Evaluation of the operating parameters of the liquid sampling-atmospheric pressure glow discharge (LS-APGD) ionization source for elemental mass spectrometry

Zhang, Lynn X.; Manard, Benjamin T.; Kappel, Stefanie; Marcus, R. Kenneth

doi:10.1007/s00216-014-7990-6

Cited by 28 publications

(44 citation statements)

References 49 publications

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“…What changes appreciably as the current increases, though, is the ability to vaporize the eluate and desolvate (decluster) hydrated analyte ions. This set of trends is entirely consistent with the more detailed parametric evaluation of the microplasma on the Paul-trap instrument [18]. To this end, as seen in the previous sections, the 235 U/…”

Section: Roles Of Ion Accumulation Time and Discharge Conditionssupporting

confidence: 72%

“…Previous LS-APGD efforts on this Orbitrap instrument and on the Thermo Scientific LCQ Advantage Max at Clemson University resulted in similar dependencies relative to the plasma operation conditions of solution feed rate, discharge current, and ion sampling distance [18]. Those works dealt specifically with the responses of atomic ions.…”

Section: Resultsmentioning

confidence: 99%

“…As suggested above, under the supposition that the oxides are formed in the mass analyzer, the initial plasma parameters were the same as those found for atomic ion analysis; more atomic ions lead to greater amounts of oxides. Ultimately, the LS-APGD was run at the following conditions throughout this effort: electrolyte (sample) flow = 30 μL min , and a discharge current = 30 mA, equivalent to the previous works [17,18]. The parameters that were varied and optimized on the Orbitrap were the Fourier transform (FT) digitization window, the ion accumulation time prior to injection into the Orbitrap (termed injection time in the system software), the number of averaged micro scans that are averaged, and the number of scans making up the spectral data.…”

Section: Resultsmentioning

confidence: 99%

“…The basic components of the LS-APGD ion source have been described previously and are shown in Figure 1 [16][17][18]. The ion source consists of a anode that is made of a metal electrode (SS, weldable feedthrough, MDC Vacuum Products,LLC, Hayward California) that has a potential applied to it from a Glassman (High Bridge, NJ) Model EH power supply (0-100 mA, 0-1 kV) and a cathode.…”

Section: Methodsmentioning

confidence: 99%

“…The normal operating parameters of the LS-APGD are gas flow rates of ≤1 L min -1 , liquid flow rates of 5-40 μL min -1 , and power consumption of only 50 W. Further, the LS-APGD is run in total consumption mode when operated correctly, which reduces waste streams to zero. Prior work out of the Marcus group using the LS-APGD for mass spectrometry shows promise as a miniature ion source [16][17][18]. While other elemental/atomic ion sources are not suitable to analyze molecular species due to excessive thermal dissociation, the LS-APGD source has also been shown to be a viable ion source for organics by simple changing the electrolytic solution makeup [19].…”

Section: Introductionmentioning

confidence: 99%

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Preliminary Figures of Merit for Isotope Ratio Measurements: The Liquid Sampling-Atmospheric Pressure Glow Discharge Microplasma Ionization Source Coupled to an Orbitrap Mass Analyzer

Hoegg

Barinaga

Hager

et al. 2016

J. Am. Soc. Mass Spectrom.

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Abstract. In order to meet a growing need for fieldable mass spectrometer systems for precise elemental and isotopic analyses, the liquid sampling-atmospheric pressure glow discharge (LS-APGD) has a number of very promising characteristics. One key set of attributes that await validation deals with the performance characteristics relative to isotope ratio precision and accuracy. Owing to its availability and prior experience with this research team, the initial evaluation of isotope ratio (IR) performance was performed on a Thermo Scientific Exactive Orbitrap instrument. While the mass accuracy and resolution performance for Orbitrap analyzers are well-documented, no detailed evaluations of the IR performance have been published. Efforts described here involve two variables: the inherent IR precision and accuracy delivered by the LS-APGD microplasma and the inherent IR measurement qualities of Orbitrap analyzers. Important to the IR performance, the various operating parameters of the Orbitrap sampling interface, high-energy collisional dissociation (HCD) stage, and ion injection/data acquisition have been evaluated. The IR performance for a range of other elements, including natural, depleted, and enriched uranium isotopes was determined. In all cases, the precision and accuracy are degraded when measuring low abundance (<0.1% isotope fractions). In the best case, IR precision on the order of 0.1% RSD can be achieved, with values of 1%-3% RSD observed for low-abundance species. The results suggest that the LS-APGD is a promising candidate for field deployable MS analysis and that the high resolving powers of the Orbitrap may be complemented with a here-to-fore unknown capacity to deliver high-precision IRs.

