0000000000067453

AUTHOR

Aravindhan Ganesan

showing 2 related works from this author

Density functional study of Cu2+-phenylalanine complex under micro-solvation environment

2013

Abstract We present an atomistic study carried out using density functional calculations including structural relaxations and Car–Parrinello Molecular Dynamics (CPMD) simulations, aiming to investigate the structures of phenylalanine-copper (II) ([Phe-Cu] 2+ ) complexes and their micro-solvation processes. The structures of the [Phe-Cu] 2+ complex with up to four water molecules are optimized using the B3LYP/6-311++G** model in gas phase to identify the lowest energy structures at each degree of solvation ( n  = 0–4). It is found that the phenylalanine appears to be in the neutral form in isolated and mono-hydrated complexes, but in the zwitterionic form in other hydrated complexes (with n …

Models MolecularCar–Parrinello molecular dynamicsPhenylalanineMolecular ConformationDFTMolecular dynamicsMaterials ChemistryMicro-solvationMoleculePhysical and Theoretical ChemistryPhenylalanine-copper (II) complexStructural motifta116Spectroscopyta114LigandHydrogen bondChemistrySolvationHydrogen BondingComputer Graphics and Computer-Aided DesignCrystallographySolvation shellModels ChemicalCPMDCopperJOURNAL OF MOLECULAR GRAPHICS AND MODELLING
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CPMD simulation of Cu2+ -- phenylalanine complex under micro-solvated environment

2013

The study combines DFT calculations and CPMD simulations to investigate the structures of phenylalanine-copper (II) ([Phe-Cu]2+) complexes and the micro-solvation processes. ....It is found that the phenylalanine moiety appears to be in the neutral form in isolated and mono-hydrated complexes, but in the zwitterionic form in other hydrated complexes (with n no less than 2). .... The present CPMD simulations reveal that the maximum coordination of Cu2+ in the presence of the Phe ligand does not exceed four: the oxygen atoms from three water molecules and one carboxyl oxygen atom of Phe. Any excess water molecules will migrate to the second solvation shell. Moreover a unique structural motif …

Chemical Physics (physics.chem-ph)Physics - Chemical PhysicsFOS: Physical sciences
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