Exchange Interaction of Strongly Anisotropic Tripodal Erbium Single-Ion Magnets with Metallic Surfaces

We present a comprehensive study of Er(trensal) single-ion magnets deposited in ultrahigh vacuum onto metallic surfaces. X-ray photoelectron spectroscopy reveals that the molecular structure is preserved after sublimation, and that the molecules are physisorbed on Au(111) while they are chemisorbed on a Ni thin film on 0(100) single-crystalline surfaces. X-ray magnetic circular dichroism (XMCD) measurements performed on Au(111) samples covered with molecular monolayers held at temperatures down to 4 K suggest that the easy axes of the strongly anisotropic molecules are randomly oriented. Furthermore XMCD indicates a weak antiferromagnetic exchange coupling between the single-ion magnets and the ferromagnetic Ni/Cu(100) substrate. For the latter case, spin-Hamiltonian fits to the XMCD M(H) suggest a significant structural distortion of the molecules. Scanning tunneling microscopy reveals that the molecules are mobile on Au(111) at room temperature, whereas they are more strongly attached on Ni/Cu(100). X-ray photoelectron spectroscopy results provide evidence for the chemical bonding between Er(trensal) molecules and the Ni substrate. Density functional theory calculations support these findings and, in addition, reveal the most stable adsorption configuration on Ni/Cu(100) as well as the Ni-Er exchange path. Our study suggests that the magnetic moment of Er(trensal) can be stabilized via suppression of quantum tunneling of magnetization by exchange coupling to the Ni surface atoms. Moreover, it opens up pathways toward optical addressing of surface-deposited single-ion magnets.

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

Nicha Thontasen

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 revealed by STM is a flat-laying double row of the molecules on Cu(100) surface showing the robustness of the structural motive. The properties of single molecular functional systems are studied on two types of large functional molecules: macrocycle complexes and proteins. Macrocyclic host-guest complexes of the three cations: Na+, Cs+ and H+ trapped in the cavity of dibenzo-24-crown-8 (DB24C8) are formed in the electrospray solutions and transferred intact to the surface. Characterization by STM and density functional theory calculations shows the structure of the complexes with the alkali ion present in the cavity. The shape of the complex at the surface is also determined. Cytochrome c, an electron transfer protein is deposited on surfaces in UHV as an ion beam of high or low charge-state. STM reveals unfolded strands with distinguishable submolecular structural features after the deposition of high charge states. When low charge states are deposited, two significantly different structures are observed. Folded proteins appear as globular features of 2-3 nm diameter, while unfolded proteins are imaged as at strands. On Au(111) the unfolded strands fold into compact two-dimensional patches. Additionally, the variation in kinetic energy upon deposition and elevated surface temperature are also studied regarding the change in conformation of the adsorbed proteins. The results of this thesis open up new opportunities for the creation of functional nanostructures on surfaces. Both the preparation of layers and thin films as well as the controlled immobilization of single functional molecules were demonstrated with ES-IBD and characterized at submolecular resolution in situ by STM. A great variety of nonvolatile substances from small to large functional molecules with different binding motives like covalent, complex coordination or hydrogen bonds, is compatible with ESI and thus can be used as building blocks to construct new materials in a well-controlled manner.

