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In the present work, the Heidelberg electron beam ion trap (EBIT) at the Max-Planck-Institute für Kernphysik (MPIK) has been used to produce, trap highly charged argon ions and study their magnetic dipole (M1) forbidden transitions. These transitions are of relativistic origin and, hence, provide unique possibilities to perform precise studies of relativistic effects in many electron systems. In this way, the transitions energies of the 1s22s22p for the 2P3/2 - 2P1/2 transition in Ar13+ and the 1s22s2p for the 3P1 - 3P2 transition in Ar14+, for 36Ar and 40Ar isotopes were compared. The observed isotopic effect has confirmed the relativistic nuclear recoil effect corrections due to the finite nuclear mass in a recent calculation made by Tupitsyn [TSC03], in which major inconsistencies of earlier theoretical methods have been corrected for the first time. The finite mass, or recoil effect, composed of the normal mass shift (NMS), and the specific mass shift (SMS) were corrected for relativistic contributions, RNMS and RSMS. The present experimental results have shown that the recoil effects on the Breit level are indeed very important, as well as the effects of the correlated relativistic dynamics in a many electron ion.
A new technique for precision ion implantation has been developed. A scanning probe has been equipped with a small aperture and incorporated into an ion beamline, so that ions can be implanted through the aperture into a sample. By using a scanning probe the target can be imaged in a non-destructive way prior to implantation and the probe together with the aperture can be placed at the desired location with nanometer precision. In this work first results of a scanning probe integrated into an ion beamline are presented. A placement resolution of about 120 nm is reported. The final placement accuracy is determined by the size of the aperture hole and by the straggle of the implanted ion inside the target material. The limits of this technology are expected to be set by the latter, which is of the order of 10 nm for low energy ions. This research has been carried out in the context of a larger program concerned with the development of quantum computer test structures. For that the placement accuracy needs to be increased and a detector for single ion detection has to be integrated into the setup. Both issues are discussed in this thesis. To achieve single ion detection highly charged ions are used for the implantation, as in addition to their kinetic energy they also deposit their potential energy in the target material, therefore making detection easier. A special ion source for producing these highly charged ions was used and their creation and interactions with solids of are discussed in detail.
This work reports on the study of the projectile x-ray emission in relativistic ion-atom collisions. Excitation of K-shell in He-like uranium ions, electron capture into H-like uranium ions and Simultaneous ionization and excitation of initially He-like uranium ions have been studied using the experimental storage ring at GSI. Information about the population of the excited states for the H- and He-like uranium ions, can be obtained by measuring the angular distribution of the decay radiation. Since the Ly_alpha2 transition is isotropic, the intensities of the Ly_alpha1 and K_alpha transitions were normalized to the Ly_alpha2 line. For the K_alpha1 and K_alpha2 transitions originating from the excitation of the He-like uranium ions, no alignment was observed. In contrast, the Ly_alpha1 radiation from the simultaneous ionization-excitation process of the He-like uranium ions shows a clear alignment. It is shown that the alignment of Ly_alpha1 was obtained by the Alignment parameter A_20. The experimental value leads to the inclusion of a magnetic term in the interaction potential. It is interesting to note that in the case of the Ly_alpha1 emission the small M2 contribution added coherently to the E1 transition amplitudes enhances the anisotropy. The capture process of target electrons into the highly-charged heavy ions was studied using H-like uranium ions at an incident energy of 220 MeV/u, impinging on N2 gas-target. It was shown that, the strongly aligned electrons captured in 2p3/2 level will couple with the available 1s1/2 electron which shows no initial directional preference. The magnetic sub-state population of the 2p3/2 electron will be redistributed according to the coupling rules to the magnetic sub-states of the relevant two-electron states. Consequently, the 1^P1 and 3^P2 states are corresponding to the the strongly aligned 2p3/2 state. This leads to the large anisotropy in the corresponding individual ground state transitions contributing to the K_alpha1 emission. Due to the fact that the 1^P1 --> 1^S0 and 3^P2 --> 1^S0 transitions are experimentally not resolved, a more detailed analysis of the angular dependence of the K_alpha1 radiation