Secondary ion mass spectrometry of low-temperature solids

Josef Michl
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引用次数: 77

Abstract

Secondary ion mass spectra obtained by bombardment of low-temperature solids such as the rare gases, nitrogen, oxygen, nitrogen oxides, and others with heavy ions of keV energies contain many cluster ion peaks, often with unusual compositions. A mechanism which accounts for the results in a qualitative way is described. It is proposed that it has general mechanistic implications for keV particle-induced desorption mass spectrometry in spite of the obvious difference between the low-temperature solids and the more usual molecular solids. The mechanism has three principal features. First, it is recognized that keV-energy atoms and ions are quite efficient in causing ionization, secondary electron formation, ionizing fragmentation and electronic excitation of molecules within the molecular solid. These processes occur in addition to homolytic bond cleavage within the collision cascade region and lead to local charging within the insulating solid. Some of the damage centers in the solid are ejected essentially immediately from one of the surface layers during the collision cascade period of the impact event. Second, since the chemical nature of the primary damage centers is the same as in MeV-energy bombardment, so are the chemical reactions and charge transfer processes leading to secondary damage, at least in a qualitative sense. Some of the secondary damage products are ejected during the thermal spike regime which follows the collision cascade. The relative importance of the two batches of the secondary ions is a function of the nature of the bombarding ion. Third, polar and/or polarizable molecules will be the best at aggregating with the various resulting charged species during the ejection from the thermal spike region into the vacuum and the best at staying associated with the charged species during subsequent gas-phase fragmentation of the resulting metastable cluster ions in an “evaporating fractionation” process.

低温固体的二次离子质谱分析
用keV能量的重离子轰击低温固体(如稀有气体、氮、氧、氮氧化物和其他)获得的二次离子质谱包含许多簇离子峰,通常具有不寻常的组成。描述了一种以定性方式解释结果的机制。尽管低温固体与一般的分子固体之间存在明显的差异,但它对keV粒子诱导解吸质谱分析具有普遍的机理意义。该机构有三个主要特点。首先,认识到高能原子和离子在分子固体中引起分子的电离、二次电子形成、电离破碎和电子激发是相当有效的。这些过程发生在碰撞级联区域的均裂键解理之外,并导致绝缘固体内部的局部充电。在撞击事件的碰撞级联期间,固体中的一些损伤中心基本上是立即从其中一个表层喷射出来的。其次,由于初级损伤中心的化学性质与mev能量轰击相同,因此导致二次损伤的化学反应和电荷转移过程也是如此,至少在定性意义上如此。一些二次损伤产物是在碰撞串级之后的热尖峰状态中喷射出来的。这两批次级离子的相对重要性是轰击离子性质的函数。第三,极性和/或极化分子在从热尖峰区喷射到真空的过程中,最容易与各种带电物质聚集在一起,并且在随后的“蒸发分馏”过程中,在产生亚稳簇离子的气相破碎过程中,最容易与带电物质保持联系。
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