Electron ionization mass spectrometry: Quo vadis?

Maciel, Edvaldo Vasconcelos Soares; Santos, Natalia Gabrielly Pereira dos; Medina, Deyber Arley Vargas; Lanças, Fernando Mauro

doi:10.1002/elps.202100392

Cited by 14 publications

(9 citation statements)

References 88 publications

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“…Nevertheless, the modern developments in nanoLC have allowed for mitigating the impacts of the mobile phase over the EI process. The techniques are becoming compatible through interfaces such as the Direct-EI, Liquid electron ionization (LEI), and the Cold-EI [102,103].…”

Section: Otlc Coupled To Otlc-ei-msmentioning

confidence: 99%

Open tubular liquid chromatography: Recent advances and future trends

Medina

Cardoso

Borsatto

et al. 2023

J of Separation Science

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Nano‐liquid chromatography (nanoLC) is gaining significant attention as a primary analytical technique across various scientific domains. Unlike conventional high‐performance LC, nanoLC utilizes columns with inner diameters (i.ds.) usually ranging from 10 to 150 μm and operates at mobile phase flow rates between 10 and 1000 nl/min, offering improved chromatographic performance and detectability. Currently, most exploration of nanoLC has focused on particle‐packed columns. Although open tubular LC (OTLC) can provide superior performance, optimized OTLC columns require very narrow i.ds. (< 10 μm) and demand challenging instrumentation. At the moment, these challenges have limited the success of OTLC. Nevertheless, remarkable progress has been made in developing and utilizing OTLC systems featuring narrow columns (< 2 μm). Additionally, significant efforts have been made to explore larger columns (10–75 μm i.d), demonstrating practical applicability in many situations. Due to their perceived advantages, interest in OTLC has resurged in the last two decades. This review provides an updated outlook on the latest developments in OTLC, focusing on instrumental challenges, achievements, and advancements in column technology. Moreover, it outlines selected applications that illustrate the potential of OTLC for performing targeted and untargeted studies.

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Section: Otlc Coupled To Otlc-ei-msmentioning

confidence: 99%

Open tubular liquid chromatography: Recent advances and future trends

Medina

Cardoso

Borsatto

et al. 2023

J of Separation Science

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“…Electron ionization (EI, also called electron impact ionization in early literature), was one of the most commonly used ionization methods for MS analysis. It utilizes the interaction between electrons and gas phase molecules to ionize the molecules [22,23]. EI often generates fragment ions during the ionization process.…”

Section: Electron Ionizationmentioning

confidence: 99%

Portable mass spectrometry system: instrumentation, applications, and path to ‘omics analysis

et al. 2022

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Mass spectrometry (MS) is an information rich analytical technique and plays a key role in various 'omics studies. Standard mass spectrometers are bulky and operate at high vacuum, which hinder their adoption by the broader community and utility in field applications. Developing portable mass spectrometers can significantly expand the application scope and user groups of MS analysis. This review discusses the basics and recent advancements in the development of key components of portable mass spectrometers including ionization source, mass analyzer, detector, and vacuum system. Further, major areas where portable mass spectrometers are applied are also discussed. Finally, a perspective on the further development of portable mass spectrometers including the potential benefits for 'omics analysis is provided.

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“…Aligned to these principles, this work proposes for the first time the use of GC × GC coupled to a flame ionization detector (GC × GC/FID) as a powerful option to fill this gap given the ability of this analytical technique to both separate at least an order of magnitude more compounds compared to conventional one-dimensional GC and to provide more detailed chemical information of complex mixtures compared to infrared spectroscopy [17,[36][37][38]. Additionally, GC × GC/FID provides remarkably better quantitation capabilities with response factors close to one for hydrocarbons unlike MS detectors while avoiding the challenge of different ionization efficiencies during electron and chemical ionization mechanisms and biases towards specific hydrocarbon groups especially when alternative blending components are analyzed via ASTM D2425 [39][40][41][42][43]. Thus, this work exhibits the applicability of GC × GC/FID and PLS to predict the kinematic viscosity of jet fuels and alternative blending components at −20 • C. Additionally, this model shows the influence of different normalization methods (mean centering normal-ization, logarithmic, and Yeo-Johnson transformations) over the PLS performance metrics.…”

Section: Introductionmentioning

confidence: 99%

Kinematic viscosity prediction of jet fuels and alternative blending components via comprehensive two‐dimensional gas chromatography, partial least squares, and Yeo‐Johnson transformation

Caceres‐Martinez,

Kilaz

2024

J of Separation Science

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This work presents an accurate yet simplified partial least squares model to predict the kinematic viscosity of conventional and alternative jet fuels at −20°C using comprehensive two‐dimensional gas chromatography coupled to a flame ionization detector (GC × GC/FID). Three different normalization methods (mean‐centering, logarithmic, and Yeo‐Johnson) were evaluated to identify their impact in the prediction of middle distillates’ physical properties. Results using Yeo‐Johnson transformation exhibited improved viscosity prediction capabilities over the validation set with a mean absolute percentage error of 5.3%, a root‐mean‐squared error of 0.23, and a coefficient of determination (R2) of 0.9404 using only 10 latent variables. Unlike previously reported correlations, this model allowed the identification of specific hydrocarbon groups and carbon numbers that drive jet fuel viscosity at low temperatures. The presence of even small amounts of large branched‐alkanes (C15–C17), dicyclic‐alkanes (C10), and cycloaromatics (C11) have the potential to strongly increase the kinematic viscosity of jet fuels. Contrastingly, light monocycloalkanes and branched‐alkanes (≤ C10) were associated with lower viscosity values. Novelly, this model suggests the implementation of Yeo‐Johnson transformations to predict the physical properties of middle distillates to further improve the performance metrics of partial least squares models based on GC data.

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Electron ionization mass spectrometry: Quo vadis?

Cited by 14 publications

References 88 publications

Open tubular liquid chromatography: Recent advances and future trends

Open tubular liquid chromatography: Recent advances and future trends

Portable mass spectrometry system: instrumentation, applications, and path to ‘omics analysis

Kinematic viscosity prediction of jet fuels and alternative blending components via comprehensive two‐dimensional gas chromatography, partial least squares, and Yeo‐Johnson transformation

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