Patent application number | Description | Published |
20080251712 | MEASUREMENT OF THE MOBILITY OF MASS-SELECTED IONS - The mobility of mass-selected ions in gases is measured at pressures of a few hectopascal by selecting the ions under investigation in a quadrupole filter according to their mass-to-charge ratio m/z, measuring their mobility in a drift region at a pressure of a few hundred Pascal under the influence of a DC electric field and then filtering the measured ions by means of a quadrupole field in order to eliminate, or detect changes in, the mass-to-charge ratio. Several embodiments for the drift region are disclosed, in which the ions are kept in the axis of the drift region by RF fields. As these drift regions can also be utilized for a collision-induced decomposition of the ions, the device can additionally be used as a so-called triple quadrupole mass spectrometer. | 10-16-2008 |
20090084948 | OVERCOMING SPACE CHARGE EFFECTS IN ION CYCLOTRON RESONANCE MASS SPECTROMETERS - In an ion cyclotron resonance mass spectrometer in which ions are trapped axially by applying electrical potentials to a pattern of electrode elements to produce an inhomogeneous alternating radio-frequency electric field with a repulsive effect, an additional electrostatic ion-attracting field is superimposed on the repulsive electric field. The voltage of the ion-attracting field is adjusted to compensate for a cyclotron frequency shift of the ions caused by the ion space charge. The voltage of the ion-attracting field can be adjusted so that the ion cyclotron frequency of all ions becomes independent of the number of ions inside the spectrometer. | 04-02-2009 |
20100090102 | ION MOBILITY MEASUREMENT AT A POTENTIAL BARRIER - Ion mobilities are measured by entraining the ions in a gas and adiabatically expanding the ion-containing gas through a nozzle to form a gas jet. An electrical field barrier with variable height is located at the nozzle exit. The field barrier may be located adjacent to the nozzle exit or an ion guide may be located between the nozzle and the field barrier. If a continuous ion current is supplied, the height of the barrier is varied and the ion current of the ions passing over the barrier is measured, the ion current can be differentiated to generate a mobility spectrum. Alternatively, the ions can be temporarily stored in the ion guide so that measurement of the ion current of the ions passing over the barrier results in a direct measurement of the mobility spectrum. | 04-15-2010 |
20100207020 | HIGH MASS RESOLUTION WITH ICR MEASURING CELLS - The compensation potentials on the compensation electrodes of an ICR measuring cell are sequentially adjusted so that an ICR measurement with the longest possible usable image current transient is produced. Then, subsequent ICR measurements are made using the ICR cell with the optimally adjusted compensation potentials. Depending on the kind of ion mixture involved, measurements with image current transients from 10 to more than 20 seconds long can be performed, from which mass spectra with a maximum mass resolution without peak coalescence can be obtained. | 08-19-2010 |
20140042315 | COMPACT ION MOBILITY SPECTROMETER - The invention relates to devices for measuring the mobility of ions in gases at pressures of a few hectopascal. To make the device more compact, drift regions are bent into curved shapes, which extend into the third dimension. Parts of the drift region may lie above others. Alternating directions of curvature in the curved shapes balance out different path lengths by passing through approximately equal drift distances on outer and inner trajectories. Ions are held near the axis of the curved drift region by sectional or permanent focusing. One possible shape is a double loop in the shape of a figure eight. The shape extends perpendicular to its plane of projection so that several double loops lie on top of each other. RF ion funnels or ion tunnels can keep the ions near the axis. Axial focusing may use a pseudopotential radial to the axis of the curved shape. | 02-13-2014 |
20140061458 | EXCITATION OF IONS IN AN ICR-CELL WITH STRUCTURED TRAPPING ELECTRODES - In an ion cyclotron resonance cell, which is enclosed at its ends by electrode structure elements with DC voltages of alternating polarity, longitudinal electrodes are divided so that the ICR measurement cell between the electrode structure elements consists of at least three sections. An excitation of ion cyclotron motions can be performed by applying additional trapping voltages to longitudinal electrodes located closest to the electrode structure elements and introducing ions into the center set of longitudinal electrodes. The ions are then excited into cyclotron orbits by applying radiofrequency excitation pulses to at least two rows of longitudinal electrodes to produce orbiting ion clouds. Subsequently, the additional trapping voltages are removed and an ion-attracting DC voltage is superimposed on the DC voltages. Ions excited to circular orbits can be detected using detection electrodes in the outer ICR cell sections. | 03-06-2014 |