Frequency dependence of pulsed EPR experiments

Direct measurements of electron spin-echo signal and noise in well-characterized X-band and S-band spectrometers agree with predictions of frequency dependence based on first principles. For the particular spectrometers compared, the echo at 9.52 GHz was 9.5 times larger than the echo at 2.68 GHz, a

The phase-inverted echo-amplitude detected nutation (PEA-Another parameter for labeling individual EPR transitions NUT) experiment for the measurement of transient electron spin is the transition moment, which is in general different for nutation frequencies is introduced. In this new pulse sequence

The electron paramagnetic resonance pulsed free induction decay (FID) of a degassed solution of a triaryl methyl radical, methyl tris(8-carboxy-2,2,6,6-tetramethyl(-d3)-benzo[1,2-d:4,5-d']bis(1,3)dithiol-4-yl) tripotassium salt, 0.2 mM in H2O, was measured at VHF (247.5 MHz) and L-band (1.40 GHz). T

Experimental EPR signal intensities at 250 MHz, 1.5 GHz, and 9.1 GHz agree within experimental error with predictions from first principles. When both the resonator size and the sample size are scaled with the inverse of RF/microwave frequency, ω, the EPR signal at constant B 1 scales as ω -1/4 . Co

A microwave two-pulse sequence with a weak and long 180°fi rst pulse and a hard 90°second pulse is employed to detect nuclear coherences in pulsed EPR. The coherences created by the first pulse are transferred after an evolution period T into an observable FID by the second pulse. The free induction