High-gradient and high-efficiency linear accelerators for hadron therapy

Hadron beams - approximately 200 MeV protons and 400 MeV/u fully stripped carbon ions - are better suited to treat deep-seated tumours than X ray beams - produced by electrons accelerated by linear accelerators (linacs) to 5-25 MeV - because they leave the maximum energy density at the end of their range in matter, in the so-called Bragg peak. This physical property allows dose depositions that are more conformal to the tumour target and spare much better the surrounding healthy tissues, so that hadron therapy treatment rooms could substitute X ray therapy rooms (about 20 000 worldwide) if the needed accelerators could be made of similar dimensions and costs. Cyclotrons and synchrotrons are at the heart of today proton and carbon ion therapy centres, respectively. At the end of 2015, more than 130 000 patients have been treated with proton beams and almost 20 000 with carbon ions [Particle Therapy Co-Operative Group data, \url{https://www.ptcog.ch/index.php/patient-statistics}]. High frequency hadron therapy linacs have been studied in the last 30 years. Their main advantage is represented by their active beam energy modulation, which permits quick treatments with superior beam quality and novel dose delivery techniques.

This thesis is the last of many research works on the development of linear accelerators for hadron therapy. The preliminary design of two linear accelerator facilities, for proton therapy (TULIP) and carbon ion therapy (CABOTO), was completed.

The introductory Chapter will review the rationale of hadron therapy as a treatment methodology, together with a discussion of the advantages of linacs in hadron therapy compared to state-of-art technologies. Finally, the most important past research activities based on which this thesis started will be presented.

The second Chapter describes the RF design of accelerating structures performed for the proton and carbon ion therapy facilities later on presented.

The third Chapter is dedicated to the proton linac design, called TULIP: TUrning LInac for Protontherapy.

The forth Chapter describes the carbon ion linac design, called CABOTO: CArbon BOoster for Therapy in Oncology.

The fifth Chapter presents the experimental activity performed on the backward travelling wave prototype built. Goal of the test is to study the high-gradient break-down limitation of S-Band cavities.

The thesis is completed by an Appendix where the beam dynamics codes developed to design the linacs are discussed.

Analysis of a Novel Toroidal Configuration for Hadron Therapy Gantries

Enrico Felcini

Hadron therapy refers to a medical treatment that uses hadron beams (i.e. protons and ions) to deliver localized energy that suppresses cancerous cells, sparing the neighbouring healthy tissues from unwanted radiation. The major technical components of a hadron therapy centre are the particle accelerator (cyclotron, synchrotron, or linac) and the beam delivery system that controls, shapes and orients the particles towards the area to be treated. The beam delivery can consist of fixed transfer lines, or it can include a gantry, a transfer line that rotates around the patient and allows radiation from multiple directions. The present work investigates a new toroidal gantry for hadron therapy, named GaToroid. This novel gantry configuration allows the dose delivery from a discrete number of angles avoiding magnets as well as patient rotation. Compared to traditional gantries that require rotating magnets, this improvement is made possible by a toroidal magnet operating in steady-state. This design constitutes the ideal conditions for the use of superconductors to generate a significantly higher magnetic field compared to normal-conducting solutions, as well as to reduce the weight and footprint of the magnets. The study of a GaToroid system requires the integration of several aspects of physics and engineering. In this framework, the focus of this research is on the design of the superconducting coils integrated with beam optics and particle tracking analyses. The first part of the thesis illustrates the optimization of the toroidal magnet. Coupling two-dimensional particle tracking and magnetic field calculations, an algorithm was developed to identify optimal gantry configurations that maximize the energy acceptance of the system. Two solutions composed of 16 coils, differing in high and low values of engineering current density, were investigated. In line with current clinical requirements, the beams converged at the isocenter within 1 mm over the whole treatment energy spectrum for both configurations. The second part of the thesis describes the algorithm implemented for the two- and three-dimensional particle tracking. Building upon the results of the magnetic optimization, a linear beam optics formalism was developed to determine the focusing properties of GaToroid. The third part of the thesis focuses on the engineering design of the low current density solution. Using two thermo-electric models, lumped and one-dimensional, the Nb-Ti and ReBCO cable geometries were validated, together with the quench protection system. Furthermore, analytical and numerical studies on mechanics made it possible to estimate the overall footprint and weight of the system. Results show that, compared with the state-of-the-art gantries, the proposed GaToroid solution has the potential to be more compact and lighter by at least a factor two. Finally, the last part of the thesis describes the design of a scaled-down demonstrator wound with ReBCO tapes. Studies on quench protection, mechanics and experimental implementation aimed at testing the use of ReBCO technology for GaToroid coils are discussed. In conclusion, this work presents the first overall description of a GaToroid system, ranging from the analytical definition, magnetic optimization, particle tracking and magnet engineering. The investigation of this new toroidal paradigm for gantries represents a quantum step toward more compact and less expensive solutions for hadron therapy centres.