is required. From the K_alpha1/K_alpha2 ratio, the current results show that the incoherent addition of the E1 and M2 transition components yield to an almost isotropic emission of the total K_alpha1. In contrast to the radiative electron capture, the experimental results for the K-shell single excitation of He-like uranium ions indicate that only the 1^P1 level contributes to the K_alpha1 transition. For this case, the anisotropy parameter beta_20 was found to be -0.20 + 0.03 which is similar to that one calculated for pure E1 transition. This work also reports on the study of a two-electron process: the simultaneous ionization and excitation occurring in relativistic collisions of heavy highly-charged ions with gaseous targets. The investigation was performed on He-like uranium ions impinging upon xenon gas-target at an incident energy of 220 MeV/u. The measurements have been performed at the ESR gas-target using atomic xenon with a typical area density of 10^12 particles/cm^2. In contrast to the solid state target, the use of gas target offers the advantage of clear separation of the one step two-electron process due to the fact that the probability of two consecutive collision in such thin targets is negligible and the double step processes can be excluded. During the process of simultaneous ionization and excitation in He-like uranium ions, one of the ground-state electrons is promoted into the continuum and the other into the L-subshell states of the projectile. To select this process, the Lyman-series radiation has been measured at various observation angles in coincidence with up-charged projectiles (U^91+). From the yields of the Ly_alpha1 and Ly_alpha2 projectile radiation, the relative cross section for the process of simultaneous ionization and excitation was directly determined. The angle dependent measurement of the radiation yields provide information about the angular distributions of the emitted radiation and permits the determination of the alignment parameter A_{20}. This parameter gives information on the level population and the collision impact parameter. The present results (b^exp = 810 fm) show that the simultaneous ionization and excitation is a process which occurs at small impact parameter.
Within this thesis, an experimental study of the photo double ionization (PDI) and the simultaneous ionization-excitation is performed for lithium in different initial states Li (1s22l) (l = s, p). The excess energy of the linearly polarized VUV-light is between 4 and 12 eV above the PDI-threshold. Three forefront technologies are combined: a magneto-optical trap (MOT) for lithium generating an ultra-cold and, by means of optical pumping, a state-prepared target; a reaction microscope (ReMi), enabling the momentum resolved detection of all reaction fragments with high-resolution and the free-electron laser in Hamburg (FLASH), providing an unprecedented brilliant photon beam at favourable time structure to access small cross sections. Close to threshold the total as well as differential PDI cross sections are observed to critically depend on the excitation level and the symmetry of the initial state. For the excited state Li (1s22p) the PDI dynamics strongly depends on the alignment of the 2p-orbital with respect to the VUV-light polarization and, thus, from the population of the magnetic substates (mp = 0, ±1). This alignment sensitivity decreases for increasing excess energy and is completely absent for ionization-excitation. Time-dependent close-coupling calculations are able to reproduce the experimental total cross sections with deviations of at most 30%. All the experimental observations can be consistently understood in terms of the long range electron correlation among the continuum electrons which gives rise to their preferential back-to-back emission. This alignment effect, which is observed here for the first time, allows controlling the PDI dynamics through a purely geometrical modification of the target initial state without changing its internal energy.
This thesis serves two main purposes:
1. The introduction of a novel experimental method to investigate phase change dynamics of supercooled liquids
2. First-time measurements for the crystallization behaviour for hydrogen isotopes under various conditions
1) The new method is established by the synergy of a liquid microjet of ~ 5 µm diameter and a scattering technique with high spatial resolution, here linear Raman spectroscopy. Due to the high directional stability and the known velocity of the liquid filament, its traveling axis corresponds to a time axis static in space. Utilizing evaporative cooling in a vacuum environment, the propagating liquid cools down rapidly and eventually experiences a phase transition to the crystalline state. This temporal evolution is probed along the filament axis, ultimately resulting in a time resolution of 10 ns. The feasibility of this approach is proven successfully within the following experiments.
