Development and Characterisation of a Laser-Based Hard X-Ray Source

Carl Tillman

Development and Characterisation of a Laser-Based Hard X-Ray Source

Carl Tillman

Research output: Thesis › Doctoral Thesis (compilation)

Abstract

A laser-produced plasma was generated by focusing 100 fs laser pulses, with an energy of 150 mJ, onto metal targets. The laser intensity was expected to reach 10E17 W/cm2. Radiation was emitted from the created plasma, with photon energies extending up to the MeV regime. The laser-based X-ray source was optimised, with the purpose of making it a realistic source of hard X-rays (>10 keV). Dedicated equipment was developed for efficient generation and utilisation of the hard X-rays.

The X-ray source was characterised with respect to its spatial extent and the X-ray yield. Measurements were made of the spectral distribution, by the use of single-photon-counting detectors in different geometries, crystal spectro-meters and dose measurements in combination with absorption filters. Ablation of the target material in the laser-produced plasma was investigated.

Imaging applications have been demonstrated, including ultrafast (picosecond) X-ray imaging, magnification imaging of up to x80, differential imaging in the spectral domain, and imaging of various biological and technical objects.

The biological response of ultra-intense X-ray pulses was assessed in cell-culture exposures. The results indicate that the biological response from ultra-intense X-ray exposures is similar to the response from exposures with conventional X-ray tubes.

Original language	English
Qualification	Doctor
Awarding Institution	Atomic Physics
Supervisors/Advisors	[unknown], [unknown], Supervisor, External person
Award date	1996 Dec 19
Publisher	Department of Physics, Lund University
ISBN (Print)	91-628-2234-9
Publication status	Published - 1996
Externally published	Yes

Bibliographical note

Defence details

Date: 1996-12-19
Time: 13:15
Place: Hörsal B, Fysicum, Lund

External reviewer(s)

Name: Mysyrowicz, André
Title: Prof.
Affiliation: Laboratoire d'Optique Appliquée, ENSTA-Centre de l'Yvette, F-91125 Palaiseau Cedex, France

---

Subject classification (UKÄ)

Atom and Molecular Physics and Optics

Free keywords

laser-produced plasma
X-ray source
laser
X-ray spectroscopy
dosimetry
radiography
medical imaging
radiation effects
differential imaging
Fysicumarkivet A:1996:Tillman
Atom- och molekylärfysik
Atomic and molecular physics

Cite this

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title = "Development and Characterisation of a Laser-Based Hard X-Ray Source",

abstract = "A laser-produced plasma was generated by focusing 100 fs laser pulses, with an energy of 150 mJ, onto metal targets. The laser intensity was expected to reach 10E17 W/cm2. Radiation was emitted from the created plasma, with photon energies extending up to the MeV regime. The laser-based X-ray source was optimised, with the purpose of making it a realistic source of hard X-rays (>10 keV). Dedicated equipment was developed for efficient generation and utilisation of the hard X-rays. The X-ray source was characterised with respect to its spatial extent and the X-ray yield. Measurements were made of the spectral distribution, by the use of single-photon-counting detectors in different geometries, crystal spectro-meters and dose measurements in combination with absorption filters. Ablation of the target material in the laser-produced plasma was investigated. Imaging applications have been demonstrated, including ultrafast (picosecond) X-ray imaging, magnification imaging of up to x80, differential imaging in the spectral domain, and imaging of various biological and technical objects. The biological response of ultra-intense X-ray pulses was assessed in cell-culture exposures. The results indicate that the biological response from ultra-intense X-ray exposures is similar to the response from exposures with conventional X-ray tubes.",

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author = "Carl Tillman",

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N1 - Defence details Date: 1996-12-19 Time: 13:15 Place: Hörsal B, Fysicum, Lund External reviewer(s) Name: Mysyrowicz, André Title: Prof. Affiliation: Laboratoire d'Optique Appliquée, ENSTA-Centre de l'Yvette, F-91125 Palaiseau Cedex, France ---

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N2 - A laser-produced plasma was generated by focusing 100 fs laser pulses, with an energy of 150 mJ, onto metal targets. The laser intensity was expected to reach 10E17 W/cm2. Radiation was emitted from the created plasma, with photon energies extending up to the MeV regime. The laser-based X-ray source was optimised, with the purpose of making it a realistic source of hard X-rays (>10 keV). Dedicated equipment was developed for efficient generation and utilisation of the hard X-rays. The X-ray source was characterised with respect to its spatial extent and the X-ray yield. Measurements were made of the spectral distribution, by the use of single-photon-counting detectors in different geometries, crystal spectro-meters and dose measurements in combination with absorption filters. Ablation of the target material in the laser-produced plasma was investigated. Imaging applications have been demonstrated, including ultrafast (picosecond) X-ray imaging, magnification imaging of up to x80, differential imaging in the spectral domain, and imaging of various biological and technical objects. The biological response of ultra-intense X-ray pulses was assessed in cell-culture exposures. The results indicate that the biological response from ultra-intense X-ray exposures is similar to the response from exposures with conventional X-ray tubes.

AB - A laser-produced plasma was generated by focusing 100 fs laser pulses, with an energy of 150 mJ, onto metal targets. The laser intensity was expected to reach 10E17 W/cm2. Radiation was emitted from the created plasma, with photon energies extending up to the MeV regime. The laser-based X-ray source was optimised, with the purpose of making it a realistic source of hard X-rays (>10 keV). Dedicated equipment was developed for efficient generation and utilisation of the hard X-rays. The X-ray source was characterised with respect to its spatial extent and the X-ray yield. Measurements were made of the spectral distribution, by the use of single-photon-counting detectors in different geometries, crystal spectro-meters and dose measurements in combination with absorption filters. Ablation of the target material in the laser-produced plasma was investigated. Imaging applications have been demonstrated, including ultrafast (picosecond) X-ray imaging, magnification imaging of up to x80, differential imaging in the spectral domain, and imaging of various biological and technical objects. The biological response of ultra-intense X-ray pulses was assessed in cell-culture exposures. The results indicate that the biological response from ultra-intense X-ray exposures is similar to the response from exposures with conventional X-ray tubes.

KW - laser-produced plasma

KW - X-ray source

KW - laser

KW - X-ray spectroscopy

KW - dosimetry

KW - radiography

KW - medical imaging

KW - radiation effects

KW - differential imaging

KW - Fysicumarkivet A:1996:Tillman

KW - Atom- och molekylärfysik

KW - Atomic and molecular physics

M3 - Doctoral Thesis (compilation)

SN - 91-628-2234-9

PB - Department of Physics, Lund University

ER -

Development and Characterisation of a Laser-Based Hard X-Ray Source

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

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Cite this