand, a highly chelating metal stabilizes the aldolate and retards fragmentation. The slowest equilibration is with boron aldolates, and increases in the series lithium < sodium < potassium, and (with alkali metal enolates) also increases in the presence of crown ethers. ... 

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