717 research outputs found
The ATLAS muon trigger detector in the barrel: performance simulation and cosmic ray tests
Il Large Hadron Collider (LHC) è l’acceleratore per collisioni di ioni e protoni attualmente in costruzione al CERN di Ginevra. Questa macchina permetterà di raggiungere un’elevata energia nel centro di massa (14 TeV per collisioni protone-protone), dando la possibilità di produrre particelle con masse fino all’ordine del TeV. ATLAS è uno degli esperimenti di LHC.
Una delle principali caratteristiche del rivelatore di ATLAS è di avere uno spettrometro per muoni in aria, che opera come un rivelatore a sé stante. Nel barrel il trigger di primo livello dei muoni è fornito dalle camere RPC (Resistive Plate Chambers): rivelatori a gas in grado di fornire una risposta veloce con un’eccellente risoluzione temporale (σt ≤1.5 ns).
In questa tesi sono presentati i risultati del primo test di funzionamento di un intero settore del rivelatore a muoni, svoltosi al test-beam H8 del CERN. Particolare attenzione è data allo studio sistematico della “cluster size” delle camere RPC (il numero di strisce contigue accese, che sono associate ad uno stesso segnale nel rivelatore). Questo studio ha mostrato come la “cluster size” osservata, lungi dall’essere casuale, dipenda in modo sistematico dal punto di impatto della particella sul piano di strisce di lettura.
Viene inoltre descritto il test sistematico, mediante raggi cosmici, di 192 camere RPC di produzione (tipo BOL), che è stato allestito presso il laboratorio INFN di Roma Tor Vergata. Questo lavoro, che ha richiesto una corposa acquisizione dati, ha fornito la necessaria base statistica per uno studio accurato della rate di rumore e delle correnti di gap, dimostrando uno standard di qualità nella produzione seriale molto superiore a quello dei prototipi. L’ampia mole di dati acquisiti fornisce inoltre l’informazione necessaria per progredire nella comprensione della fisica del rivelatore.
Successivamente viene presentata una simulazione Monte Carlo (in GEANT4) della logica di trigger di livello-1 con muoni cosmici, orientata a studiare le possibili configurazioni del trigger così da massimizzare la rate con i raggi cosmici durante la fase di “commissioning” del rivelatore. E’ stata inoltre prodotta una simulazione limitata a sei torri del trigger, al fine di verificare l’accordo dei risultati ottenuti con le rate misurate durante il primo test di “commissioning” nella caverna di ATLAS, permettendo così per la prima volta di validare il programma di simulazione.
Infine viene presentata l’analisi dei dati prodotti durante il test in caverna delle prime tre torri assemblate dello spettrometro a muoni.The Large Hadron Collider (LHC) is the machine for proton and ion collisions in construction at CERN of Geneva. It will provide a very high energy in the center of mass, reaching the value of 14 TeV for proton-proton collisions, and giving the possibility to produce particles with mass up to few TeV. ATLAS is one of the LHC experiments.
The ATLAS detector is characterized by its stand-alone Muon Spectrometer, based on an air-core toroid system, which generates a large field volume and a strong bending power with a light and open structure. In the barrel the ATLAS first level muon trigger relies on the Resistive Plate Chambers (RPC): these are gas ionization detectors which are characterized by a fast response and an excellent time resolution (σt ≤1.5 ns).
A good understanding of the detector physics and a complete control of the performance are essential. For this purpose, a cosmic muon test stand has been built in the INFN Roma Tor Vergata Laboratory and a systematic test of the 192 biggest ATLAS RPCs was carried out. It consisted of a preliminary check of the detector status (gas-tightness and test of the electric circuits), and a characterization of every chamber: in particular the noise rate, the cluster size, the detection efficiency and the gap current have been studied for each detector.
Moreover at H8 beam site at CERN, an ATLAS-like detector slice was assembled and tested with particle beams. The presence in the test of the tracking chambers (MDT), combined with the RPCs, allowed to the author an independent study of the RPC performances, exploiting the information extracted from the muon tracks reconstructed by the precision chambers.
The assembly of the ATLAS detector in the cavern has already started and will be completed in almost one year. Then a phase of detector calibration and test will precede the beginning of the experiment, using the RPCs as trigger of cosmic rays. To optimize the selection of the cosmic muons, the author studied dedicated first level muon trigger configurations, using a Monte Carlo simulation (based on GEANT4).
