Abstract
This dissertation research aims to develop a cavity as a converter for laser radiation into soft X-rays, and to characterise this thermal radiation. The concept of indirect heating allows for the production of a spatially homogenous plasma at solid state density. For the purpose of this research, the Nhelix laser system has been extended by a second oscillator with a shorter pulse length, and the optical system layout has been redesigned for both beams. This dissertation presents data on the energy loss of Ar-ions in plasma targets generated by direct heating of carbon foils with the Nhelix laser. Due to the use of a new ion detector, the energy resolution ({delta}E/E{approx}0.1%) and the signal-to-noise ratio of the measurements were improved. Measurements with thin carbon foil showed the maximum energy loss in the plasma to be 31% above the energy loss in comparison with the cold foil. The transparency of thin carbon foils for laser light has been investigated as a function of foil thickness and pulse length, which resulted in a maximum laser pulse length applicable for a certain foil thickness and laser intensity. an interferometer was developed and constructed, with which the electron density could be determined with spatial
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Citation Formats
Schaumann, G.
Experiments with laser heated cavity targets for the investigation of heavy ion-plasma interaction; Experimente mit lasergeheizten Hohlraeumen fuer die Untersuchung der Wechselwirkung von Schwerionen mit ionisierter Materie.
Germany: N. p.,
2007.
Web.
Schaumann, G.
Experiments with laser heated cavity targets for the investigation of heavy ion-plasma interaction; Experimente mit lasergeheizten Hohlraeumen fuer die Untersuchung der Wechselwirkung von Schwerionen mit ionisierter Materie.
Germany.
Schaumann, G.
2007.
"Experiments with laser heated cavity targets for the investigation of heavy ion-plasma interaction; Experimente mit lasergeheizten Hohlraeumen fuer die Untersuchung der Wechselwirkung von Schwerionen mit ionisierter Materie."
Germany.
@misc{etde_21060521,
title = {Experiments with laser heated cavity targets for the investigation of heavy ion-plasma interaction; Experimente mit lasergeheizten Hohlraeumen fuer die Untersuchung der Wechselwirkung von Schwerionen mit ionisierter Materie}
author = {Schaumann, G}
abstractNote = {This dissertation research aims to develop a cavity as a converter for laser radiation into soft X-rays, and to characterise this thermal radiation. The concept of indirect heating allows for the production of a spatially homogenous plasma at solid state density. For the purpose of this research, the Nhelix laser system has been extended by a second oscillator with a shorter pulse length, and the optical system layout has been redesigned for both beams. This dissertation presents data on the energy loss of Ar-ions in plasma targets generated by direct heating of carbon foils with the Nhelix laser. Due to the use of a new ion detector, the energy resolution ({delta}E/E{approx}0.1%) and the signal-to-noise ratio of the measurements were improved. Measurements with thin carbon foil showed the maximum energy loss in the plasma to be 31% above the energy loss in comparison with the cold foil. The transparency of thin carbon foils for laser light has been investigated as a function of foil thickness and pulse length, which resulted in a maximum laser pulse length applicable for a certain foil thickness and laser intensity. an interferometer was developed and constructed, with which the electron density could be determined with spatial resolution, and for the first time also at different times during the experiment. This diagnostic provides images of the interference pattern with a time difference of 1.5 ns and allows determination of the free electron density up to a maximum density of 2 x 10{sup 20} cm{sup -3}. In order to characterise the cavity radiation, a spectrometer with high time resolution was developed and calibrated in terms of absolute intensity units with a deuterium-lamp. While the laser heats the cavity, the rise in temperature was measured with a time resolution <1 ns up to a maximal radiation temperature of 73{+-}8 eV/k{sub B} (85 x 10{sup 4} C). For this particular cavity geometry, conversion efficiency (with time resolution) of laser energy to thermal energy of the cavity radiation has been derived from the measurements of the development of radiation temperature. (orig.)}
place = {Germany}
year = {2007}
month = {Jul}
}
title = {Experiments with laser heated cavity targets for the investigation of heavy ion-plasma interaction; Experimente mit lasergeheizten Hohlraeumen fuer die Untersuchung der Wechselwirkung von Schwerionen mit ionisierter Materie}
author = {Schaumann, G}
abstractNote = {This dissertation research aims to develop a cavity as a converter for laser radiation into soft X-rays, and to characterise this thermal radiation. The concept of indirect heating allows for the production of a spatially homogenous plasma at solid state density. For the purpose of this research, the Nhelix laser system has been extended by a second oscillator with a shorter pulse length, and the optical system layout has been redesigned for both beams. This dissertation presents data on the energy loss of Ar-ions in plasma targets generated by direct heating of carbon foils with the Nhelix laser. Due to the use of a new ion detector, the energy resolution ({delta}E/E{approx}0.1%) and the signal-to-noise ratio of the measurements were improved. Measurements with thin carbon foil showed the maximum energy loss in the plasma to be 31% above the energy loss in comparison with the cold foil. The transparency of thin carbon foils for laser light has been investigated as a function of foil thickness and pulse length, which resulted in a maximum laser pulse length applicable for a certain foil thickness and laser intensity. an interferometer was developed and constructed, with which the electron density could be determined with spatial resolution, and for the first time also at different times during the experiment. This diagnostic provides images of the interference pattern with a time difference of 1.5 ns and allows determination of the free electron density up to a maximum density of 2 x 10{sup 20} cm{sup -3}. In order to characterise the cavity radiation, a spectrometer with high time resolution was developed and calibrated in terms of absolute intensity units with a deuterium-lamp. While the laser heats the cavity, the rise in temperature was measured with a time resolution <1 ns up to a maximal radiation temperature of 73{+-}8 eV/k{sub B} (85 x 10{sup 4} C). For this particular cavity geometry, conversion efficiency (with time resolution) of laser energy to thermal energy of the cavity radiation has been derived from the measurements of the development of radiation temperature. (orig.)}
place = {Germany}
year = {2007}
month = {Jul}
}