Johnson Grant E, Gunaratne Don, Laskin Julia
Physical Sciences Division, Pacific Northwest National Laboratory, P.O. Box 999, MSIN K8-88, Richland, WA, 99352.
Mass Spectrom Rev. 2016 May-Jun;35(3):439-79. doi: 10.1002/mas.21451. Epub 2015 Apr 16.
Soft- and reactive landing of mass-selected ions is gaining attention as a promising approach for the precisely-controlled preparation of materials on surfaces that are not amenable to deposition using conventional methods. A broad range of ionization sources and mass filters are available that make ion soft-landing a versatile tool for surface modification using beams of hyperthermal (<100 eV) ions. The ability to select the mass-to-charge ratio of the ion, its kinetic energy and charge state, along with precise control of the size, shape, and position of the ion beam on the deposition target distinguishes ion soft landing from other surface modification techniques. Soft- and reactive landing have been used to prepare interfaces for practical applications as well as precisely-defined model surfaces for fundamental investigations in chemistry, physics, and materials science. For instance, soft- and reactive landing have been applied to study the surface chemistry of ions isolated in the gas-phase, prepare arrays of proteins for high-throughput biological screening, produce novel carbon-based and polymer materials, enrich the secondary structure of peptides and the chirality of organic molecules, immobilize electrochemically-active proteins and organometallics on electrodes, create thin films of complex molecules, and immobilize catalytically active organometallics as well as ligated metal clusters. In addition, soft landing has enabled investigation of the size-dependent behavior of bare metal clusters in the critical subnanometer size regime where chemical and physical properties do not scale predictably with size. The morphology, aggregation, and immobilization of larger bare metal nanoparticles, which are directly relevant to the design of catalysts as well as improved memory and electronic devices, have also been studied using ion soft landing. This review article begins in section 1 with a brief introduction to the existing applications of ion soft- and reactive landing. Section 2 provides an overview of the ionization sources and mass filters that have been used to date for soft landing of mass-selected ions. A discussion of the competing processes that occur during ion deposition as well as the types of ions and surfaces that have been investigated follows in section 3. Section 4 discusses the physical phenomena that occur during and after ion soft landing, including retention and reduction of ionic charge along with factors that impact the efficiency of ion deposition. The influence of soft landing on the secondary structure and biological activity of complex ions is addressed in section 5. Lastly, an overview of the structure and mobility as well as the catalytic, optical, magnetic, and redox properties of bare ionic clusters and nanoparticles deposited onto surfaces is presented in section 6.
质量选择离子的软着陆和反应性着陆作为一种有前景的方法正受到关注,该方法可用于在无法使用传统方法进行沉积的表面上精确控制材料的制备。目前有多种电离源和质量过滤器可供使用,这使得离子软着陆成为一种使用超热(<100 eV)离子束进行表面改性的通用工具。能够选择离子的质荷比、其动能和电荷状态,以及精确控制离子束在沉积靶上的尺寸、形状和位置,这使离子软着陆有别于其他表面改性技术。软着陆和反应性着陆已被用于制备实际应用的界面以及化学、物理和材料科学基础研究中精确界定的模型表面。例如,软着陆和反应性着陆已被应用于研究气相中分离出的离子的表面化学,制备用于高通量生物筛选的蛋白质阵列,生产新型碳基和聚合物材料,丰富肽的二级结构和有机分子的手性,将电化学活性蛋白质和有机金属固定在电极上,制备复杂分子的薄膜,以及固定催化活性有机金属以及连接的金属簇。此外,软着陆使得能够研究临界亚纳米尺寸范围内裸金属簇的尺寸依赖性行为,在该尺寸范围内,化学和物理性质与尺寸之间不存在可预测的比例关系。还使用离子软着陆研究了较大裸金属纳米颗粒的形态、聚集和固定,这与催化剂的设计以及改进的存储器和电子器件直接相关。这篇综述文章在第1节首先简要介绍了离子软着陆和反应性着陆的现有应用。第2节概述了迄今为止用于质量选择离子软着陆的电离源和质量过滤器。第3节讨论了离子沉积过程中发生的竞争过程以及所研究的离子和表面类型。第4节讨论了离子软着陆期间和之后发生的物理现象,包括离子电荷的保留和减少以及影响离子沉积效率的因素。第5节讨论了软着陆对复合离子二级结构和生物活性的影响。最后,第6节概述了沉积在表面上的裸离子簇和纳米颗粒的结构和迁移率以及催化、光学、磁性和氧化还原性质。
