An X-ray Based Spectroscopic Study of Structure Influencing Electrons : Fragmentation, Ultrafast Charge Dynamics and Surface Composition

Sammanfattning: The structure of biomolecules, such as proteins, is intimately connected to the function of the molecules. These structures are often studied using X-ray diffraction. However, the interaction of the X-ray photons with the molecule can excite or ionize its electrons which in turn can causes changes in the molecular structure. Getting a better understanding of the radiation damage induced by the X-rays, will lead to higher resolution molecular imaging. In proteins, sulfur bridges stabilize the structure, but sulfur is relatively more susceptible to X-ray photon-induced dynamics. The first section of the thesis presents results obtained by fragment mass spectroscopy using an ion trap on the X-ray induced dynamics leading to breakage in the smallest unit containing sulfur bridge in proteins, cystine. The fragmentation of the bridge is seen to depend on the photon energy used.Molecular damage is not always undesirable. The radiation-induced damage of DNA of cancer cells is an aspired outcome of radiation therapy treatment. Along with the direct damaging effect of the radiation, the surrounding water and metal ions also play a role in indirectly destroying the DNA structure. The X-rays ionize the metal ions and water molecules, which relaxes via different processes, producing water radicals and slow electrons. Both are agents of the destruction of DNA strands. The second section of the thesis reports on results obtained by electron spectroscopy on ultrafast electron dynamics originating from the relaxation of core-excited and ionized aqueous ions, which can result in slow electrons and water radicals. To understand the damages in the system of aqueous ions and biomolecules, one needs to understand the interaction between the organic-inorganic species. Using surface sensitive X-ray photoelectron spectroscopy on such a sample mixture of potassium chloride and amino acids is explained in the last section of the thesis. It is seen that changing the chemical environment in the solution (pH), affects both the protonation of the functional group of amino acids and the surface distribution of solvated counter ions. The interaction between organic biomolecules and inorganic ions can be ensured by controlling the chemical environment. This thesis puts forward the study of electrons that influences the molecular structure using various X-ray based spectroscopy techniques.