离子迁移率测量过程中常见爆炸分子加合物络合物的寿命和稳定性。
Lifetimes and stabilities of familiar explosive molecular adduct complexes during ion mobility measurements.
作者信息
McKenzie-Coe Alan, DeBord John Daniel, Ridgeway Mark, Park Melvin, Eiceman Gary, Fernandez-Lima Francisco
机构信息
Department of Chemistry and Biochemistry, Florida International University, Miami, FL 33199, USA.
出版信息
Analyst. 2015 Aug 21;140(16):5692-9. doi: 10.1039/c5an00527b.
Abstract
Trapped ion mobility spectrometry coupled to mass spectrometry (TIMS-MS) was utilized for the separation and identification of familiar explosives in complex mixtures. For the first time, molecular adduct complex lifetimes, relative stability, binding energies and candidate structures are reported for familiar explosives. Experimental and theoretical results showed that the adduct size and reactivity, complex binding energy and the explosive structure tailor the stability of the molecular adduct complex. The flexibility of TIMS to adapt the mobility separation as a function of the molecular adduct complex stability (i.e., short or long IMS experiments/low or high IMS resolution) permits targeted measurements of explosives in complex mixtures with high confidence levels.
摘要
将阱式离子迁移谱与质谱联用(TIMS-MS)用于复杂混合物中常见炸药的分离和鉴定。首次报道了常见炸药的分子加合物络合物寿命、相对稳定性、结合能和候选结构。实验和理论结果表明,加合物大小和反应性、络合物结合能以及炸药结构决定了分子加合物络合物的稳定性。TIMS能够根据分子加合物络合物的稳定性调整迁移率分离(即短或长的离子迁移谱实验/低或高的离子迁移谱分辨率),从而能够在高置信水平下对复杂混合物中的炸药进行靶向测量。
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