2) A main object of study are para-hydrogen liquid filaments. Raman spectra reveal a temperature gradient of the liquid across the filament. This behaviour can quantitatively be reconstructed by numerical simulations using a layered model and is rooted in the effectiveness of evaporative cooling on the surface and a finite thermal conductivity. The deepest supercoolings achieved are ~ 30% below the melting point, at which the filament starts to solidify from the surface towards the core. With a crystal growth velocity extracted from the data the appropriate growth mechanism is identified. The crystal structure that initially forms is metastable and probably the result of Ostwald’s rule of stages. Indications for a transition within the solid towards the stable equilibrium phase support this interpretation.
The analog isotope ortho-deuterium is evidenced to behave qualitatively similar with quantitative differences being mass related.
In further measurements, isotopic mixtures of para-hydrogen and ortho-deuterium are investigated. It is found that the crystallization process starts earlier and lasts significantly longer compared to the pure substances with the maximum values between 20-50% ortho-deuterium content. A solely temperature based explanation for this effect can be excluded. The difference in the quantum character and hence effective size of the isotopes suggests a strong influence of the progressing liquid-solid-interface. Small dilutions of each para-hydrogen and ortho-deuterium with neon show an even more extended crystallization process compared to above isotopic mixtures. Additionally, the crystal is strongly altered in favor of the equilibrium lattice structure of neon.
The implementation of pump-probe experiments with ultrashort laser pulses enables the study of dynamical processes in atoms or molecules, which may provide a deeper inside in their physical origin. The application of this method to systems as nitrous oxide, which is not only a simple example for polyatomic molecules but which also plays a crucial role in the greenhouse effect, promises interesting and beneficial findings. This thesis presents, on the one hand, the technical extension of an existing experimental setup for high-harmonic generation (HHG) and ultra-fast laser physics by an extreme ultraviolet (XUV) spectrometer for the in-situ observation of the harmonic spectrum during ongoing measurements. The present setup enables the production of short laser pulse trains in the XUV spectral range with durations of a few hundred attoseconds (1 as = 10^−18 s) via HHG and supports to perform XUV-IR pump-probe experiments using the infrared (IR) driving field with durations of a few femtoseconds. Moreover, a reaction microscope is implemented, which enables the coincident detection of several charged particles emerging from an ionization or dissociation process and to reconstruct their full 3-D-momentum vectors. With this technique it is possible to perform time-resolved momentum spectroscopy of few-particle quantum systems. Here, the design and the calibration of the XUV spectrometer is presented as well as a first application to the analysis of experimental data by providing information on the produced photon energies. On the other hand, the results of an XUV-pump IR-probe measurement on nitrous oxide (N2O) are discussed. With the broad harmonic spectrum (∼ 17 − 45 eV) it is possible to address several states of the singly and doubly ionized cation. One reaction channel is the single ionization into a stable state of N2O+. Here, the coincidently measured photoelectron energies allow the observation of sidebands, which served to estimate the pulse durations of the involved XUV pulse trains as well as of the fundamental IR pulses. Additionally, single ionization of nitrous oxide can lead to a dissociation into a charged and a neutral fragment. The four respective dissociation channels are compared by presenting their branching ratios, kinetic energy release (KER) distributions and their dependencies on the time delay between pump and probe pulse. In the production of the dication, there are two competitive processes: direct double ionization considering photon energies above the double-ionization threshold, and autoionization of singly ionized and excited molecules in the case of photon energies near the double-ionization threshold. In both cases, the ionization leads to a Coulomb explosion into two charged fragments, where the N − N bond or the N − O bond may dissociate. The influence of the IR-probe field on the ionization yield and the KER was investigated for both dissociation channels and compared. In addition, the corresponding photoelectron energy spectra are presented, which show indications for autoionizing states being involved, and their dependence on the delay and the KER of the respective ions is analyzed.
