Chien Chung Liou scite author profile

Ladders of relative alkali ion affinities of crown ethers and acyclic analogs were constructed by using the kinetic method. The adducts consisting of two different ethers bound by an alkali metal ion, (M1 + Cat + M2)(+), were formed by using fast atom bombardment ionization to desorb the crown ethers and alkali metal ions, then collisionally activated to induce dissociation to (M1 + Cat)(+) and (M2 + Cat)(+) ions. Based on the relative abundances of the cationized ethers formed, orders of relative alkali ion affinities were assigned. The crown ethers showed higher affinities for specific sizes of metal ions, and this was attributed in part to the optimal spatial fit concept. Size selectivities were more pronounced for the smaller alkali metal ions such as Li(+), Na(+), and K(+) than the larger ions such as Cs(+) and Rb(+). In general, the cyclic ethers exhibited greater alkali metal ion affinities than the corresponding acyclic analogs, although these effects were less dramatic as the size of the alkali metal ion increased.

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New frontiers in host-guest chemistry: The gas phase

Brodbelt¹,

Liou²

1993

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Comparison of gas-phase proton and ammonium ion affinities of crown ethers and related acyclic analogs

Liou¹,

Brodbelt²

1992

J. Am. Chem. Soc.

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Hydrogen-bonding interactions in gas-phase polyether/ammonium ion complexes

Liou

Brodbelt

1994

J. Am. Soc. Mass Spectrom.

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Hydrogen bonds are among the most important interactions involved in selective complexation in host-guest chemistry. In this study a variety of hydrogen-bonded crown ether/ammonium ion complexes are generated in the gas phase by association reactions between an amine substrate and a polyether, one of which is initially protonated, and stabilized by many collisions in the chemical ionlzation source of a triple quadrupole mass spectrometer or in a quadrupole ion trap. The nature of the hydrogen-bonding interactions of the ion complexes are evaluated by comparison of their collision-activated dissociation spectra. After collisional activation, those complexes that are weakly bound dissociate to form intact protonated polyether molecules and/or ammonium ions by simple cleavages of the hydrogen-bond association interactions. In contrast, those complexes strongly bound by multiple hydrogen bonds dissociate not only to the protonated polyether and/or ammonium ions but also by extensive covalent bond cleavage of the protonated ether skeleton.This latter type of dissociation behavior suggests that the polyether/ammonium ion complexes may be sufficiently strongly bound that surpassing the high barrier to decomposition results in formation of internally excited polyether molecules that may then undergo subsequent fragmentation by skeletal cleavages. Moreover, complexes involving multiple hydrogen bonds may have slower dissociation kinetics, allowing competition from fast dissociation processes that have substantial energy barriers.

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Chien Chung Liou

Selective adduct formation by dimethyl ether chemical ionization in a quadrupole ion trap mass spectrometer and a conventional ion source

Determination of orders of relative alkali metal ion affinities of crown ethers and acyclic analogs by the kinetic method

New frontiers in host-guest chemistry: The gas phase

Comparison of gas-phase proton and ammonium ion affinities of crown ethers and related acyclic analogs

Hydrogen-bonding interactions in gas-phase polyether/ammonium ion complexes

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