Precision Improvements of Penning Trap Mass Measurements Using Highly Charged Ions : Applications to solving current problems in fundamental physics

Fritioff, Tomas

January 2002

In my thesis I describe the improvements of the Penning trap mass spectrometer SMILETRAP. The objective of these improvements have been to increase the reliability and the accuracy with which an atomic mass can be measured using highly charged ions. The improvements have been achieved by stabilizing both the electric and magnetic fields of the trap and by improving the technical performance of the trap system. As a result it has been possible to measure accurately the mass of several atoms ranging from hydrogen to mercury using charge states from 1+ to 52+. It was only possible to use the highest charge states after applying a successful cooling of these ions with Helium during the charge breeding. The technical improvements made a number of interesting accurate mass measurements possible. The measurements of the 3H, 3He, and 4He masses showed that the previously values were wrong. The mass difference between 3H and 3He which is the Q-value of the tritium beta decay has been determined to 18.588(3) keV. The Q-value of the double β-decay of 76Ge was measured at an accuracy of 50 eV. This value is indispensable for the evaluation the Heidelberg-Moscow experiment which aims at finding a possible neutrino-less decay which if present would be a violation of the standard model. The mass ratio of mCs/mp is used to determine the fine structure constant independent of QED calculations. The two decades old anomaly in the mass values of Hg was solved by the mass determination of 198Hg and 204Hg. The mass of 24Mg was measured at an uncertatinty of 0.6 ppb and will be used in the determination of the g-factor of a bound electron in a hydrogen like ions.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Measuring magnetization in Nickel Ferrite samples using odd and even harmonics

Jatkar, Kasturie

January 2020

No description available.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Temporal Characterization and Intensity Contrast Improvement of Few-cycle Laser Pulses

Zhang, Xiaoying

January 2019

Due to the unique combination of properties of high intensity and few optical cycle pulse duration, the ultrashort laser pulses have widespread applications in pump-probe spectroscopy and laser-plasma interaction. Correspondingly, it is critical to precisely measure the electric field in the temporal or spectral domain. Since there are no shorter pulses available to sample them in time, it is not easy to characterize few-cycle pulses. In this thesis, the temporal characterization methods including second harmonic generation (SHG) interferometric autocorrelation, single-shot SHG frequency-resolved optical gating (FROG) and chirp scan are used to measure the laser pulses at different positions in our laser system, the Light Wave Synthesizer-20. The SHG interferometric autocorrelation measured a 25.3 fs pulse duration after the kHz frontend laser with a 24.5 fs Fourier limit (FL). The FROG is tested by measuring seed pulses with a 6.5 fs FL providing 6.7 fs pulse duration with mostly flat phase. Then, this FROG apparatus is used to characterize the amplified pulses with a 4.5 fs FL after the whole laser system. The measured pulse duration is 4.5 fs reaching the FL. Similarly, the chirp scan is also used to measure the amplified pluses with a slightly different spectral phase, which retrieved a longer pulse duration of 5.2 fs. The second part of the thesis is focused on contrast improvement. The temporal intensity contrast is reduced in the amplification process leading to a deteriorated laser-plasma interaction. Contrast improvement based on the nonlinear elliptical polarization rotation (NER) technique in a hollow-core fiber (HCF) is implemented and its optimization is performed by using high extinction ratio polarizer, utilizing Ar gas and testing smaller polarization ellipticity (NER angle). The optimal condition is found to be 7° NER angle and 650 mbar Ar in the HCF. Under this optimal condition, sub-4 fs pulses with a smooth spectrum are generated with a power above 30 mW. The NER efficiency is higher than 50%. After amplification to 75 mJ energy with sub-5 fs duration the measured contrast improvement is 3 order of magnitude. In conclusion, the intense few-cycle pulses have been fully characterized by FROG and chirp-scan techniques. Furthermore, the NER method is promising to get cleaned pulses with higher than 3 order of magnitude contrast enhancement.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Observation, control, and automation of an OPCPA system

Nagy, Gergely

January 2020

No description available.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Generation and characterization of intense attosecond XUV pulses

Wu, Xiuyu

January 2019

Electronic dynamics in molecules and atoms takes place on the attosecond timescale. For the observation of such processes, measurement techniques with attosecond resolution are needed. High-harmonic generation (HHG) in gas medium provides an ultrashort light source on the attosecond timescale for observing, understanding and controlling light-induced process on this scale with the necessary time resolution. To be able to use these attosecond pulses to measure electron dynamics, they have to be characterized. For this characterization, the XUV spectrum is extremely important. The XUV spectrum not only contains the information about the photon energies of the pulses, but also temporal information such as the difference between a single isolated attosecond pulse or an attosecond pulse train. The Light Wave Synthesizer 20 generates intense femtosecond pulses with a peak power of 16 TW and a spectrum spanning over the region from 580 to 1000 nm. This allow one to generate attosecond pulses based on HHG in gas medium with 100 eV photon energy and up to 20 nJ pulse energy. The generated attosecond pulses can be observed with a photodiode to measure the energy, an XUV CCD used as a profiler and an XUV flat-field spectrometer. The detector of the flat-field spectrometer is an XUV CCD which records the diffracted beam from a grating. Hence, a certain pixel of the camera shows the intensity for a certain range of photon energies. However, the calibration from pixel to energy is not always fixed due to e.g. the alignment of the spectrometer. This pixel to photon energy calibration can be done either by using the harmonic peaks in the XUV spectra or theoretical analyses of the spectrometer structure. In this thesis, both methods are investigated and the results are in good agreement. Due to the analytical calibration has a lower error and faster to do, future measurements can be evaluated with the analytical method.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Contrast improvement of few-cycle pulses