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Section: Roles Of Ion Accumulation Time and Discharge Conditionssupporting

confidence: 72%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Preliminary Figures of Merit for Isotope Ratio Measurements: The Liquid Sampling-Atmospheric Pressure Glow Discharge Microplasma Ionization Source Coupled to an Orbitrap Mass Analyzer

Hoegg

Barinaga

Hager

et al. 2016

J. Am. Soc. Mass Spectrom.

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Modern Plasma‐based Desorption/Ionization: From Atoms and Molecules to Chemical Synthesis

Molnar

Shelley

2020

Mass Spectrometry Reviews

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Since the first mass spectrometry (MS) experiments were conducted by Thomson and Aston, plasmas have been used as ionization sources. Historically, plasma ion sources were used for these experiments because they were one of the few known sources of gasphase ions at the time and they were relatively simple to setup and operate. Since then, developments in plasma ionization have continued to inform and motivate advances in other areas of MS. For example, plasma-desorption MS demonstrated ionization of large peptides and polymers more than 10 years before the first descriptions of electrospray ionization (ESI) and matrix-assisted laser desorption/ionization (MALDI). As a result, significant effort was placed on development of ionization approaches, mass analysis, and detection approaches for very large molecules: even before the advent of ESI and MALDI. Since then, new analytical challenges and opportunities in plasma ionization have arisen. In this review, the emerging trends in plasma-based ionization for several areas of MS will be discussed, including molecular ionization, elemental ionization, hybrid elemental and molecular ion sources, and unique chemical transformations.

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Combined atomic and molecular (CAM) ionization with the liquid sampling‐atmospheric pressure glow discharge microplasma

Marcus

Hoegg

Hall

et al. 2021

Mass Spectrometry Reviews

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In a world where information‐rich methods of analysis are often sought over those with superior figures of merit, there is a constant search for ionization methods which can be applied across diverse analytical systems. The liquid sampling‐atmospheric pressure glow discharge (LS‐APGD) is a microplasma device which has the inherent capabilities to operate as a combined atomic and molecular (CAM) ionization source. The plasma is sustained by placement of a high voltage (~500 V, dc) onto an electrolytic solution through which the analyte is generally delivered to the discharge. Judicious choice of the solvent provides a means of obtaining atomic/elemental and/or molecular mass spectra. Presented here are the diverse modes of sample introduction and mass spectrometer platforms to which the LS‐APGD has been interfaced. Likewise, representative spectra and figures of merit are presented towards elemental and isotope ratio measurements, as well as application to small organic molecules, organometallic complexes, and intact proteins. It is believed that the diversity of analytical applications and ready implementation across the entirety of mass spectrometry platforms portends a level of versatility not realized with other ionization sources.

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Evaluation of the operating parameters of the liquid sampling-atmospheric pressure glow discharge (LS-APGD) ionization source for elemental mass spectrometry

Cited by 28 publications

References 49 publications

Preliminary Figures of Merit for Isotope Ratio Measurements: The Liquid Sampling-Atmospheric Pressure Glow Discharge Microplasma Ionization Source Coupled to an Orbitrap Mass Analyzer

Preliminary Figures of Merit for Isotope Ratio Measurements: The Liquid Sampling-Atmospheric Pressure Glow Discharge Microplasma Ionization Source Coupled to an Orbitrap Mass Analyzer

Modern Plasma‐based Desorption/Ionization: From Atoms and Molecules to Chemical Synthesis

Combined atomic and molecular (CAM) ionization with the liquid sampling‐atmospheric pressure glow discharge microplasma

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