Study of macroscopic and microscopic homogeneity of DEPFET X-ray detectors

Bergbauer, Bettina

17 December 2015

For the X-ray astronomy project Advanced Telescope for High ENergy Astrophysics (Athena) wafer-scale DEpleted P-channel Field Effect Transistor (DEPFET) detectors are proposed as Focal Plane Array (FPA) for the Wide Field Imager (WFI). Prototype structures with different pixel layouts, each consisting of 64 x 64 pixels, were fabricated to study four different DEPFET designs. This thesis reports on the results of the electrical and spectroscopic characterization of the different DEPFET designs. With the electrical qualification measurements the transistor properties of the DEPFET structures are investigated in order to determine whether the design intentions are reflected in the transistor characteristics. In addition, yield and homogeneity of the prototypes can be studied on die, wafer and batch level for further improvement of the production technology with regard to wafer-scale devices. These electrical characterization measurements prove to be a reliable tool to preselect the best detector dies for further integration into full detector systems. The spectroscopic measurements test the dynamic behavior of the designs as well as their spectroscopic performance. In addition, it is revealed how the transistor behavior translates into the detector performance. This thesis, as the first systematic study of different DEPFET designs on die and detector level, shows the limitations of the current DEPFET assessment methods. Thus, it suggests a new concise characterization procedure for DEPFET detectors as well as guidelines for expanded testing in order to increase the general knowledge of the DEPFET. With this study of four different DEPFET variants not only designs suitable for Athena mission have been found but also improvement impulses for the starting wafer-scale device production are provided.

info:eu-repo/classification/ddc/621

ddc:621

info:eu-repo/classification/ddc/537

ddc:537

Electronic Structure Investigation of Novel Superconductors / Elektronische Struktur neuartiger Supraleiter

Buling, Anna

14 August 2014

The discovery of superconductivity in iron-based pnictides in 2008 gave rise to a high advance in the research of high-temperature superconductors. But up to now there is no generally admitted theory of the non-BCS mechanism of these superconductors. The electron and hole doped Ba122 (BaFe2As2) compounds investigated in this thesis are supposed to be suitable model systems for studying the electronic behavior in order to shed light on the superconducting mechanisms. The 3d-transiton metal doped Ba122 compounds are investigated using the X-ray photoelectron spectroscopy (XPS), X-ray absorption spectroscopy (XAS), X-ray emission spectroscopy (XES) and X-ray magnetic circular dichroism (XMCD), while the completely hole doped K122 is observed using XPS. The experimental measurements are complemented by theoretical calculations. A further new class of superconductors is represented by the electride 12CaO*7Al2O3: Here superconductivity can be realized by electrons accommodated in the crystallographic sub-nanometer-sized cavities, while the mother compound is a wide band gap insulator. Electronic structure investigations, represented by XPS, XAS and resonant X-ray photoelectron spectroscopy (ResPES), carried out in this work, should help to illuminate this unconventional superconductivity and resolve a debate of competing models for explaining the existence of superconductivity in this compound.