Although the ATLAS detector installation in the cavern is still undergoing, some subdetectors are already operative: three muon stations of the lowest sector are ready and working. This allowed to validate the trigger simulation and furthermore to start the muon station debugging
Use of bremsstrahlung radiation to identify hidden weak beta- sources: feasibility and possible use in radio-guided surgery
The recent interest in beta- radionuclides for radio-guided surgery derives
from the feature of the beta radiation to release energy in few millimeters of
tissue. Such feature can be used to locate residual tumors with a probe located
in its immediate vicinity, determining the resection margins with an accuracy
of millimeters. The drawback of this technique is that it does not allow to
identify tumors hidden in more than few mm of tissue. Conversely, the
bremsstrahlung X-rays emitted by the interaction of the beta- radiation with
the nuclei of the tissue are relatively penetrating. To complement the beta-
probes, we have therefore developed a detector based on cadmium telluride, an
X-ray detector with a high quantum efficiency working at room temperature. We
measured the secondary emission of bremsstrahlung photons in a target of
Polymethylmethacrylate (PMMA) with a density similar to living tissue. The
results show that this device allows to detect a 1 ml residual or lymph-node
with an activity of 1 kBq hidden under a layer of 10 mm of PMMA with a 3:1
signal to noise, i.e. with a five sigma discrimination in less than 5 s
Scintillating fiber devices for particle therapy applications
Particle Therapy (PT) is a radiation therapy technique in which solid tumors are treated with charged ions and exploits the achievable highly localized dose delivery, allowing to spare healthy tissues and organs at risk. The development of a range monitoring technique to be used on-line, during the treatment, capable to reach millimetric precision is considered one of the important steps towards an optimization of the PT efficacy and of the treatment quality. To this aim, charged secondary particles produced in the nuclear interactions between the beam particles and the patient tissues can be exploited. Besides charged secondaries, also neutrons are produced in nuclear interactions. The secondary neutron component might cause an undesired and not negligible dose deposition far away from the tumor region, enhancing the risk of secondary malignant neoplasms that can develop even years after the treatment. An accurate neutron characterization (flux, energy and emission profile) is hence needed for a better evaluation of long-term complications. In this contribution two tracker detectors, both based on scintillating fibers, are presented. The first one, named Dose Profiler (DP), is planned to be used as a beam range monitor in PT treatments with heavy ion beams, exploiting the charged secondary fragments production. The DP is currently under development within the INSIDE (Innovative Solutions for In-beam DosimEtry in hadrontherapy) project. The second one is dedicated to the measurement of the fast and ultrafast neutron component produced in PT treatments, in the framework of the MONDO (MOnitor for Neutron Dose in hadrOntherapy) project. Results of the first calibration tests performed at the Trento Protontherapy center and at CNAO (Italy) are reported, as well as simulation studies
In-room test results at CNAO of an innovative PT treatments online monitor (Dose Profiler)
The use of C, He and O ions as projectiles in Particle Therapy (PT) treatments is getting more and more widespread as a consequence of their enhanced relative biological effectiveness and oxygen enhancement ratio, when compared to the protons one. The advantages related to the incoming radiation improved efficacy are requiring an accurate online monitor of the dose release spatial distribution. Such monitor is necessary to prevent unwanted damage to the tissues surrounding the tumour that can arise, for example, due to morphological changes occurred in the patient during the treatment with respect to the initial CT scan. PT treatments with ions can be monitored by detecting the secondary radiation produced by the primary beam interactions with the patient body along the path towards the target volume. Charged fragments produced in the nuclear process of projectile fragmentation can be emitted at large angles with respect to the incoming beam direction and can be detected with high efficiency in a nearly background-free environment. The Dose Profiler (DP) detector, developed within the INSIDE project, is a scintillating fibre tracker that allows an online reconstruction and backtracking of such secondary charged fragments. The construction and preliminary in-room tests performed on the DP, carried out using the 12C ions beam of the CNAO treatment centre using an anthropomorphic phantom as a target, will be reviewed in this contribution. The impact of the secondary fragments interactions with the patient body will be discussed in view of a clinical application. Furthermore, the results implications for a pre-clinical trial on CNAO patients, foreseen in 2019, will be discussed
Extended calibration range for prompt photon emission in ion beam irradiation
Monitoring the dose delivered during proton and carbon ion therapy is still a
matter of research. Among the possible solutions, several exploit the
measurement of the single photon emission from nuclear decays induced by the
irradiation. To fully characterize such emission the detectors need
development, since the energy spectrum spans the range above the MeV that is
not traditionally used in medical applications. On the other hand, a deeper
understanding of the reactions involving gamma production is needed in order to
improve the physic models of Monte Carlo codes, relevant for an accurate
prediction of the prompt-gamma energy spectrum.This paper describes a
calibration technique tailored for the range of energy of interest and
reanalyzes the data of the interaction of a 80MeV/u fully stripped carbon ion
beam with a Poly-methyl methacrylate target. By adopting the FLUKA simulation
with the appropriate calibration and resolution a significant improvement in
the agreement between data and simulation is reported.Comment: 4 pages, 7 figures, Submitted to JINS
First Ex-Vivo Validation of a Radioguided Surgery Technique with beta- Radiation
Purpose: A radio-guided surgery technique with beta- -emitting radio-tracers
was suggested to overcome the effect of the large penetration of gamma
radiation. The feasibility studies in the case of brain tumors and abdominal
neuro-endocrine tumors were based on simulations starting from PET images with
several underlying assumptions. This paper reports, as proof-of-principle of
this technique, an ex-vivo test on a meningioma patient. This test allowed to
validate the whole chain, from the evaluation of the SUV of the tumor, to the
assumptions on the bio-distribution and the signal detection.
