Experimental Study of the $w$-Values and Fano Factors of Gaseous Xenon and Ar-Xe Mixtures for X-Rays

Carmo, S.J.C. do; Borges, Fernandes; Vinagre, F.L.R.; Conde, C.A.N.

doi:10.1109/tns.2008.2003075

Cited by 25 publications

(24 citation statements)

References 37 publications

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“…Additionally energy resolutions σ E /E of down to 3.85 % at 5.9 keV could be achieved at optimized settings in a gas mixture of Argon and isobutane with 10 % quencher fraction and energy determination by simple pixel (or electron) counting. This value, however, is already close to the lower limit of roughly 3 % given by the Fano factor [17]. The corresponding spectrum is shown in figure 4c, again the number of fired-pixels is taken as measure of the photon energy.…”

Section: An Ingrid Based Low Energy X-ray Detector For the Cast Expersupporting

confidence: 61%

An InGrid based Low Energy X-ray Detector for the CAST Experiment

Krieger¹,

Desch²,

Kamiński³

et al. 2015

Proceedings of Technology and Instrumentation in Particle Physics 2014 — PoS(TIPP2014)

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The CERN Axion Solar Telescope (CAST) is searching for axions and other new particles like chameleons coupling to photons and emerging from the Sun. Those particles are converted into soft X-ray photons in a high magnetic field. To enhance sensitivity for physics beyond the Standard Model it is necessary to cope with weak couplings and low energies, thus requiring an efficient background discrimination as well as a detection threshold below 1 keV. A promising candidate for a future CAST detector is an InGrid based X-ray detector. This detector combines the high spatial resolution of a pixelized readout with a highly granular Micromegas gas amplification stage. Fabrication by photolithographic postprocessing techniques allows to match the amplification grid to the pixels. The high granularity facilitates the detection of single electrons which allows to determine the X-ray energy by electron counting. Additionally, rejection of background events mostly originating from cosmic rays is provided by an event shape analysis exploiting the high spatial resolution. In order to demonstrate its low detection threshold, an InGrid based detector was tested in the CAST Detector Lab where an X-ray generator for energies down to a few hundred eV is available.Results of these tests demonstrate the detector's ability to detect the carbon K-alpha line at 277 eV. The detector was mounted afterwards at the CAST experiment behind an X-ray telescope in order to take data during the 2014 run of CAST.

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Section: An Ingrid Based Low Energy X-ray Detector For the Cast Expersupporting

confidence: 61%

An InGrid based Low Energy X-ray Detector for the CAST Experiment

Krieger¹,

Desch²,

Kamiński³

et al. 2015

Proceedings of Technology and Instrumentation in Particle Physics 2014 — PoS(TIPP2014)

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“…Another parameter, the gas multiplication factor, , that characterizes gas avalanche detectors, can be also estimated from a comparison of pulse-height spectral peaks generated by a 5.9 keV X-ray source and a charge calibrator: (2) where is a 2 pF calibrated capacitor, is the amplitude of the test pulse from the pulse generator, is the average energy required to produce an electron-ion pair in the gas, is the electron charge and and are the channel numbers, in the multichannel analyzer, for the test pulse and for the X-ray (with energy ) charge pulse collected at the anode, respectively. Although the -values for pure Xe and Ar and their mixtures can be found in the literature [17] this is not true for the case of P10-Xe mixtures. In these cases, instead of the gas multiplication factor , we used pulse amplitudes to characterize the gas gain of each studied mixture as will be described in Sections IV and V. Pulse amplitudes are proportional to the position of the centroid of the gaussian fitted to spectrum main peak, , i.e.…”

Section: Description Of the Detector And Experimental Setupmentioning

confidence: 96%

Quenched and Non-Quenched Ar-Xe Penning Mixtures as Detection Media for a Gridded-Microstrip Gas Chamber X-Ray Detector

Carita

Conde

Santos

2009

IEEE Trans. Nucl. Sci.

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The performance of quenched and non-quenched argon-xenon Penning mixtures in a Gridded-Microstrip Gas Chamber is studied for 5.9 keV X-rays. The best energy resolution obtained was 12.5% for the 95%Ar-5%Xe mixture. Charge multiplication gains one order of magnitude higher than in pure xenon were obtained for 95%Ar-5%Xe. With the addition of the quenching agent (methane), although the gas gain at the same anode voltage decreases, a better energy resolution of 12.3% is achieved for the 85.5%Ar-5%Xe-9.5%CH4 mixture.Index Terms-Argon-xenon and P10-xenon gas mixtures, microstrip plate, Penning mixtures, x-ray gaseous detector.

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“…2 = intrinsic limit, which is 0.6 % for 662 keV in Xe assuming a Fano factor F=0.25 and w=21.6 eV [10].…”

Section: Principle Of Operationmentioning

confidence: 99%

“…This detector consist of a high pressure Xe filled cylinder at ground potential with 4 circular grids parallel to each other and to a CsI film (about 500 nm thick), vacuum evaporated in the lower and inner surface of the detector. The ionizing radiation is absorbed, mainly by photoelectric and Compton processes, in the 5 to 20 cm long HPXe drift region (at a pressure p in the 5-20 atm range), where the electric field is below the 1 V.cm -1 .Torr -1 threshold for secondary scintillation, and produces n primary electrons (n §30,000 electrons for a 662 keV γ-photon) [10].…”

Section: Principle Of Operationmentioning

confidence: 99%

A new technique for gaseous gamma ray detectors: The multigrid high pressure xenon gas proportional scintillation counter

Borges

Carmo

Mariquito

et al. 2009

2009 IEEE Nuclear Science Symposium Conference Record (NSS/MIC)

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A new technique is presented for high pressure gaseous radiation detectors leading to pulse amplitudes about one order of magnitude larger than ionization chamber based gamma ray detectors. The technique uses room temperature Xe based gaseous mixtures at pressures of about 5 to 20 atm (or higher) to detect ionizing radiation in a multigrid high pressure gas proportional scintillation counter (MGHP-GPSC) with a CsI deposit as the photocathode and no optical windows. The detector relies on secondary scintillation for the charge amplification stage rather than on charge avalanche multiplication as in proportional counters. Experimental results are presented for a small prototype filled with pure Xe up to 5 atm showing that the principle of operation of the detector works. The detector maximum gain obtained in the first results is about 10.

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Experimental Study of the $w$-Values and Fano Factors of Gaseous Xenon and Ar-Xe Mixtures for X-Rays

Cited by 25 publications

References 37 publications

An InGrid based Low Energy X-ray Detector for the CAST Experiment

An InGrid based Low Energy X-ray Detector for the CAST Experiment

Quenched and Non-Quenched Ar-Xe Penning Mixtures as Detection Media for a Gridded-Microstrip Gas Chamber X-Ray Detector

A new technique for gaseous gamma ray detectors: The multigrid high pressure xenon gas proportional scintillation counter

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