EPFL2011

Single-molecule-level characterization of supramolecular systems at surfaces

Dietmar Payer

This thesis deals with the self-organization of individual building blocks, specifically organic molecules and metal atoms, into supramolecular structures on metal surfaces under ultra high vacuum conditions (UHV). Self-organization of supramolecular systems is a promising candidate for a bottom-up approach in the fabrication of complex structures with specific properties. This process is steered by interactions between functional groups of the individual building blocks and is of apparent interest to gain a detailed understanding of the influence and the behavior of these functional groups enabling intermolecular binding. In the first part of the thesis, we investigate hydrogen bonded structures on metal surfaces. Of especial interest is the possibility of the formation of ionic hydrogen bonds, a special class of hydrogen bond which connects a charged donor (acceptor) and a neutral acceptor (donor) and is important in biological systems. By combined Scanning Tunneling Microscopy (STM), X-ray Photoelectron Spectroscopy (XPS) and Near Edge X-ray Absorption Fine Structure (NEXAFS) measurement we show the deprotonation of carboxylic functions in the molecules, forming carboxylate groups involved in intermolecular binding. With our complementary experimental and theoretical examinations we clearly show that the carboxylate groups are indeed still charged although adsorbed onto a conducting metal surface and that the observed structures can be computationally reproduced by using these charges in classical molecular dynamic calculations. Our investigations clearly reveal that all requirements for the formation of ionic hydrogen bonds in these samples at metal surfaces under solvent free conditions are fulfilled. In the second part, the confinement of surface state electrons in self-assembled hydrogen-bonded structures is investigated. The examined structure contains two-dimensional cavities, with different inner diameters in the periodic arrangement and in domain boundaries. Inside the cavities we detect a spatially localized modification in the local density of states (LDOS) of the Ag(111) surface state electrons. The energy of the peak correlates with the cavity area as predicted by a simple "particle in a box" model. This clearly shows that the surface state electrons form a confined state inside the cavities. Furthermore we examine self-assembled periodic structures as templates for binding single macrocyclic molecules. The macrocyclic molecules can be deposited by sublimation, as STM-topographs with submolecular resolution reflect the shape of the intact molecules and reveal a coverage dependent aggregation behavior. We show that it is possible to fabricate a structure in which at most one macrocyclic molecule per pore can be found in a defined binding position. In the last part of the thesis we investigate the influence of individual metal atoms on the chemical activity and the self-assembly process of molecules on metal surfaces. First, we demonstrate the high chemical reactivity of these metal atoms. In our experiments we address the chemical reactivity of static active sites, like kinks and step edges, and of dynamic active sites, like the metal atoms, separately. Doing this we show that a non-negligible amount of the chemical reactivity of a metal surface is due to this dynamic adatom gas. Furthermore the influence of metal atoms on the structure formation of organic molecules is investigated. We show that two-dimensional structures based on a complex formation between metal centers and ligands can be formed and that the coordination number is independent of the substrate symmetry. Furthermore, we show the possibility that on metal surfaces one can prepare three-fold coordinated Fe-centers, a coordination number which is rarely seen in three dimensional chemistry. In the last part we study catenanes, which consist of two interlocked macrocyclic molecules. Main interest is on the confirmation of a structural change of the catenanes adsorbed on a metal substrate. For our experiments we use the fact that the catenanes are designed to "trap" a Cu-atom by complex formation. As this reaction is associated with a structural change and a change in intermolecular interaction, we can verify a reaction of catenanes adsorbed onto a surface with Cu adatoms and therefore a structural alteration by simply imaging the formed structures. Our measurements show the possibility of depositing large molecules like catenanes by sublimation and of their potential for use as molecular machines adsorbed onto metal surfaces.

EPFL2007

Quantum dynamics in individual surface spins

Tobias Bilgeri

This thesis presents a combined experimental and theoretical study of the classical and quantum magnetization dynamics in single magnetic adatoms and molecules, and on the classical and quantum coherent control thereof. First, a detailed description of the methods and in particular electron spin resonance scanning tunneling spectroscopy is given. Next, we give a detailed account of how to experimentally update a standard scanning tunneling microscope for such experiments, which ultimately lead us to set up the world's second microscope with such capabilities. Subsequently, we show how we iteratively improved the setup, and how we were able to achieve a transmission of radiofrequency voltages to the tunneling junction with almost no additional losses beyond the intrinsic limitations of the materials used, a great improvement compared to most setups presently in use.Afterwards, we apply this technique to the metal-organic complex iron phthalocyanine. On MgO, we find it to form a spin-1/2 system, and we demonstrate quantum coherent control thereof, and investigate the magnetic interaction between surface-adsorbed molecules. Furthermore, we use this technique to experimentally demonstrate the magnetic stability of Dy adatoms on MgO. We find that this system, by several metrics, represents the worlds most stable single atom magnet discovered thus far. Using the capability of scanning tunneling microscopes to perform atomic manipulation, we ensemble atomically precise Dy nanostructures. By classically controlling the magnetic orientation of the Dy atoms, we are thus able to store information long-term in single adatoms and nanostructures even in absence of an external field, and create nanomagnets and local magnetic fields with unprecedented precision and stability.Finally, we investigate the magnetic properties of Ho/MgO. Depending on the precise adsorption site and charge configuration, we find either long lifetimes in the case of top-site 4f10 Ho, which was recently discovered as world's first single atom magnet, or fast sub-barrier relaxation due to strongly mixed quantum states. Using a novel theoretical approach, we are able to disentangle the different contributions of the individual species measured in ensemble-averaging X-ray absorption studies, and lift the discrepancies between previous X-ray and scanning tunneling microscopy based studies on Ho/MgO. By theoretically describing the perturbing effects of the experimental probes driving the spin degree of freedom out of thermal equilibrium, we are able to explain the measured dynamics in good agreement with the experimental data.

EPFL2021