Methods: A patient affected by meningioma was administered 300 MBq of
90Y-DOTATOC. Several samples extracted from the meningioma and the nearby Dura
Mater were analyzed with a beta- probe designed specifically for this
radio-guided surgery technique. The observed signals were compared both with
the evaluation from the histology and with the Monte Carlo simulation.
Results: we obtained a large signal on the bulk tumor (105 cps) and a
significant signal on residuals of 0.2 ml (28 cps). We also show that
simulations predict correctly the observed yields and this allows us to
estimate that the healthy tissues would return negligible signals (~1 cps).
This test also demonstrated that the exposure of the medical staff is
negligible and that among the biological wastes only urine has a significant
activity.
Conclusions: This proof-of-principle test on a patient assessed that the
technique is feasible with negligible background to medical personnel and
confirmed that the expectations obtained with Monte Carlo simulations starting
from diagnostic PET images are correct.Comment: 17 pages, 4 Figs, Accepted by Physica Medic
Measurement of secondary particle production induced by particle therapy ion beams impinging on a PMMA target
Particle therapy is a technique that uses accelerated charged ions for cancer treatment and combines a high irradiation precision with a high biological effectiveness in killing tumor cells [1]. Informations about the secondary particles emitted in the interaction of an ion beam with the patient during a treatment can be of great interest in order to monitor the dose deposition. For this purpose an experiment at the HIT (Heidelberg Ion-Beam Therapy Center) beam facility has been performed in order to measure fluxes and emission profiles of secondary particles produced in the interaction of therapeutic beams with a PMMA target. In this contribution some preliminary results about the emission profiles and the energy spectra of the detected secondaries will be presente
Towards a Radio-guided Surgery with Decays: Uptake of a somatostatin analogue (DOTATOC) in Meningioma and High Grade Glioma
A novel radio guided surgery (RGS) technique for cerebral tumors using
radiation is being developed. Checking the availability of a
radio-tracer that can deliver a emitter to the tumor is a
fundamental step in the deployment of such technique. This paper reports a
study of the uptake of 90Y labeled (DOTATOC) in the meningioma and the high
grade glioma (HGG) and a feasibility study of the RGS technique in these cases.Comment: 21 pages, 5 figure
Measurement of charged particle yields from therapeutic beams in view of the design of an innovative hadrontherapy dose monitor
Particle Therapy (PT) is an emerging technique, which makes use of charged particles to efficiently cure different kinds of solid tumors. The high precision in the hadrons dose deposition requires an accurate monitoring to prevent the risk of under-dosage of the cancer region or of over-dosage of healthy tissues. Monitoring techniques are currently being developed and are based on the detection of particles produced by the beam interaction into the target, in particular: charged particles, result of target and/or projectile fragmentation, prompt photons coming from nucleus de-excitation and back-to-back γ s, produced in the positron annihilation from β + emitters created in the beam interaction with the target. It has been showed that the hadron beam dose release peak can be spatially correlated with the emission pattern of these secondary particles. Here we report about secondary particles production (charged fragments and prompt γ s) performed at different beam and energies that have a particular relevance for PT applications: 12C beam of 80 MeV/u at LNS, 12C beam 220 MeV/u at GSI, and 12C, 4He, 16O beams with energy in the 50–300 MeV/u range at HIT. Finally, a project for a multimodal dose-monitor device exploiting the prompt photons and charged particles emission will be presented
Characterization of a detector for β− radio-guided surgery
This paper reports a new device for the radio-guided surgery technique exploiting β− emitters. A specific intraoperative β− detecting probe based on a low-density organic crystal, the diphenylbutadiene-doped para-therphenyl, coupled by optical fibres to a photomultiplier, was developed. A portable readout electronics was designed to provide the surgeons with multi real-time feedback. The
aspects related to the applicability of the device, in particular the perception of the spatial resolution of the probe and the comprehension time necessary to the operator
to interpret the system response were investigated. Preliminary promising results support the possibility of using this innovative probe in cancer surgery
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