Methods for operating electrostatic trap mass analyzers

What is claimed is: 1. A method of operating an electrostatic trapping mass analyzer, comprising: introducing a sample of ions from a population of ions into a trapping region of the mass analyzer, wherein an established trapping field within the trapping region is such that ions of the introduced sample of ions are caused to exhibit radial motion with respect to a central longitudinal axis of the trapping region while undergoing harmonic motion in a dimension z defined by the central longitudinal axis of the trapping region, the frequency of harmonic motion of a particular ion being a function of its mass-to-charge ratio; superimposing a multi-frequency periodic modulation field onto the trapping field within the trapping region, wherein the multi-frequency periodic modulation field comprises a plurality of component frequencies, each component frequency associated with a respective amplitude and a respective phase offset, and wherein the multi-frequency periodic modulation field acts to either increase or reduce the harmonic motion energies of the ions by an amount varying according to the frequency of harmonic motion; and acquiring a mass spectrum of the ions in the trapping region by measuring a signal representative of an image current induced by the harmonic motion of the ions, wherein the plurality of component frequencies and the plurality of phase offsets are determined from an analysis of a prior signal generated by the electrostatic trapping mass analyzer in response to a prior introduction of a different sample of ions from the population of ions into the trapping region. 2. A method as recited in claim 1 , wherein the plurality of component frequencies are determined from a transform of the prior signal and the plurality of phase offsets are determined from phase corrections applied to imaginary and real components of the transform of the prior signal. 3. A method as recited in claim 1 , wherein the superimposing of the modulation field onto the trapping field is such that a spectral resolution of the mass spectrum is improved as compared to a mass spectrum of the sample of ions obtained using the mass analyzer in the absence of the superimposing of the modulation field onto the trapping field within the trapping region. 4. A method as recited in claim 1 , wherein the introducing of the sample of ions into the trapping region comprises introducing the ions into a trapping region defined by: an inner spindle electrode having an outer surface that is axially symmetric about the longitudinal axis and that is symmetric about a central equatorial plane that is perpendicular to the longitudinal axis; and a pair of outer electrodes disposed at either side of the equatorial plane and having respective inner surfaces, wherein the outer surface of the inner spindle electrode and the inner surfaces of the outer electrodes are shaped such that a trapping potential corresponding to the trapping field is a quadro-logarithmic potential that is established by application of an electrostatic voltage difference between the inner spindle electrode and the outer electrodes. 5. A method as recited in claim 1 , wherein the introducing of the sample of ions into the trapping region comprises introducing the sample of ions into a trapping region of a Cassinian trap mass analyzer. 6. A method as recited in claim 4 , wherein the superimposing of the periodic modulation field onto the trapping field is performed by: applying a periodic voltage waveform across the pair of outer electrodes or between the inner spindle electrode and one of the outer electrodes. 7. A method as recited in claim 4 , wherein the superimposing of the periodic modulation field onto the trapping field is performed by: applying a periodic voltage waveform between the inner spindle electrode and both of the outer electrodes, wherein there is no potential difference between the outer electrodes. 8. A method of operating an electrostatic trapping mass analyzer, comprising: introducing a sample of ions from a population of ions into a trapping region of the mass analyzer, wherein an established trapping field within the trapping region is such that ions of the introduced sample of ions are caused to exhibit radial motion with respect to a central longitudinal axis of the trapping region while undergoing harmonic motion in a dimension z defined by the central longitudinal axis of the trapping region, the frequency of harmonic motion of a particular ion being a function of its mass-to-charge ratio; superimposing a multi-frequency periodic modulation field onto the trapping field within the trapping region, wherein the multi-frequency periodic modulation field comprises a plurality of component frequencies, each component frequency associated with a respective amplitude and a respective phase offset, wherein the multi-frequency periodic modulation field acts to either increase or reduce the harmonic motion energies of the ions by an amount varying according to the frequency of harmonic motion; and acquiring a mass spectrum of the ions in the trapping region by measuring a signal representative of an image current induced by the harmonic motion of the ions, wherein the plurality of component frequencies and the plurality of phase offsets are determined from an analysis of a prior signal generated by the electrostatic trapping mass analyzer in response to a prior introduction of a set of calibrant ions into the trapping region prior to the superimposing of the multi-frequency periodic modulation field onto the trapping field. 9. A method as recited in claim 8 , wherein the plurality of component frequencies are determined from a transform of the prior signal and the plurality of phase offsets are determined from phase corrections applied to imaginary and real components of the transform of the prior signal. 10. A method as recited in claim 8 , wherein the superimposing of the modulation field onto the trapping field is such that a spectral resolution of the mass spectrum is improved as compared to a mass spectrum of the sample of ions obtained using the mass analyzer in the absence of the superimposing of the modulation field onto the trapping field within the trapping region. 11. A method as recited in claim 8 , wherein the introducing of the sample of ions into the trapping region comprises introducing the ions into a trapping region defined by: an inner spindle electrode having an outer surface that is axially symmetric about the longitudinal axis and that is symmetric about a central equatorial plane that is perpendicular to the longitudinal axis; and a pair of outer electrodes disposed at either side of the equatorial plane and having respective inner surfaces, wherein the outer surface of the inner spindle electrode and the inner surfaces of the outer electrodes are shaped such that a trapping potential corresponding to the trapping field is a quadro-logarithmic potential that is established by application of an electrostatic voltage difference between the inner spindle electrode and the outer electrodes. 12. A method as recited in claim 8 , wherein the introducing of the sample of ions into the trapping region comprises introducing the sample of ions into a trapping region of a Cassinian trap mass analyzer. 13. A method as recited in claim 11 , wherein the superimposing of the periodic modulation field onto the trapping field is performed by: applying a periodic voltage waveform across the pair of outer electrodes or between the inner spindle electrode and one of the outer electrodes. 14. A method as recited in claim 11 , wherein the superimposing of the periodic modulat