Validation of a model for radon-induced background processes in electrostatic spectrometers

Wandkowsky, N.; Drexlin, G.; Fränkle, F. M.; Glück, F.; Groh, Stefan; Mertens, S.

doi:10.1088/0954-3899/40/8/085102

Cited by 18 publications

(45 citation statements)

References 53 publications

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“…The secondary low-energy electrons produced in this process, can leave the trap, being counted by the detector as background events. Thus, a single radon decay, which can produce primary electrons from a few eV up to 200 keV, can lead to an elevated background rate for a limited time interval, until the energy of the primary electron is spent [5]. The length of the time interval depends on the pressure and the energy of the primary electron.…”

Section: The Katrin Main Spectrometermentioning

confidence: 99%

Simulation and measurement of the suppression of radon induced background in the KATRIN experiment

Wolf

Harms

2018

AIP Conference Proceedings

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Abstract. Short-lived radon isotopes, such as 219 Rn or 220 Rn, are a serious source of background for the measurement of the neutrino mass with the KATRIN experiment. Most of the radon emanates from the main vacuum pumps of the KATRIN Main Spectrometer, which consist of 2000 m of Non-Evaporable Getter (NEG) strips. This paper describes a method to suppress the radon rate with liquid-nitrogen-cooled baffles in front of the NEG-pumps in the ultra-high vacuum chamber and compares simulations with measured data. The effectiveness of the method depends both on the half-life of the radon isotopes, and on the temperature of the cryogenic baffles, which affects their sojourn time on the cold surface. The measurements with the Main Spectrometer showed that the radon suppression with cold baffles works sufficiently well, so that the remaining background is no longer dominated by radon decays.

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Section: The Katrin Main Spectrometermentioning

confidence: 99%

Simulation and measurement of the suppression of radon induced background in the KATRIN experiment

Wolf

Harms

2018

AIP Conference Proceedings

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“…A measurement with a cooled baffle system results in a background level equivalent to the one without radon induced events (blue squares). studied already in great detail in [20,21,22,23]. With test experiments at the prespectrometer it was shown that a single radon decay in the sensitive volume of the spectrometer can lead to very high background rates.…”

Section: Background Performancementioning

confidence: 99%

Status of the KATRIN Experiment and Prospects to Search for keV-mass Sterile Neutrinos in Tritium β-decay

Mertens

2015

Physics Procedia

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In this contribution the current status and future perspectives of the Karlsruhe Tritium Neutrino (KATRIN) Experiment are presented. The prime goal of this single β-decay experiment is to probe the absolute neutrino mass scale with a sensitivity of 200 meV (90% CL). We discuss first results of the recent main spectrometer commissioning measurements, successfully verifying the spectrometer's basic vacuum, transmission and background properties. We also discuss the prospects of making use of the KATRIN tritium source, to search for sterile neutrinos in the multi-keV mass range constituting a classical candidate for Warm Dark Matter. Due to the very high source luminosity, a statistical sensitivity down to active-sterile mixing angles of sin 2 θ < 1 · 10 −7 (90% CL) could be reached.

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“…Our model allows for consecutive IC processes in case the initial de-excitation process does not result in a ground state configuration of the polonium daughter. We also include the rare IC process of the decay 220 Rn → 216 Po * [19], but its contribution is negligible for the investigations in [9,10]. As mentioned above, the emission Table 2.…”

Section: Internal Conversionmentioning

confidence: 99%

“…To study the event topologies of electrons from the α-decay of 219,220 Rn atoms, and to estimate background rates and characteristics due to their subsequent trapping (for details, see [9,10]), a detailed code for particle trajectory calculations in the complex electromagnetic field configuration of the KATRIN spectrometer is required. This challenging task is met by the KATRIN simulation package Kassiopeia [32], which was validated by a variety of different measurements [10,12,13,33]. A Monte Carlo event generator was developed to model electron emission following 219,220 Rn α-decay and is described in section 3.1.…”

Section: Implementation Into the Simulation Softwarementioning

confidence: 99%

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Modeling of electron emission processes accompanying radon-α-decays within electrostatic spectrometers

Wandkowsky¹,

Drexlin²,

Fränkle³

et al. 2013

New J. Phys.

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Electrostatic spectrometers utilized in high-resolution βspectroscopy studies such as in the Karlsruhe Tritium Neutrino (KATRIN) experiment have to operate with a background level of less than 10 −2 counts per second. This limit can be exceeded by even a small number of 219,220 Rn atoms being emanated into the volume and undergoing α-decay there. In this paper we present a detailed model of the underlying background-generating processes via electron emission by internal conversion, shake-off and relaxation processes in the atomic shells of the 215,216 Po daughters. The model yields electron energy spectra up to 400 keV and electron multiplicities of up to 20 which are compared to experimental data.

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Validation of a model for radon-induced background processes in electrostatic spectrometers

Cited by 18 publications

References 53 publications

Simulation and measurement of the suppression of radon induced background in the KATRIN experiment

Simulation and measurement of the suppression of radon induced background in the KATRIN experiment

Status of the KATRIN Experiment and Prospects to Search for keV-mass Sterile Neutrinos in Tritium β-decay

Modeling of electron emission processes accompanying radon-α-decays within electrostatic spectrometers

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