N. J. Spinks scite author profile

The direct detection of dark matter is a key problem in astroparticle physics that generally requires the use of deep-underground laboratories for a low-background environment where the rare signals from dark matter interactions can be observed. This work reports on the Stawell Underground Physics Laboratory – currently under construction and the first such laboratory in the Southern Hemisphere – and the associated research program. A particular focus will be given to ANU’s contribution to SABRE, a NaI:Tl dark matter, direct detection experiment that aims to confirm or refute the long-standing DAMA result. Preliminary measurements of the NaI:Tl quenching factor and characterisation of the SABRE liquid scintillator veto are reported.

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Quenching factor measurements of sodium nuclear recoils in NaI:Tl determined by spectrum fitting

Bignell

Mahmood

Nuti

et al. 2021

J. Inst.

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We have performed measurements of sodium nuclear recoils in NaI:Tl crystals, following scattering by neutrons produced in a 7Li(p,n)7Be reaction. Understanding the light output from such recoils, which is reduced relative to electrons of equivalent energy by the quenching factor, is critical to interpret dark matter experiments that search for nuclear scattering interactions. We have developed a spectrum-fitting methodology to extract the quenching factor from our measurements, and report quenching factors for nuclear recoil energies between 36 and 401 keV. Our results agree with other recent quenching factor measurements that use quasi-monoenergetic neutron sources. The new method will be applied in the future to the NaI:Tl crystals used in the SABRE experiment.

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Pulse Shape Discrimination of low-energy nuclear and electron recoils for improved particle identification in NaI:Tl

Spinks

Bignell²,

Lane³

et al. 2023

Nuclear Instruments and Methods in Physics Research Section A:

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Emerging collectivity in neutron-hole transitions near doubly magic 208Pb

et al. 2021

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N. J. Spinks

Evidence for shape coexistence and superdeformation in 24Mg

SABRE and the Stawell Underground Physics Laboratory Dark Matter Research at the Australian National University

Quenching factor measurements of sodium nuclear recoils in NaI:Tl determined by spectrum fitting

Pulse Shape Discrimination of low-energy nuclear and electron recoils for improved particle identification in NaI:Tl

Emerging collectivity in neutron-hole transitions near doubly magic 208Pb

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