Structure and cation effects on phosphorus-31 NMR chemical shifts and chemical-shift anisotropies of orthophosphates

The principal componenls or the 3'P chemical shirt baser in six phosphonic acid suers and ~\\TJ phosphonic acids xverr determined. The chemical shirl anisorropies of the es~crs lie in rhr range herween 149 and 182 ppm and the asymmcq paramekrs between 0.1 and 0.5.

The effect of an offset term in the cross-polarization (CP) Hamiltonian of a heteronuclear spin-12 pair due to off-resonant radio frequency (rf) irradiation and/or chemical shift anisotropy on one of the rf channels is investigated. Analytical solutions, simulations, and experimental results are pre

The effects of organic solvents on the 3'P-mr chemical shifts of various phosphate diesters have been investigated in water and mixed-organic solvent systems. The addition of organic solvents to cyclic phosphates and to diethyl phosphate causes large upfield shifts of the phosphorus resonance which

Tricoordinate phosphorus NMR chemical shifts are computed (GIAO/6È311 ] G\*\*//RMP2(fc)/6È 31 ] G\*) and analyzed for molecules (X, F, OH, BeH, Li and H \ "simple Ðrst PX 2 Y Y \ EH n : N H 2 , CH 3 , BH 2 , row substituentsÏ), the "normalÏ d(31P) relationship with the substituent electronegativity

The source of conspicuous disagreement between theory and experiment for the chemical shift of C,~ in the 1-cyclopropylcyclopropylidenemethyl cation is identified as an inadequate treatment of electron correlation effects in a previous theoretical study. When the sophisticated CCSD(T) method is used