Unlocking the Mysteries of the Desorption–Ionization Mechanism via Separate Thermal and Charge Strategies

Abstract

Herein, a new strategy is employed to build a controllable thermal-coupled charge ionization (TCCI) device to elucidate the desorption–ionization mechanism of plasma ion sources. Efficient synergistic desorption and ionization are achieved within the TCCI device by independently controlling the desorption temperature and plasma charges. The TCCI device efficiently ionizes samples using abundant free electrons, charges, and active species from arc plasma. The coexistence of free electrons and hydroxide radicals confers redox capability to the TCCI system, implying the presence of a unified redox mechanism even when the arc plasma is transmitted through a metal conductor over a distance. In addition, molecular ions of the analytes facilitate the differentiation between primary and secondary amines during their analysis. Notably, the TCCI device enables a switch between hard and soft ionization by adjusting the thermal desorption temperature. At high temperatures (>400 °C), the TCCI device exhibits hard ionization characteristics, producing fragment ions beneficial for isomer discrimination. The TCCI mass spectrometry exhibits robust performance in terms of sensitivity and accuracy for detecting antibiotics and sterols in saline solutions, achieving linearity with correlation coefficients ≥0.99 and excellent reproducibility. The successful analysis of seven pharmaceuticals and four sterols in complex matrices using the TCCI device demonstrates its excellent salt and matrix tolerance. Overall, the TCCI device, with its independent control over thermal desorption and arc plasma, achieves efficient synergistic desorption and ionization, overcoming limitations in existing ionization technologies and contributing to the study of gas-phase ion dynamics and mechanisms.