Design considerations for a cycloidal mass analyzer using a focal plane array detector

Horvath, Kathleen L.; Piacentino, Elettra L.; Serpa, Rafael Bento; Aloui, Tanouir; Vyas, Raul; Zhilichev, Yuriy; Windheim, Jesko von; Sartorelli, M. L.; Denton, M. Bonner; Gehm, Michael E.; Glass, Jeffrey T.; Amsden, Jason J.

doi:10.1002/jms.4874

Cited by 2 publications

(1 citation statement)

References 67 publications

(157 reference statements)

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“…As a result, computational reconstruction of the coded spectral data measured at the array detector is simplified because the coded aperture image projected across the detector plane does not exhibit distortion. Spectral reconstruction can be performed under the assumption of a shift-invariant instrument response function (system response function is constant as a function of the system parameters such as electric field, magnetic field, ion mass to charge ratio, and ion velocity) and only requires a simple deconvolution of the aperture image to reconstruct the mass spectrum. − ,− In contrast, 90-degree and Mattauch-Herzog mass analyzers generate a distorted image of the coded aperture at the detector plane and require a more complex reconstruction process . However, reconstruction of experimental spectral data using a cycloidal mass analyzer with a shift-invariant system response can lead to reconstruction artifacts because nonidealities such as field nonuniformity, misalignment, and shallow depth of focus can result in a system response function that varies as a function of the system parameters .…”

Section: Introductionmentioning

confidence: 99%

Spectral Reconstruction Improvement in a Cycloidal Coded-Aperture Mass Spectrometer

Aloui,

Vyas,

Francini

et al. 2024

J. Am. Soc. Mass Spectrom.

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Spatial aperture coding is a technique used to improve throughput without sacrificing resolution both in optical spectroscopy and sector mass spectrometry (MS). Previous work demonstrated that aperture coding combined with a position-sensitive array detector in a miniature cycloidal mass spectrometer was successful in providing high-throughput, high-resolution measurements. However, due to poor alignment and field nonuniformities, reconstruction artifacts were present. Recently, significant progress was made in eliminating most of the reconstruction artifacts with improved field uniformity and alignment. However, artifacts as large as 1/3 of the main peak were still observed at low mass (<17 u). Such artifacts will reduce accuracy in identification and quantification of analytes, reducing the impact of the throughput advantage gained by using a coded aperture. The artifacts were hypothesized to be a result of a mass dependent in curvature of ions in the ion source. Ions with higher mass (m/z > 17 u) and a larger curvature did not pass through all slits in the coded aperture. Therefore, when reconstructing with a system response derived from the aperture image from a higher mass m/z = 32 u ion, reconstruction artifacts appeared for m/z < 17 u. In this work, two methods were implemented to significantly reduce the presence of artifacts in reconstructed data. First, we modified the reconstruction algorithm to incorporate a mass-dependent system response function across the mass range (10–110 u). This method reduced the size of the artifacts by 82%. Second, to validate the hypothesis that the mass-dependent system response function was a result of differences in curvature of ions in the ion source, we modified the design of the ion source by shifting the coded aperture slits relative to the center of the ionization volume. This method resulted in ions of all masses passing through all slits in the coded aperture, a constant system response function across the entire mass range. Artifacts were reduced by 94%.

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Section: Introductionmentioning

confidence: 99%

Spectral Reconstruction Improvement in a Cycloidal Coded-Aperture Mass Spectrometer

Aloui,

Vyas,

Francini

et al. 2024

J. Am. Soc. Mass Spectrom.

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A super‐resolution proof of concept in a cycloidal coded aperture miniature mass spectrometer

Aloui

Serpa

Abboud

et al. 2023

Rapid Comm Mass Spectrometry

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RationaleHigher resolution in fieldable mass spectrometers (MS) is desirable in space flight applications to enable resolving isobaric interferences at m/z < 60 u. Resolution in portable cycloidal MS coupled with array detectors could be improved by reducing the slit width and/or by reducing the width of the detector pixels. However, these solutions are expensive and can result in reduced sensitivity. In this paper, we demonstrate high‐resolution spectral reconstruction in a cycloidal coded aperture miniature mass spectrometer (C‐CAMMS) without changing the slit or detector pixel sizes using a class of signal processing techniques called super‐resolution (SR).MethodsWe developed an SR reconstruction algorithm using a sampling SR approach whereby a set of spatially shifted low‐resolution measurements are reconstructed into a higher‐resolution spectrum. This algorithm was applied to experimental data collected using the C‐CAMMS prototype. It was then applied to synthetic data with additive noise, system response variation, and spatial shift nonuniformity to investigate the source of reconstruction artifacts in the experimental data.ResultsExperimental results using two ½ pixel shifted spectra resulted in a resolution of ¾ pixel full width at half maximum (FWHM) at m/z = 28 u. This resolution is equivalent to 0.013 u, six times better than the resolution previously published at m/z = 28 for N2+ using C‐CAMMS. However, the reconstructed spectra exhibited some artifacts. The results of the synthetic data study indicate that the artifacts are most likely caused by the system response variation.ConclusionsThis paper demonstrates super‐resolution spectral reconstruction in C‐CAMMS without changing the slit or detector pixel sizes using a sampling SR approach. With improvements, this technique could be used to resolve isobaric interferences in a portable cycloidal MS for space flight applications.

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Design considerations for a cycloidal mass analyzer using a focal plane array detector

Cited by 2 publications

References 67 publications

Spectral Reconstruction Improvement in a Cycloidal Coded-Aperture Mass Spectrometer

Spectral Reconstruction Improvement in a Cycloidal Coded-Aperture Mass Spectrometer

A super‐resolution proof of concept in a cycloidal coded aperture miniature mass spectrometer

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