Dipolar and quadrupolar detection using an FT-ICR MS setup at the MPIK Heidelberg

Heck, M.; Blaum, Klaus; Cakirli, R. B.; Rodriguez, D. Rodriguez; Schweikhard, L.; Ståhl, S.; Ubieto-Diaz, M.

doi:10.1007/s10751-011-0330-8

Cited by 9 publications

(6 citation statements)

References 27 publications

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“…However, the implemented ICR cells remained limited to serving particular questions of authors' interests in precision mass spectrometry of atomic ions. 41 Performance-wise, the reported mass (frequency) spectra demonstrated a visible contribution from the second harmonic of the reduced cyclotron frequency.…”

Section: ■ Introductionmentioning

confidence: 93%

Narrow Aperture Detection Electrodes ICR Cell with Quadrupolar Ion Detection for FT-ICR MS at the Cyclotron Frequency

Nagornov

Kozhinov

Nicol

et al. 2020

J. Am. Soc. Mass Spectrom.

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Ion signal detection at the true (unperturbed) cyclotron frequency instead of the conventional reduced cyclotron frequency has remained a formidable challenge since the inception of Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS). Recently, routine FT-ICR MS at the true cyclotron frequency has become a reality with the implementation of ICR cells with narrow aperture detection electrodes (NADEL). Here, we describe the development and implementation of the next generation of these cells, namely, a 2xNADEL ICR cell, which comprises four flat detect and four ∼45° cylindrical excite electrodes, enabling independent ion excitation and quadrupolar ion detection. The performance of the 2xNADEL ICR cell was evaluated on two commercial FT-ICR MS platforms, 10 T LTQ FT from Thermo Scientific and 9.4 T SolariX XR from Bruker Daltonics. The cells provided accurate mass measurements in the analyses of singly and multiply charged peptides (root-mean-square, RMS, mass error Δm/m of 90 ppb), proteins (Δm/m = 200 ppb), and petroleum fractions (Δm/m < 200 ppb). Due to the reduced influence of measured frequency on the space charge and external (trapping) electric fields, the 2xNADEL ICR cells exhibited stable performance in a wide range of trapping potentials (1–20 V). Similarly, in a 13 h rat brain MALDI imaging experiment, the RMS mass error did not exceed 600 ppb even for low signal-to-noise ratio analyte peaks. Notably, the same set of calibration constants was applicable to Fourier spectra in all pixels, reducing the need for recalibration at the individual pixel level. Overall, these results support further experimental development and fundamentals investigation of this promising technology.

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Section: ■ Introductionmentioning

confidence: 93%

Narrow Aperture Detection Electrodes ICR Cell with Quadrupolar Ion Detection for FT-ICR MS at the Cyclotron Frequency

Nagornov

Kozhinov

Nicol

et al. 2020

J. Am. Soc. Mass Spectrom.

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“…Interestingly, flat (wide aperture) excitation electrodes (capacitor configuration) may be considered to provide an optimum excitation field configuration; (2) simultaneous detection of a number of transients or detection at frequency multiples when several NADEL pairs are employed, for instance leading to an optimized design of the recently implemented quadruple frequency multiple detection ICR cell [36]; (3) enabling implementation of efficient quadrature ion excitation and quadrupolar ion detection schemes when two pairs of 90°wide excite electrodes and two NADEL pairs are employed without the need for a high-frequency switch between excitation and detection modes. Quadrupolar ion detection should further benefit high mass accuracy and high dynamic range demanding applications by providing measurements of trapping potential-insensitive unperturbed ion cyclotron frequency [23,55]; (4) creation of special ion motion conditions in ICR cell even with dipolar ion excitation leading to ion detection at unperturbed cyclotron frequency [56]; (5) facilitating and improving the efficiency of fluorescence-based ion spectroscopy due to substantially increased optical access to and from the cell [57][58][59]; and, last but not least, (6) enabling high throughput high-resolution mass spectrometry by accelerating ions to high post-excitation radii when, significantly, an order of magnitude higher resolving power can be obtained in the same ion detection period. The latter regime requires the development of the matching signal processing methods, capable of efficient analysis of periodic non-sinusoidal transients with high order harmonics [60].…”

