Your search keyword '"Butler I"' showing total 2 results

1. [Infrared and raman spectra studies of DL-homocysteic acid (DLH) and its lanthanum complex at high external pressure].

Author

Li WH, Xu ZH, Wu JG, and Butler IS

Subjects

Homocysteine chemistry, Hydrogen Bonding, Molecular Structure, Pressure, Stereoisomerism, Homocysteine analogs & derivatives, Lanthanum chemistry, Spectrophotometry, Infrared, Spectrum Analysis, Raman

Abstract

DL-Homocysteic acid (DLH, (NH3 )-CH(COOH)-(CH2 )2-SO3-) is extensively in existence as free amino-acid in the central nervous system of mammal. The infrared (IR) and Raman spectra of DL-Homocysteic acid (DLH) and its La complex [La (DLH)2Cl3 . H2O = LaL2] were measured at high external pressure. The DLH has two pressure-induced phase transitions (near 17 kbar and 37 kbar) and three pressure-phase areas below 50 kbar for there are ten intermolecular hydrogen bonds between the DLH molecules. But there is only one pressure-induced phase transition (near 27 kbar) to be observed in the complex LaL2. These show that the ten intermolecular hydrogen bonds of the DLH molecules changed due to the formation of complex LaL2. In infrared spectra, the changing trend of the pressure sensitivities (dv/dp) of symmetry stretching of SO3- in DLH and asymmetry stretching of SO3- in LaL2 are very different from the other vibrational modes when both compounds undergo high external pressure. In infrared spectra, the average pressure sensitivities of symmetry stretching of SO3- are: low-pressure phase area (0.30 cm(-1) x (kbar)(-1)) < middle-pressure phase area (0.32 cmn(-1) (kbar) (-1)) < high-pressure phase area (0.41 cm(-1) x (kbar)(-1)), but 0.86 cm(-1) x (kbar)(-1) (low-pressure phase area) >0.64 cm(-1) x (kbar)(-1) (middle-pressure phase area) >0.26 cm(-1) x (kbar)(-1) (high-pressure phase area) to other vibrational modes in DLH. The average pressure sensitivities of asymmetry stretching of SO3- in LaL2 are lower in low-pressure phase area than in high-pressure phase area, but the average pressure sensitivities of other modes are higher in low-pressure phase area than in high-pressure phase area.

Published

2005

2. [Raman and infrared spectral studies of tungsten organometallic carbyne complex at high external pressure].

Author

Xu ZH, Mayr A, and Butler IS

Subjects

Chelating Agents chemistry, Pressure, Spectrophotometry, Infrared, Spectrum Analysis, Raman, Carbamates chemistry, Organometallic Compounds chemistry, Tungsten chemistry

Abstract

The Raman and infrared spectra of complex: [Cl(CO)2 (DPPE) W identical to CC6H4C identical to CC6H4NC]2 Re Cl(CO)3 (DPPE = bis (diphenylphosphino) ethane, (Ph)2PCH2CH2P(Ph)2) were measured at high external pressure (up to about 50 kbar). The pressure induced phase transition was observed near 30 kbar. The pressure dependence d nu/dp of nu (W identical to C) at the low-pressure phase is a little high (0.59 cm-1.(kbar)-1) and is very low (0.04 cm-1.(kbar)-1) at the high-pressure phase. It shows that the pi-backbonding from W to pi*--orbital of CO is strengthened at the high external pressure in fragment Cl(CO)2 (DPPE) W identical to C; The bond intensity and the force constant of W identical to C and nu (W identical to C) are decreasing; This effect compete with the normal increasing nu (W identical to C) on compression.

Published

2001