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MuSR /
InitialPhase< Setup, calibrations and analysis: more details | Index | FFT Amplitudes > Initial Phase in a transverse field experiment (e.g. GPS) When a magnetic field is applied longitudinally to the muon beam - say, along z - the incoming muons travel along the lines of the stray magnetic field of the magnet. If the muon spin has initially a component transverse to z, as in when the Spin Rotator is active, this component starts to precess before implantation. The time of implantation is taken as zero for any subsequent analysis but in this case a sizeable, field dependent initial phase must be taken into account. This extra initial phase is not present, of course, if the external field is zero and the spin precession is due to an internal field, e.g. if one has turned the Spin Rotator on, and the sample is single crystalline, with internal field along z. Specifically, for the present magnet wiring of GPS (2005):
{$ d\phi = 2 \pi \nu dt $} in radiant for each frequency ν, or, equivalently {$ d\phi = 360 \nu dt $} in degrees. Hence the phase could be determined precisely from a calibration experiment with a suitable sample, providing a spectrum of few narrow frequencies, both low and high.
{$ d\phi = \frac{d\phi}{dB} B $} and for GPS the derivative of φ with respect to B is equal to 0.0231 degree per Oersted within the same errorbar of Eq. (2). This initial phase is the same that would be acquired if the muons where let to precess in the field at the sample for a time {$ \Delta t = \frac{d \phi}{dB} \frac {1}{360 \gamma} = 4.7355 \mbox{ns} $} with {$\gamma= 0.000001355$} GHz/Oe and {$d\phi/dB$} in deg/Oe. < Setup, calibrations and analysis: more details | Index | FFT Amplitudes > |