化学
质谱法
离子迁移光谱法
离子
分析化学(期刊)
环境化学
离子迁移谱-质谱
溶解有机碳
高分辨率
分辨率(逻辑)
色谱法
串联质谱法
选择性反应监测
有机化学
遥感
计算机科学
人工智能
地质学
作者
P. R. B. Oliveira,Dennys Leyva,Lílian V. Tose,Chad R. Weisbrod,Anton N. Kozhinov,Konstantin O. Nagornov,Yury O. Tsybin,Francisco Fernández-Lima
标识
DOI:10.1021/jasms.4c00232
摘要
The molecular level characterization of complex mixtures remains an analytical challenge. We have shown that the integration of complementary, high-resolution, gas-phase separations allows for chemical formula level isomeric content description. In the current work, we revisited the current challenges associated with the analysis of dissolved organic matter using high-resolution trapped ion mobility separation (TIMS) and Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS). In particular, we evaluated the separation capabilities provided by TIMS-MS compared to MS alone, the use of ICR complementary data acquisition (DAQ) systems and transient processing strategies, ICR cell geometries (e.g., Infinity cell vs harmonized cell), and magnetic field strengths (7 T vs 9.4 T vs 21 T) for the case of a Harney River DOM sample. Results showed that the external high-performance DAQ enables direct representation of mass spectra in absorption mode FT (aFT), doubling the MS resolution compared to the default magnitude mode FT (mFT). Changes between half- vs full-apodization result in greater MS signal/noise vs superior MS resolving power (RP); in the case of DOM analysis, a 45% increase in assigned formulas is observed when employing the DAQ half (Kaiser-type)-apodization window and aFT when compared to the default instrument mFT. Results showed the advantages of reprocessing 2D-TIMS-FT-ICR MS data with higher RP and magnetic field chemical formulas generated list acquired (e.g., 21 T led to a 24% increase in isomers reported) or the implementation of alternative strategies.
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