Zhang, Xiaoying

January 2019

The intense few-cycle laser pulses play an important role in the investigations of laser-plasma interaction. However, one of the biggest challenges in their generation is the reduction of temporal intensity contrast by introducing undesired pre-pulses and a long pedestal. Two techniques were investigated in this work to improve the contrast. First, the crossed-polarized wave (XPW) generation was optimized to get clean pulse. The conditions for XPW were optimized including crystal thickness and maximal background pressure in the vacuum cell. Second, the method of elliptical polarization rotation (EPR) in a gas-filled hollow-core fiber (HCF) was implemented to produce both broadened and cleaned pulse, since its setup is much simpler. For the tested EPR-based nonlinear filter, the spectral smoothening and broadening were obtained. The contrast of cleaned pulse was characterized providing 2 order of magnitude contrast enhancement, while it had a high average power of 80 mW. The EPR-based nonlinear filter is a promising simplified technique in the development of intense few-cycle lasers.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Optimization of Intense Attosecond XUV Pulses

Wu, Xiuyu

January 2019

To observe electron dynamics in molecules and atoms which takes place on the attosecond timescale, single isolated attosecond pulses are required utilized in performing pump–probe experiments. The Light Wave Synthesizer 20 generates intense sub-5 fs pulses with a peak power of 16 TW and a broad spectrum. This offers a chance of generating isolated attosecond pulses via high harmonic generation (HHG) in gas medium. In this project, the variation of cutoff energy of HHG with different intensities of the driving laser was investigated. In addition, an isolated attosecond pulse with an Fourier-limited pulse duration of 188 as is produced with a selection of 15 eV around the cutoff region. Moreover, one optimization method refer to GDD scan was illustrated to optimize the HHG cutoff and continuum.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Investigations of coherent and incoherent diffractive imaging

Vantaraki, Christina

January 2020

No description available.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

Multi-angle Oblique Optical Coherence Tomography

Malmström, Mikael

January 2008

Optical Coherence Tomography (OCT) is a non-invasive high-resolutionmethod for measuring the reectance of scattering media in 1/2/3D, e.g.skin. The method has been used in a number of dierent medical elds andfor measurement of tissue optical properties.The software developed in this thesis is able to display features hidden ina shadowed volume by adding multiple OCT measurements taken at obliqueangles, a technique here called Multiple-Angle Oblique Optical CoherenceTomography (MAO-OCT).Three dierent objects with were measured at 5 to 9 angles. The measurementswere automatically and manually aligned in the software. They werealso tested with 6 dierent high pass intensity lters (HPIF) and reduced insize using 4 dierent methods to speed up calculations.The software's automatic alignment was tested with one tilted computergenerated test at 9 angles and with 5 dierent shadow strengths.With MAO-OCT it is possible to remove some eects of shadows in OCT,though it comes with a cost of reduced sharpness. The errors depend muchon the dierences in index of refraction in the sample.The software managed to automatically align 90% of the articial measurements,and 60% of the OCT measurements. The shadow strength andthe resize method had no noticeable eect on the automatic alignment of themeasurements.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik

How to measure the Transverse Chromatic Aberration of the human eye in off-axis angels

Daemi, Bita

January 2011

Peripheral vision plays an important role for visually impaired people with central field loss. Furthermore, recent studies show that defocus in the image on the peripheral retina might influence the development of myopia. Apart from the refractive errors and astigmatism, off-axis aberrations such as coma and transverse chromatic aberration (TCA) also influence the image quality on the peripheral retina. Theory shows that the amount of TCA is quite large in peripheral vision especially in large off-axis angles. The aim of this study is to develop a method to measure the amount of TCA in the peripheral field of view of the human eye. The method which was used for this study was subjective and the amount of TCA was measured in the left eye of the three volunteer adult subjects. The method was based on measuring the TCA as a chromatic difference of position outside of the eye. The measurements were done in the nasal retina of the eye in seven angles from 0 deg eccentricity (fovea) to 60 deg eccentricity. To compare the experimental results with theoretical values two schematic eye models were implemented in ZEMAX optical design software; a reduced eye model and a wide angle eye model. The results showed the expected increase of TCA with off-axis angle. The measurements for two subjects were in good agreement with the eye models. The magnitudes for TCA varied between subjects, one reason for this can be related to the different shapes of the eye in different subjects. The third subject had different values for TCA. This difference led us to investigate the reliability and the repeatability of the method in more detail.

Atom and Molecular Physics and Optics

Atom- och molekylfysik och optik