The use of orthogonal bremsstrahlung beams for imaging in radiation therapy /

Sarfehnia, Arman.

January 2006

No description available.

Health Sciences, Radiology.

Biophysics, Medical.

Physics, Radiation.

Image-guided radiotherapy using 2D and 3D ultrasound combined with Monte Carlo dose calculations in prostate treatments

Mark, Clarisse Ildikó.

January 2005

No description available.

Health Sciences, Radiology.

Biophysics, Medical.

Physics, Radiation.

Implementation of 3D external photon beam dosimetry for the McGill Treatment Planning System

DeBlois, François

January 1996

No description available.

Health Sciences, Radiology.

Engineering, Biomedical.

Physics, Radiation.

3-D automatic anatomy-based image registration in portal imaging

Sirois, Luc M.

January 1999

No description available.

Biophysics, Medical.

Health Sciences, Radiology.

Physics, Radiation.

A new penumbra generator for matching of electron for matching of electron fields

Lachance, Bernard, 1967-

January 1996

No description available.

Health Sciences, Radiology.

Physics, Radiation.

Engineering, Biomedical.

Paramètres de blindage photonique d'une salle de radiothérapie

Frenière, Normand

January 1995

No description available.

Engineering, Biomedical.

Health Sciences, Radiology.

Physics, Radiation.

Magnetic field issues in magnetic resonance imaging

Petropoulos, Labros Spiridon

January 1993

No description available.

Physics, Radiation

Magnetic field

Magnetic resonance imaging

MMCTP : a radiotherapy research environment for Monte Carlo and patient-specific treatment planning

Alexander, Andrew William

January 2006

No description available.

Health Sciences, Radiology.

Biophysics, Medical.

Physics, Radiation.

Validation of a Monte Carlo based treatment planning system (TPS) for electron beams

Asiev, Krum

January 2006

No description available.

Health Sciences, Radiology.

Biophysics, Medical.

Physics, Radiation.

Perforated diode neutron sensors

McNeil, Walter J.

January 1900

Doctor of Philosophy / Department of Mechanical and Nuclear Engineering / Douglas S. McGregor / A novel design of neutron sensor was investigated and developed. The perforated, or micro-structured, diode neutron sensor is a concept that has the potential to enhance neutron sensitivity of a common solid-state sensor configuration. The common thin-film coated diode neutron sensor is the only semiconductor-based neutron sensor that has proven feasible for commercial use. However, the thin-film coating restricts neutron counting efficiency and severely limits the usefulness of the sensor. This research has shown that the perforated design, when properly implemented, can increase the neutron counting efficiency by greater than a factor of 4. Methods developed in this work enable detectors to be fabricated to meet needs such as miniaturization, portability, ruggedness, and adaptability. The new detectors may be used for unique applications such as neutron imaging or the search for special nuclear materials. The research and developments described in the work include the successful fabrication of variant perforated diode neutron detector designs, general explanations of fundamental radiation detector design (with added focus on neutron detection and compactness), as well as descriptive theory and sensor design modeling useful in predicting performance of these unique solid-state radiation sensors. Several aspects in design, fabrication, and operational performance have been considered and tested including neutron counting efficiency, gamma-ray response, perforation shapes and depths, and silicon processing variations. Finally, the successfully proven technology was applied to a 1-dimensional neutron sensor array system.

neutron sensor

neutron detector

Engineering, Nuclear (0552)

Physics, Radiation (0756)