Ion Beam Deposition and STM Analysis of Macromolecules on Solid Surfaces in UHV

Organic and biological macromolecules have attracted great interest within nanotechnology research due to properties that can be useful in future devices. Interesting functionalities such as optical activity, host-guest binding and molecular recognition are based on effects at the single molecular level. To study the properties and functions of molecules at submolecular scale, an atomically defined environment with low contamination is of great advantage. This can for instance be provided on a clean surface in ultrahigh vacuum (UHV), where surface sensitive analytical techniques and advanced nanostructure fabrication can be applied. Atoms and small organic molecules are easily transferred to a surface in vacuum by thermal sublimation. Many large, functional molecules, however, are nonvolatile and disintegrate at an elevated temperature, which hinders their application and investigation within the UHV environment. To explore the properties of nonvolatile molecules adsorbed at surface as well as the nanostructure fabricated from such molecules, electrospray ion beam deposition (ES-IBD), a technique capable of transferring nonvolatile molecules intact to surfaces in UHV, and in situ scanning tunneling microscopy (STM) are combined. A home-built ES-IBD setup allows molecular beam deposition with an unprecedented level of control: the ion beam composition is monitored by time-of-flight mass spectrometry (TOF-MS) prior to the deposition, molecular flux and coverage controlled via the ion beam current and the beam energy can be measured and adjusted. The modified surfaces are characterized in situ by STM, which reveals structural and electronic properties with submolecular resolution. Moreover, ex situ analysis by atomic force microscopy (AFM) allows to access meso-scale structural formation. In addition, Laser Desorption Ionization (LDI), Matrix-Assisted Laser Desorption Ionization (MALDI) and Secondary Ion Mass Spectrometry (SIMS) are performed to check the chemical composition and purity of the adsorbed materials. This work first introduces the principles of our experiments and reviews of the literature on molecular ion beam deposition. In the following, the experimental method is characterized in detail using Rhodamine 6G, an organic dye, as a model system. It is shown that homogeneous layers of adsorbed, intact molecules are formed on the surface and single molecule adsorbates are observed by STM. An investigation by SIMS and LDI reveals that the kinetic energy of the molecular ions upon collision with the surface determines whether intact or fragment ions are deposited. Molecular layer growth was studied using cluster ion beams of the nonvolatile surfactant SDS, resulting in an arrangement of the molecules typical for surfactants in a head-to-head and tail-to-tail manner based on the structural motive. Crystalline structures are observed by AFM resembling inverted bilayer-membranes formed on graphite and SiOx surfaces. A similar structural feature