Superconductors

X-Ray Spectroscopy

Pnictides

Supraleiter

Röntgenspektroskopie

Pnictide

33.07 - Spektroskopie

33.74 - Supraleitung

33.61 - Festkörperphysik

ddc:530

ddc:500

X-ray Spectroscopy in the Intense Laser-Solid Interactions

Pan, Xiayun

24 October 2024

High-intensity, short-pulse laser-solid interactions are of great importance for a number of applications and fundamental research, such as high energy density (HED) physics, laboratory astrophysics, inertial confinement fusion (ICF), particle acceleration, and ultrafast x-ray sources. X-ray spectroscopy is a powerful diagnostic tool to investigate the extreme states of matter created by these interactions. This thesis presents the development and application of x-ray spectroscopy in relativistic laser-solid interactions. Two x-ray crystal spectrometers have been developed on the DRACO and European X-ray Free Electron Laser (XFEL) facilities for the diagnosis of dense plasmas produced by ultrashort relativistic laser pulses. A high-resolution x-ray crystal spectrometer is developed at the DRACO petawatt laser, measuring the K-shell emission spectra of Ti targets ranging from cold Kα to thermal Heα lines. This spectrometer employs a spherically bent quartz crystal and adopts Johann geometry in the dispersive plane. Geometrical analysis and ray-tracing simulations are implemented, respectively, to determine the most suitable configuration and evaluate the performance of the spectrometer, showing an excellent spectral resolution of E/δE≈15000. With the quartz spectrometer, the production and transport of hot electrons as well as the heating state in the proton acceleration Ti targets can be investigated at the DRACO petawatt laser. In addition, a multipurpose imaging x-ray crystal spectrometer is developed for the HED instrument of the European XFEL. This spectrometer is designed to measure x-rays in the energy range of 4 - 10 keV, providing high-resolution, spatially-resolved spectral measurements. A toroidally bent germanium (Ge) crystal is used, allowing x-ray diffraction from the crystal to image along a one-dimensional spatial profile while spectrally resolving along the other. A detailed geometrical analysis is performed to determine the curvature of the crystal. The theoretical performance of the spectrometer in various configurations is calculated by ray-tracing simulations. The key properties of the spectrometer, including the spectral and spatial resolution, are demonstrated experimentally on different platforms. Experimental results prove that this Ge spectrometer is a powerful tool for spatially resolved measurements of x-ray emission, scattering, or absorption spectra in high energy density physics. The enhancement effect of a microstructured surface on laser absorption and characteristic Kα emission has been investigated by measuring K-shell emission from titanium (Ti) targets irradiated with high-intensity (~ 10^20 W/cm^2), sub-picosecond (500 fs) laser pulses. The experimental results indicate a modest enhancement (1.6x) of Kα emission from microstructured targets compared to flat foils, but with similar intensity and profile of Heα and Li-like satellites. Particle-in-cell (PIC) simulations are implemented to further understand the underlying physical processes in the laser interaction with both targets, interpreting the mechanisms responsible for the Kα enhancement. The reasons for the lower-than-expected enhancement of Kα emission are discussed. The rapid heating of the bulk plasma might result in the premature shutdown of Kα emission before the thermalization of hot electrons or even the end of laser pulses, suggesting that the use of Kα emission as a diagnostic of the hot-electron yield or relaxation could lead to a misinterpretation. This work reveals that an optimized microstructured target shows promise to produce high-brightness, quasi-monochromatic laser-driven x-ray sources for many probing applications. While x-ray spectroscopy has been widely used for diagnosing the internal conditions of laser-produced plasmas, it is usually very challenging to extract reliable and accurate physical information from the raw x-ray spectra, especially for time- and space-integrated spectra emitting from a range of plasma conditions. In this thesis, a complex spatio-temporally resolved analysis of time- and space-integrated x-ray emission spectroscopy from the relativistic laser plasmas is presented. Particle-in-cell (PIC) simulations using the PICLS code are performed to investigate the laser-solid interaction within a picosecond (ps). The subsequent plasma evolution is simulated with the hydrodynamic code FLASH on a larger timescale (hundreds of ps). With the outputs of PIC and hydrodynamic simulations, atomic kinetics-spectroscopy simulations using the FLYCHK, SCFLY, and ATOMIC codes are performed to generate a series of synthetic spectra. These synthetic spectra are used to reconstruct a composite emission spectrum and then compared to the measured integrated spectra. A full-time evolution of electron density, temperature, and ionization state of laser plasmas is thus extracted, and verified by the comparison between the measured and simulated spectra. By this methodology, the dynamics of ultrafast relativistic laser-plasma systems was studied. The combination of x-ray spectroscopy, atomic physics, and multi-scale (i.e. PIC and hydro-) simulations is demonstrated to be a promising method to characterize the evolution of internal conditions of laser-produced plasmas. This method can also be used as an effective benchmark or reference for these numerical simulations.

info:eu-repo/classification/ddc/530

ddc:530

X-ray Diagnostics of Accretion Plasmas in Selected Soft Polars / Akkretionsplasmen in Polaren mit ausgeprägter weicher Röntgenstrahlung

Traulsen, Iris

06 March 2009

No description available.

520 Astronomie

Mathematics and Computer Science

Kataklysmischer Doppelstern

Weißer Zwerg

Röntgenspektroskopie

XMM-Newton

Cataclysmic variable

White dwarf

X-ray spectroscopy

XMM-Newton

39.40

TBK 000: Hochenergieastronomie

THT 700: Kompakte Sterne {Astronomie}

THT 900: Doppelsterne {Astronomie}