An investigation of photoelectron angular distributions and circular dichroism of chiral molecules
(2021)
The present work demonstrates the capability of several type of molecular frame photoelectron angular distributions (MFPADs) and their linked chiroptical phenomenon the photoelectron circular dichroism (PECD) to map in great detail the molecular geometry of polyatomic chiral molecules as a function of photoelectron energy. To investigate the influence of the molecular potential on the MFPADs, two chiral molecules were selected, namely 2-(methyl)oxirane (C3H6O, MOx, m = 58,08 uma) and 2-(trifluoromethyl)oxirane (C3H3F3O, TFMOx, m = 112,03 uma). The two molecules differs in one substitutional group and share an oxirane group where the O(1s) electron was directly photoionized with the use of synchrotron radiation in the soft X-ray regime. The direct photoionization of the K-shell electron is well localized in the molecule and it induces the ejection of two or more electrons; the excited system separates into several charged (and eventually neutral) fragments which undergo Coulomb explosion due to their charges. The electrons and the fragments were detected using the COLd Target Recoil Ion Momentum Spectroscopy (COLTRIMS) and the momentum vectors calculated for each fragment belonging from a single ionization. The former method gives the possibility to post-orient molecules in space, giving access to the molecular frame, thus the MFPAD and its related PECD for multiple light propagation direction.
Stereochemistry (from the Greek στερεο- stereo- meaning solid) refers to chemistry in three dimensions. Since most molecules show a three-dimensional structure (3D), stereochemistry pervades all fields of chemistry and biology, and it is an essential point of view for the understanding of chemical structure, molecular dynamics and molecular reactions. The understanding of the chemistry of life is tightly bounded with major discoveries in stereochemistry, which triggered tremendous technical advancements, making it a flourishing field of research since its revolutionary introduction in late 18th century. In chemistry, chirality is a brunch of stereochemistry which focuses on objects with the peculiar geometrical property of not being superimposable to their mirror-images. The word chirality is derived from the Greek χειρ for “hand”, and the first use of this term in chemistry is usually attributed to Lord Kelvin who called during a lecture at the Oxford University Junior Scientific Club in 1893 “any geometrical figure, or group of points, “chiral”, and say that it has chirality if its image in a plane mirror, ideally realized, cannot be brought to coincide with itself.”. Although the latter is usually considered as the birth of the word chirality, the concept underlying it was already present in several fields of science (above all mathematics), already proving the already multidisciplinary relevance of chirality across many field of science and beyond. Nature shows great examples of chiral symmetry on all scales. Empirically, it is possible to observe it at macroscopic scale (e.g. distribution of rotations of galaxies), down to the microscopic scale (e.g. structure of some plankton species), but it is at the molecular level where the number gets remarkable: most of the pharmaceutical drugs, food fragrances, pheromones, enzymes, amino acids and DNA molecules, in fact, are chiral. Moreover, the concept of chirality goes far beyond the mere spatial symmetry of objects being crucially entangled with the fundamental properties of physical forces in nature. The symmetry breaking, namely the different physical behaviour of a two chiral systems upon the same stimuli, is considered to be one of the best explanation for the long standing questions of homochirality in biological life, and ultimately to the chemical origin of life on Earth as we know it. Our organism shows high enantio-selectivity towards specific compounds ranging from drugs, to fragrances. Over 800 odour molecules commonly used in food and fragrance industries have been identified as chiral and their enantiomeric forms are perceived to have very different smells, as the well-know example of D- and L- limonene. Similarly, responses to pharmaceuticals drugs can be enantiomer specific, and in fact about 60 % the drugs currently on the market are chiral compounds, and nearly 90 % of them are sold as racemates. The same degree of enantio-selectivity is observed in the communications systems of plants and insects. Plants produce lipophilic liquids with high vapour pressure called plant volatiles (PVs) which are synthesized via different enzymes called tarpene synthases that are usually chiral. Chiral molecules and chiral effects have a strong impact on all the fields of science with exciting developments ranging from stereo-selective synthesis based on heterogeneous enantioselective catalysis, to optoelctronics, to photochemical asymmetric synthesis, and chiral surface science, just to cite a few.