EPFL2021

Direct search for Higgs boson in LHCb and contribution to the development of the vertex detector

Laurent Locatelli

The LHCb experiment (Large Hadron Collider beauty) is one of the four experiments under construction at the LHC (Large Hadron Collider) at CERN near Geneva. It is planned to start in 2007 and its goal is the study of b-quark physics. The LHC is a circular accelerator in which collide protons-protons at a center-of-mass energy of √s = 14 TeV. This generates a large number of high energy bb pairs which are predominantly produced in the same forward cone. The LHCb detector is therefore a forward single arm spectrometer designed to exploit the large bb production cross section (σbb ~ 500 μb) and to perform precise measurements of CP violation in b-hadrons decays. One of the actual greatest challenges in High Energy Physics is the discovery of the Higgs boson which is responsible for the Model Standard particles mass generation through the Spontaneous Symmetry Breaking process. The Higgs mass is not known and cannot be predicted by the theory. However the recent results of LEP at CERN have shown that mH0 > 114 GeV/c2. Below ~ 150 GeV/c2 the Higgs decay into two b-quarks H0 → bb dominates. The two quarks emitted back-to-back in the H0 rest frame form a string which fragments, giving rise to hadronization in jets containing b-hadrons. The aim of this thesis is to assess the feasibility to discover a Higgs boson with intermediate mass at LHCb by using the detector sensibility to b-hadrons in order to reconstruct these jets using jets reconstruction algorithms. The study is focused on the mechanisms in which the Higgs boson is produced in association with a gauge boson decaying leptonically H0 + W± → bb + ℓνℓ and H0 + Z0 → bb + ℓ+ℓ- for Higgs masses in the range 100 - 130 GeV/c2. The gauge bosons decay produces hard leptons quite often isolated from the b-jets. Hence an isolated lepton with high transverse momentum is required in order to reject the large QCD background. Several important background channels which also provide two b-quarks and an isolated lepton – like tt → W+b W-b, Z0 + W± → bb + ℓνℓ, Z0 + Z0 → bb + ℓ+ℓ-, W± + b-jets, Z0 + b-jets and generic bb – are studied in parallel. The idea is to find observables which behave differently for backgrounds and Higgs signal and to exploit these differences in the framework of a neural network, precisely in order to discriminate background from signal. The LHCb experiment needs a high capability to identify b-hadrons despite their very short lifetime τB ~ 1.5 · 10-12 s. The Vertex Locator (VeLo) is a sub-detector placed around the p-p interaction point which has to provide accurate measurements of the b-hadrons production and decay points by reconstructing secondary vertices. The second part of this thesis is a technical contribution to the development of the VeLo analogue transmission line. It consists in testing several hardware and software methods to improve the VeLo analogue transmission between the on-detector part of the readout and the off-detector electronics. Because the ~ 60 m line introduces an important attenuation, several cables and line drivers configurations with frequency and gain compensation are studied in order to obtain the best results in terms of signal-to-noise ratio and channel crosstalk. The different contributions to the noise are also studied and an estimation of the contribution due to the Beetle pipeline non-uniformity is given in order to see if a specific correction is needed or if it can be suppressed by a standard common noise correction procedure.

EPFL2007

Cyclinac medical accelerators using pulsed C6+/H + 2 ion sources

Alberto Degiovanni, Adriano Garonna

Charged particle therapy, or so-called hadrontherapy, is developing very rapidly. There is large pressure on the scientific community to deliver dedicated accelerators, providing the best possible treatment modalities at the lowest cost. In this context, the Italian research Foundation TERA is developing fast-cycling accelerators, dubbed 'cyclinacs'. These are a combination of a cyclotron (accelerating ions to a fixed initial energy) followed by a high gradient linac boosting the ions energy up to the maximum needed for medical therapy. The linac is powered by many independently controlled klystrons to vary the beam energy from one pulse to the next. This accelerator is best suited to treat moving organs with a 4D multipainting spot scanning technique. A dual proton/carbon ion cyclinac is here presented. It consists of an Electron Beam Ion Source, a superconducting isochronous cyclotron and a high-gradient linac. All these machines are pulsed at high repetition rate (100-400 Hz). The source should deliver both C6+ and H+ 2 ions in short pulses (1.5 μs flat-top) and with sufficient intensity (at least 10 8 fully stripped carbon ions per pulse at 300 Hz). The cyclotron accelerates the ions to 120 MeV/u. It features a compact design (with superconducting coils) and a low power consumption. The linac has a novel C-band high-gradient structure and accelerates the ions to variable energies up to 400 MeV/u. High RF frequencies lead to power consumptions which are much lower than the ones of synchrotrons for the same ion extraction energy. This work is part of a collaboration with the CLIC group, which is working at CERN on high-gradient electron-positron colliders. © 2010 IOP Publishing Ltd and SISSA.