Radiation | EPFL Graph Search

In physics, radiation is the emission or transmission of energy in the form of waves or particles through space or through a material medium. This includes:

electromagnetic radiation, such as radio waves, microwaves, infrared, visible light, ultraviolet, x-rays, and gamma radiation (γ)
particle radiation, such as alpha radiation (α), beta radiation (β), proton radiation and neutron radiation (particles of non-zero rest energy)
acoustic radiation, such as ultrasound, sound, and seismic waves (dependent on a physical transmission medium)
gravitational radiation, that takes the form of gravitational waves, or ripples in the curvature of spacetime

Radiation is often categorized as either ionizing or non-ionizing depending on the energy of the radiated particles. Ionizing radiation carries more than 10 eV, which is enough to ionize atoms and molecules and break chemical bonds. This is an important distinction due to the large difference in harmfulness to living organisms. A c

Radiography appliance comprising a movable arm

Thomas Gabella

The invention relates to a radiography appliance comprising a column and a movable arm mounted such that it slides along the column and rotates about an axis oriented perpendicularly to the main direction of the column, one end of the arm comprising a detector and the other end a radiation source. The appliance is characterised in that it comprises means for locking the arm against rotation and/or against translation.

2016

Analysis of Femtosecond Electron Bunches at the SwissFEL Injector Test Facility

Bennie Smit

The SwissFEL (Swiss Free Electron Laser) is a free electron laser which is being built at the Paul Scherrer Institute. The SwissFEL will be a user facility to study processes on unexplored scales of space and time. In order to achieve these aims, X-ray pulses on the order of femtoseconds must be generated. For such short X-ray pulses, the electron bunch length must be comparable to the final X-ray pulse length. In order to achieve such a short electron bunch length, it must be monitored at every compression stage. This work proposes two novel methods to measure such electron bunches, namely a novel spectral method that analyses the frequency content of electron bunches that becomes easier with shorter bunch length and a transverse deflecting cavity method which can conceptually measure a zero bunch length. Because the SwissFEL was not built at the time of the PhD, all experiments were performed at the SwissFEL Injector Test Facility (SITF). The SITF is a 200 MeV test bed linear electron accelerator. Theoretically the bunch length is limited due to the uncorrelated energy spread and the higher order components of the bunch compressor. However, due to the limited electron energy in combination with the short electron bunches, space charge effects dominate the beam in the transverse phase space as well as in the longitudinal phase space. A transverse deflecting cavity (TDC) measurement was used to measure a reference bunch length to which the spectral fluctuations could be correlated. In a TDC the electric fields are oriented perpendicular to the beam direction and streaks the head and tail in opposite directions onto a screen. In a conventional TDC measurement, the projected beam size onto the temporal axis is the current profile, provided that the intrinsic beam size is small. However, in the SITF the intrinsic beam size was large due to the aforementioned space charge effects. This led to the development of a novel bunch length analysis method in a space charge dominated beam. In the proposed analysis method, a dispersive section in combination with a TDC was used to visualise the longitudinal phase space. The longitudinal phase space was sliced in the momentum domain to reveal the difference between the intrinsic and the streaked beam in a momentum slice. The bunch length could be extracted by recording the times for all slices. Both the simulations and experiments suggest the method enables the measurement of bunch length in a space charge dominated beam in which the transverse intrinsic beam size is large. The measured minimal bunch length from simulations and experiments are of the same order, 19.5 fs to 24.5 fs, respectively. Since the TDC at PSI has a specified resolution of 20 fs at 200 pC, this method may be used to reduce the resolution. The spectral content of femtosecond electron bunches contains electron bunch length information. As an electron beam collides with an optical transition radiation (OTR) foil, radiation is emitted. The radiation is collected by means of a mirror setup into an optical fibre and into an optical spectrometer. The spectral range of the spectrometer is 316 THz (950 nm) to 1364 THz (220 nm). From OTR theory a flat OTR spectrum was expected and measured. As the electron bunch length was reduced below 70 fs, periodic fluctuations started to appear on the spectra. These fluctuations broaden with decreasing bunch length and show a good agreement with the bunch length measured with the TDC.

EPFL2015

A New Concept of Sensor for Ultra-high Levels of Radiation based on Radiation Enhanced Oxidation of Copper Thin-films

Georgi Gorine

The Future Circular Collider (FCC) is the envisioned particle accelerator to be installed in the Geneva area (Switzerland). It could achieve an energy of 100 TeV by colliding proton beams (FCC-hh) travelling through a 100 km tunnel. Unprecedented radiation levels inside the FCC detectors will presumably exceed several tens of MGy with more than 10e17 particles/cm2. Current solid-state dosimetry technologies based on silicon, are not capable of withstanding such radiation, thus requiring a new type of sensor to be used as dosimeter in the future irradiation facilities and, at a later stage, in the accelerator itself. The aim of this thesis is to develop a Radiation Dependent Resistor (RDR) as novel candidate technology for ultra-high radiation monitoring, and to study the radiation effects that are responsible for the measured increase of resistance of the RDR. Following theoretical and experimental selection processes, copper was chosen as the best candidate material as thin film for the active layer of such radiation sensor. Such approach was never attempted before. The RDR was developed via four experimental phases each including: the micro-fabrication at the CMi Center of MicroNanoTechnology (EPFL), the irradiation tests with protons at the IRRAD Proton Facility (CERN) and neutrons at the TRIGA nuclear reactor (Jožef Stefan Institute), and the characterisation at CERN and EPFL. As result, the RDR was fully prototyped with an optimized process flow, a compact chip layout, a radiation hard Printed Circuit Board (PCB), and an online and remote readout system. By analyzing the electrical data and cross-sectional images of the irradiated samples, the conventional theory of high-temperature copper oxidation has proven useful in proposing a new concept of room temperature oxidation which is considerably amplified by radiation (Radiation Enhanced Oxidation). This new interpretation has been implemented in behavioural, analytical and empirical models and validated against experimental data. Through the knowledge gathered in the framework of this thesis, the RDR technology was demonstrated to be compatible with the radiation levels expected in high energy physics experiments such as the HL-LHC and FCC. Additionally, these copper RDR sensors could also be used as dosimeters in particularly radioactive environments such as nuclear and fusion reactors.

EPFL2020