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Open-chain cryptands

New "Open-Chain Cryptands" with Specific Ion Transport Abilities... [Pg.103]

NEW OPEN-CHAIN CRYPTANDS WITH SPECIFIC ION TRANSPORT ABILITIES... [Pg.105]

As a new series of "open-chain cryptands", "multi-armed cyclams" were designed and employed in the cation transport experiments. Parent polyamine macrocycle (cyclam) is well known to show somewhat different cation binding properties from those of macrocyclic polyethers. It effectively bind ammoniiim cations via strong hydrogen bonding as well as transition metal cations via coordination interaction. Hence, new "multi-armed cyclams" are expected to exhibit unique cation transport abilities. Their cation transport results are summarized in Table 3. [Pg.108]

Podand Open-chained (acyclic) analogs of either coronands or cryptands. [Pg.8]

The synthesis of 1,10-diaza-l 8-crown-6 (9) has been an important problem because this is the key starting material in the synthesis of numerous cryptands (see Chap. 8). Although first synthesized some years ago, the process has recently been patented. Di-azacrown 9 is prepared by a high dilution condensation of 1,8-diamino-3,7-dioxaoctane with ethylene glycol diacetyl chloride. The resulting diamide is then reduced with lithium aluminum hydride to give 9 in 56% overall yield from the open-chained diamine. The synthesis is illustrated In Eq. (4.8), below. [Pg.160]

In specific applications to phase transfer catalysis, Knbchel and his coworkers compared crown ethers, aminopolyethers, cryptands, octopus molecules ( krakenmole-kiile , see below) and open-chained polyether compounds. They determined yields per unit time for reactions such as that between potassium acetate and benzyl chloride in acetonitrile solution. As expected, the open-chained polyethers were inferior to their cyclic counterparts, although a surprising finding was that certain aminopolyethers were superior to the corresponding crowns. [Pg.312]

The bulk of the work which has been performed on open-chained crown ether and cryptand equivalents, especially for application to general cation binding studies has been accomplished by Vogtle and his coworkers. Vogtle has reviewed both his own and other work in this field . [Pg.316]

The preparation of novel phase transfer catalysts and their application in solving synthetic problems are well documented(l). Compounds such as quaternary ammonium and phosphonium salts, phosphoramides, crown ethers, cryptands, and open-chain polyethers promote a variety of anionic reactions. These include alkylations(2), carbene reactions (3), ylide reactions(4), epoxidations(S), polymerizations(6), reductions(7), oxidations(8), eliminations(9), and displacement reactions(10) to name only a few. The unique activity of a particular catalyst rests in its ability to transport the ion across a phase boundary. This boundary is normally one which separates two immiscible liquids in a biphasic liquid-liquid reaction system. [Pg.143]

The results (Table 10) show that the cryptands could act to produce carrier-mediated facilitated diffusion and there was no transport in the absence of the carrier. The rate of transport depended upon the cation and carrier, and the transport selectivity differed widely. The rates were not proportional to complex stability. There was an optimal stability of the cryptate complex for efficient transport, logKs 5, and this value is similar to that for valinomycin (4.9 in methanol). [3.2.2] and [3.3.3] showed the same complexation selectivity for Na+ and K+ but opposing transport selectivities. The structural modification from [2.2.2] to [2.2.C8] led to an enhanced carriage of both Na+ and K+ but K+ was selected over Na+. The modification changes an ion receptor into an ion carrier, and indicates that median range stability constants are required for transport. Similar, but less decisive, results have been found in experiments using open-chain ligands and crown ethers.498... [Pg.55]

An additional nuance in the nomenclature of these compounds concerns their complexes. The open-chained compounds are often referred to as podands and their complexes as podates. The cyclic ethers may also be called coronands and their complexes are therefore coronates. Complexed cryptands are cryptates. The even more complicated structures known as spherands, cavitands, or carcerands are called spherates, cavitates, or carcerates, respectively, when complexed. The combination of a macrocycle (crown ether or coro-nand) and a sidechain (podand) is typically called a lariat ether. [Pg.34]

The crown ethers form stable complexes with many cations, both inorganic and organic, as well as neutral species. As would be expected, the Macrocyclic Effect see Macrocycle) provides a significant contribution to this stability. For example, the stability constant of the K+ complex of 18-crown-6 in anhydrous methanol is 10 , whereas the complex of the open chain analog has a stability constant of 10. The tricyclic cryptands are even more preorganized, and generally form more stable complexes than the corresponding crown... [Pg.5070]

The open-chain tripodal ligands, 7a and 7c, yield remarkable extraction of ReO4 at pH 7.4. From among the amino cryptands investigated, only ligand 7d gives similar extraction to that observed for 7a and 7b, whereas 7e yields a comparable... [Pg.92]

See other pages where Open-chain cryptands is mentioned: [Pg.1106]    [Pg.1116]    [Pg.171]    [Pg.103]    [Pg.109]    [Pg.1106]    [Pg.1116]    [Pg.171]    [Pg.103]    [Pg.109]    [Pg.311]    [Pg.38]    [Pg.117]    [Pg.122]    [Pg.289]    [Pg.24]    [Pg.3]    [Pg.368]    [Pg.48]    [Pg.147]    [Pg.142]    [Pg.161]    [Pg.146]    [Pg.184]    [Pg.134]    [Pg.275]    [Pg.127]    [Pg.3]    [Pg.5069]    [Pg.1887]    [Pg.289]    [Pg.99]    [Pg.249]    [Pg.250]    [Pg.196]    [Pg.790]    [Pg.883]    [Pg.340]   
See also in sourсe #XX -- [ Pg.103 ]



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Cryptands 2.1.1 [cryptand

Open-chain

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