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Study of the shape of b spectra Development of a Si spectrometer for measurement of b spectra . Charlène Bisch. Introduction Beta detectors Experimental device Monte Carlo calculations Conclusion and perspectives .
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Study of the shape of b spectra Development of a Si spectrometer for measurement of b spectra Charlène Bisch • Introduction • Beta detectors • Experimental device • Monte Carlo calculations • Conclusion and perspectives LNHB/CDF : M.-M. Bé, C. Bisch, C. Dulieu, M. A. Kellett, X. Mougeot In collaboration with IPHC, Ramses, Strasbourg (A.-M. Nourreddine)
Beta spectra shapes evaluation Experiments are necessary : validation of the calculations, uncertainties of the models Calculations are necessary : very short T1/2, multiple beta decays, cascades, … Subtle understanding of the phenomena that distorting beta spectra Understand the theory to make it evolve Growth of computing power more complex models Growth of computing power Monte-Carlo simulations Test and constrain calculations with perfectly controlled experiments Introduction • Users : Nuclear Power Industry (decay heat calculations), medical care sector (dose calculations), ionizing radiation metrology (liquid scintillation and ionization chamber techniques)
Measurements – metallic magnetic calorimeters Dilution cooler • Very promising technique: • Detection efficiency > 99,9 % • Energy threshold of about 200 eV • Energy resolution of 30 eV @ 6 keV • Non-linearity of 0,1 % in 6 – 80 keV • But: • Activity ≤ 15 Bq • Measurements at 10 mK • cooling timeof about 3 days • Bremsstrahlung from 800 keV • deacrease of efficiency • Quality of the source • distortion of the spectrum? Detectors floors
Measurements – Silicon detector • More classical technique: • Good energy resolution of 8 keV @ 100 keV (300 K) • Linear response • Easy to implement • But: • Dead zones • Bremsstrahlung • Backscattering • High quality of vacuum • Detector thickness Si(Li) PIPS • Our detector specifications: • PIPS: Passivated Implanted Planar Silicon Detector • Window thickness (Si eq.): < 50 nm • Active diameter: 23,9 mm • Active thickness: 500 µm
Experimental aspects • Experimental spectra may be distorted by the detection system • Experimental aspects to limit sources of distortion • - Detector cooled to liquid nitrogen temperature thermal noise • - Ultra high vacuum interactions e-/environment and dead layer due to water steam condensation • - Reduction of vibrations microphonics (additional component to electronic noise) • Distance from source to detector and centring of the source • solid angle, reproducibility, simulations • - Source: ultra-thin reduction of auto-absorption • quality minimisation of impurities • homogeneous reproducibility, simulations • Any remaining factors will be quantified by Monte-Carlo simulations
Experimental device - General Detection chamber “The Cube” with the PIPS detector Gate valve PUMP GAUGE Linear feed-through 17 cm 100 cm
Experimental device - The source holder Source holder Source support POMPE DEWAR JAUGE Vanne à vide Screen Influence of X-rays Canne de translation
Experimental device - The detection chamber ElectricalBNC/microdot connector An electrical wire connects the detector to the BNC/microdot connector to avoid thermal transfer Detector holder in copper detector cooled uniformly
Monte Carlo simulations • Utilisation of GEANT4 to optimise the source holder and the detection chamber • Influence of the source-detector distance • Geometry and materials least likely to scatter electrons • Code validation: Theory MC Monte Carlo simulations VS Counts S-D distance (mm)
Influence of the source-detector distance • Four source – detector distances : 10 mm, 20 mm, 30 mm, 40 mm • 106 particles emitted from 90Y (MetroMRT project) isotropic source • Thickness of active volume: 500 µm 90 Y PIPS 500 µm 10 mm 30 mm 24 mm 20 mm 40 mm Huge influence of the solid angle Detector thickness too small
Influence of the thickness of active volume • Source – detector distance: 10 mm • 106 particles emitted from 90 Y isotropic source • Four thicknesses of active volume (500 µm, 2 mm, 5 mm, 8 mm) 8 mm 90 Y 5 mm 2 mm 500 µm 10 mm 5 mm thickness active volume is necessary for measuring 90 Y spectra
Geometry and materials of the cube Source – detector distance: 40 mm Source – detector distance: 10 mm No cube Steel cube 250 mm Steel cube 170 mm Aluminium cube 170 mm 170 mm 170 mm 250 mm 250 mm
Sources of distortion • Four main sources of distortion: • - Solid angle source – detector distance • - Detector thickness effect depth of active volume • - Geometry effect geometry of active volume • - Scattering and backscattering energy, Z of the material, incidence angle Geometry effect
Conclusion and perspectives • Development phase of experimental device is complete • The experimental setup is currently being assembled • We intend to do our first measurements of beta spectra early 2013
Theory • Beta decay: the electron and the antineutrino • share the momentum and energy of the decay • continuous kinetic energy spectra 85Kr • Fermi (1933): Probability Energy