Cylindrical Demagnetization Fields and Microprobe Design in High-Resolution NMR

The microscopic magnetic-induction field ''seen by each nuwork which relations can be safely extended to the present cleus'' in a material medium and which is generated by a rapidly NMR context in which the nuclear spin magnetization is time-dependent spin magnetization gives rise to surprising new

In Part I, we review some basic physics, properties, and types of magnetism ( ) as they relate to high-resolution nuclear magnetic resonance NMR probe design, both in liquids and in solids, and some of the reasons it is technically difficult to obtain resolution of several parts per billion. We note

Various issues affecting nuclear magnetic resonance probe resolution are ( ) discussed, with emphasis on high-resolution or magic angle spinning MAS in this part. Symmetric positioning of chip capacitors at the magic angles addresses the largest B 0 perturbation with ultra-low-inductance decoupling

We describe a new and powerful computer program called TRIPLE\_GRADIENT which calculates optimized pulsed field gradient sequences for specific coherence pathway selection or rejection. Sequences can be computed for gradient coils acting along one, two, or three perpendicular axes. The program is ba

In a recent publication we presented a method to obtain highly resolved NMR spectra in the presence of an inhomogeneous B 0 field with the help of a matched RF gradient. If RF gradient pulses are combined with "ideal" 90 • pulses to form inhomogeneous z rotation pulses, the line broadening caused by