High magnetic field 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

It is well-known that mass resolving power in Fourier transform ion cyclotron resonance mass spectrometry (FTICR MS) can increase linearly with increasing applied magnetic field induction, B. Here, we show that eight other FTICR primary performance parameters theoretically also increase linearly (qu

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 world's first national high-field Fourier transform ion cyclotron resonance (FTICR) mass spectrometry facility began unofficiallly with the arrival in September 1993 of Alan Marshall and Shenheng Guan at the U.S.A. National High Magnetic Field Laboratory in Tallahassee,