K+ ions seemingly permeate K-channels rapidly because channel binding sites mimic coordination of K+ ions in water. Highly selective ion discrimination should occur when binding sites form rigid cavities that match K+, but not the smaller Na+, ion size or when binding sites are composed of specific chemical groups. Although conceptually attractive, these views cannot account for critical observations: 1), K+ hydration structures differ markedly from channel binding sites; 2), channel thermal fluctuations can obscure sub-Angström differences in ion sizes; and 3), chemically identical binding sites can exhibit diverse ion selectivities. Our quantum mechanical studies lead to a novel paradigm that reconciles these observations. We find that K-channels utilize a "phase-activated" mechanism where the local environment around the binding sites is tuned to sustain high coordination numbers (>6) around K+ ions, which otherwise are rarely observed in liquid water. When combined with the field strength of carbonyl ligands, such high coordinations create the electrical scenario necessary for rapid and selective K+ partitioning. Specific perturbations to the local binding site environment with respect to strongly selective K-channels result in altered K+/Na+ selectivities.
A theoretical treatment based upon the quasi-chemical theory of solutions predicts the most probable number of water neighbors in the inner shell of a Li + ion in liquid water to be four. The instability of a six water molecule inner sphere complex relative to four-coordinated structures is confirmed by an 'ab initio' molecular dynamics calculation. A classical Monte Carlo simulation equilibrated 26 water molecules with a rigid six-coordinated Li(H 2 O) 6 + complex with periodic boundary conditions in aqueous solution. With that initial configuration for the molecular dynamics, the six-coordinated structure relaxed into four-coordinated arrangements within 112 fs and stabilized. This conclusion differs from prior interpretations of neutron and X-ray scattering results on aqueous solutions. * LA-UR-99-3360.
Fluoroethylene carbonate (FEC) shows promise as an electrolyte additive for improving passivating solid-electrolyte interphase (SEI) films on silicon anodes used in lithium ion batteries (LIB).We apply density functional theory (DFT), ab initio molecular dynamics (AIMD), and quantum chemistry techniques to examine excess-electron-induced FEC molecular decomposition mechanisms that lead to FEC-modified SEI. We consider one-and two-electron reactions using cluster models and explicit interfaces between liquid electrolyte and model Li x Si y surfaces, respectively. FEC is found to exhibit more varied reaction pathways than unsubstituted ethylene carbonate.The initial bond-breaking events and products of one-and two-electron reactions are qualitatively similar, with a fluoride ion detached in both cases. However, most one-electron products are chargeneutral, not anionic, and may not coalesce to form effective Li + -conducting SEI unless they are further reduced or take part in other reactions. The implications of these reactions to silicon-anode based LIB are discussed.
Potassium channels and valinomycin molecules share the exquisite ability to select K(+) over Na(+). Highly selective K channels maintain a special local environment around their binding sites devoid of competing hydrogen bond donor groups, which enables spontaneous transfer of K(+) from states of low coordinations in water into states of over-coordination by eight carbonyl ligands. In such a phase-activated state, electrostatic interactions from these 8-fold binding sites, constrained to maintain high coordinations, result in K(+)/Na(+) selectivity with no need for a specific cavity size. Under such conditions, however, direct coordination from five or six carbonyl ligands does not result in selectivity. Yet, valinomycin molecules achieve selectivity by providing only six carbonyl ligands. Does valinomycin use additional coordinating ligands from the solvent or does it have special structural features not present in K channels? Quantum chemical investigations undertaken here demonstrate that valinomycin selectivity is due to cavity size constraints that physically prevent it from collapsing onto the smaller sodium ion. Valinomycin enforces these constraints by using a combination of intramolecular hydrogen bonds and other structural features, including its specific ring size and the spacing between its connected ligands. Results of these investigations provide a consistent explanation for the experimental data available for the ion-complexation properties of valinomycin in solvents of varying polarity. Together, investigations of these two systems reveal how nature, despite being popular for its parsimony in recycling functional motifs, can use different combinations of phase, coordination number, cavity size, and rigidity (constraints) to achieve K(+)/Na(+) selectivity.
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