TEDDI: Tomographic Energy Dispersive Diffractive Imaging
X-rays have revolutionised our understanding of the micro and macro world. TEDDI is a revolutionary new X-ray technique that holds the promise of becoming a main-stream analysis and characterisation tool for a wide range of applications by using the principles of X-ray tomography, X-ray diffraction and X-ray fluorescence.
The TEDDI process allows the user to obtain X-ray diffraction data from a sample, enabling analysis of the samples internal structure.
TEDDI has a wide range of applications including analysis of pathological tissues, security, non-destructive testing of engineering parts and archeology.
Aims
To produce an entirely new imaging concept with numerous applications in science, engineering and processing technologies. To achieve this goal, this projects seeks to:
- manufacture high aspect ratio X-ray collimators coupled with the creation of inexpensive and scaleable X-ray detectors to greatly increase the spatial resolution of TEDDI and data collection rates
- build a high aspect ratio X-ray collimator and design a robust manufacturing route for the rapid creation of X-ray collimators using high fluence (J/cm ) short wavelength lasers
- couple the X-ray collimators with new inexpensive X-ray detectors to allow rapid (seconds) non-destructive characterisation of a test piece
Results
The first X-ray collimator employed a patent pending alignment and drilling process. The collimator holes were laser drilled using a nanosecond pulse duration DPSS (Diode Pumped Solid State) laser operating at 355nm. Testing of the collimator has revealed collimation of the X-rays through the array, but also revealed a misalignment of some of the holes within each of the discrete tungsten drilled plates. The next version will use a more robust version of the alignment and drilling procedure and will employ a DPSS femtosecond laser to enhance the laser drilled hole quality.
Conclusions
The fast and reconfigurable manufacture of a high aspect ratio X-ray collimator with a DPSS nanosecond pulse duration laser has been demonstrated with the creation of the version 1 collimator. A new concept for collimator production has been developed and will be realised in the near future.
Collaborators
- Spectra Physics UK Ltd
- RAL
- Culham Lab
- Daresbury Lab
- Manchester University
- Birkbeck College
Researchers
L. Tunna
Funding
Duration
2003 - 2005