Chiral molecules come in two forms called enantiomers. Their almost identical chemical and physical properties continue to pose technical challenges concerning the resolution of racemic mixtures, the determination of the enantiomeric excess, and the direct determination of the absolute configuration of an enantiomer. ...
The present work deals with photoionization in the realm of the absorption of one single photon. The formal treatment of one-photon ionization usually employs a semi-classical approach, where the electron’s initial and final states are described as quantum-mechanical wave functions but the photon is treated as a classical electromagnetic wave. In the calculation of photoionization cross sections with this semi-classical method, there is an often used approximation which is called the electric dipole approximation. Mathematically, the application of the dipole approximation corresponds to truncating the series expansion of an exponential after the leading term. Physically, this means neglecting the linear photon momentum and the spatial dependence of the light field. The dipole approximation is valid if the wavelength of the light is much larger than the spatial extent of the target and if the photon momentum is small compared to the momenta of the reaction products, which is generally the case for photon energies short above the electron binding energy.
For the present work, we experimentally investigated nondipolar photoionization, i.e., one-photon ionization at high photon energies where the dipole approximation breaks down. In our experiments, we irradiated single atoms and molecules with such high-energetic photons and measured the three-dimensional momentum distributions of the reaction fragments to uncover the effects of the linear photon momentum and the spatially-dependent light field on photoionization. Our observations allow the first profound insight into photoionization that reveals all photon properties, i.e., photon energy, spin, linear momentum, and the speed of light. Hopefully, our efforts make a constructive contribution to the understanding and the further exploration of light-matter interaction.
This work gives a detailed introduction into a fully new experimental method to investigate the quantum crystal behavior of solid Helium-4. It has been found that a fascinating new effect occurs in the expansion of solid Helium-4 into a vacuum through pinhole orifices with diameters between 1 and 5 µm. It is observed that the beam flux intensity shows a periodic behavior for source conditions corresponding to the solid phase of Helium-4. The period is in the range of seconds up to minutes. It shows a strong dependence on temperature and source pressure. The oscillating part of the beam flux intensity amounts several percent of the total flux. This new phenomenon has been studied for temperatures between 2.1 K and 1.3 K and pressures up to 30 bar above the melting pressure. The beam flux intensity has been recorded by the vacuum pressure in a pitot vacuum chamber. The jet velocity in the range of 200 m/sec indicates that surprisingly the beam is a liquid jet, whereas the conditions in the source correspond to the solid state. In this work mainly the behavior of the flux modulation has been studied as a function of pressure and temperature and the influence of the isotope Helium-3. Furthermore geometrical aspects such as the influence of the nozzle diameter d0 have been investigated. In order to explain this novel phenomenon a kinetic model based on the injection of excess vacancies into the solid is proposed. According to this model the vacancies are generated at a solid/liquid interface. Forced by drift and diffusion they accumulate at some distance from the orifice, leading to the collapse of the solid. With the subsequent re-injection of vacancies the effect repeats and turns out to be periodical. The reproducibility of the time dependent beam flux intensity is demonstrated for a wide range of temperatures and pressures and gives direct access to values such as the temperature and pressure dependence of the vacancy diffusion coefficient Dv in the range of 10 high -5 cm high 2/sec, the recombination time of vacancies with interstitials T r near 1-20 sec and the vacancy activation energy f near 20 K. The good agreement with former experimental results by Zuev et al. [131] confirms the applicability of the theoretical model. As a result from the kinetic model the vacancy concentration is increased above the equilibrium vacancy concentration, caused by the injection of excess vacancies. Therefore, the most important discovery is the possibility of generating a non-equilibrium quantum solid. The investigation of this non-equilibrium solid leads to the discovery of a fluid-like regime in the solid phase of Helium-4 at temperatures below T = 1.58 K. The result gives a strong indication for the supersolid state, especially because the fluid-like behavior of the solid can be eliminated with smallest concentrations of Helium-3.