Fourier transform ion cyclotron resonance spectroscopy

An ion cyclotron resonance (ICR) absorption spectrum has been obtained by exciting an ICR spectral segment with a fixed-frequency electric field pulse, followed by broad-band detection, digitization of the (rime-domain) transient response, and digital Fourier transformation to produce the (frequency

This paper reports first use of 2 numeric3I decomalutian procedure for producing ampl'litudecarrccted, phwsecnrrectcd absorption-mode Fourier tmnsform ion cyclotron resonance fIT ICR) spectm. Compared to m;tSnirude-mode TT ICR spectral display, tk RCB metfiod =n enlwxe mass resolution by a factor of

A single ion cyctotron resonance (ICR) absorption spectrum showing both CH; and CHG signals has been obtained by exciting both ion cyclotron resonances with a frequency-swept rf irradiation, followed by broad-band detection, digitization of the (time-domain) response, and finally discrete Fourier tr

The development of Fourier transform ion cyclotron resonance (FT-ICR) spectroscopy is traced from its 1973 conception by analogy to Fourier transform nuclear magnetic resonance (FT-NMR) spectroscopy and its 1974 experimental demonstration to its 1978 demonstration as the technique of choice for exam