Section: Nadel Icr Cell Concept Advantagesmentioning

confidence: 99%

“…Quadrupolar modes of ion excitation, including the quadrature excitation, are other attractive approaches for improving the coherence of excited ion motion [20][21][22][23]. ICR cell operation in these modes also suffers from the same low flexibility of the current ICR cell design, when wide aperture detection electrodes compete with the excitation electrodes for space.…”

Section: Introductionmentioning

confidence: 99%

Ion Trap with Narrow Aperture Detection Electrodes for Fourier Transform Ion Cyclotron Resonance Mass Spectrometry

Nagornov

Kozhinov

Tsybin

et al. 2015

J. Am. Soc. Mass Spectrom.

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Abstract. The current paradigm in ion trap (cell) design for Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) is the ion detection with wide aperture detection electrodes. Specifically, excitation and detection electrodes are typically 90°wide and positioned radially at a similar distance from the ICR cell axis. Here, we demonstrate that ion detection with narrow aperture detection electrodes (NADEL) positioned radially inward of the cell's axis is feasible and advantageous for FT-ICR MS. We describe design details and performance characteristics of a 10 T FT-ICR MS equipped with a NADEL ICR cell having a pair of narrow aperture (flat) detection electrodes and a pair of standard 90°excitation electrodes. Despite a smaller surface area of the detection electrodes, the sensitivity of the NADEL ICR cell is not reduced attributable to improved excite field distribution, reduced capacitance of the detection electrodes, and their closer positioning to the orbits of excited ions. The performance characteristics of the NADEL ICR cell are comparable with the state-of-the-art FT-ICR MS implementations for small molecule, peptide, protein, and petroleomics analyses. In addition, the NADEL ICR cell's design improves the flexibility of ICR cells and facilitates implementation of advanced capabilities (e.g., quadrupolar ion detection for improved mainstream applications). It also creates an intriguing opportunity for addressing the major bottleneck in FTMS-increasing its throughput via simultaneous acquisition of multiple transients or via generation of periodic non-sinusoidal transient signals.

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“…A detailed description can be found in Refs. [30,31]. The trap is placed in an ultra-high vacuum system, i.e.…”

Section: Experimental Setup and Timing Structurementioning

confidence: 99%

“…(a) Schematic view of the FT-ICR setup[30,31]. The Penning trap is placed in a homogeneous region of the magnetic field.…”

mentioning

confidence: 99%

One- and two-pulse quadrupolar excitation schemes of the ion motion in a Penning trap investigated with FT-ICR detection

et al. 2012

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In a Penning ion trap the interconversion between the radial motional modes of stored particles can be accomplished by applying one- and two-pulse (Ramsey) azimuthal quadrupolar radio frequency fields. In this work the interaction of ions with the excitation fields has been probed by Fourier transform ion cyclotron resonance (FT-ICR) detection. A theoretical description of this interaction is derived by use of a quasi-classical coherent state and the interconversion of modes is interpreted in a quantum-mechanical context. The dipolar-detection FT-ICR signal at the modified cyclotron frequency has been studied as a function of the interaction parameters such as excitation frequency, amplitude and duration and is compared with the theoretical results

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Dipolar and quadrupolar detection using an FT-ICR MS setup at the MPIK Heidelberg

Cited by 9 publications

References 27 publications

Narrow Aperture Detection Electrodes ICR Cell with Quadrupolar Ion Detection for FT-ICR MS at the Cyclotron Frequency

Narrow Aperture Detection Electrodes ICR Cell with Quadrupolar Ion Detection for FT-ICR MS at the Cyclotron Frequency

Ion Trap with Narrow Aperture Detection Electrodes for Fourier Transform Ion Cyclotron Resonance Mass Spectrometry

One- and two-pulse quadrupolar excitation schemes of the ion motion in a Penning trap investigated with FT-ICR detection

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