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1. Low-energy calibration of XENON1T with an internal $$^{{\textbf {37}}}$$Ar source

   https://doi.org/10.1140/epjc/s10052-023-11512-z  

   Aprile, E. ; Abe, K. ; Agostini, F. ; Ahmed Maouloud, S. ; Alfonsi, M. ; Althueser, L. ; Andrieu, B. ; Angelino, E. ; Angevaare, J. R. ; Antochi, V. C. ; et al ( June 2023 , The European Physical Journal C)

   Abstract A low-energy electronic recoil calibration of XENON1T, a dual-phase xenon time projection chamber, with an internal $${}^{37}$$ 37 Ar source was performed. This calibration source features a 35-day half-life and provides two mono-energetic lines at 2.82 keV and 0.27 keV. The photon yield and electron yield at 2.82 keV are measured to be ( $$32.3\,\pm \,0.3$$ 32.3 ± 0.3 ) photons/keV and ( $$40.6\,\pm \,0.5$$ 40.6 ± 0.5 ) electrons/keV, respectively, in agreement with other measurements and with NEST predictions. The electron yield at 0.27 keV is also measured and it is ( $$68.0^{+6.3}_{-3.7}$$ 68 . 0 - 3.7 + 6.3 ) electrons/keV. The $${}^{37}$$ 37 Ar calibration confirms that the detector is well-understood in the energy region close to the detection threshold, with the 2.82 keV line reconstructed at ( $$2.83\,\pm \,0.02$$ 2.83 ± 0.02 ) keV, which further validates the model used to interpret the low-energy electronic recoil excess previously reported by XENON1T. The ability to efficiently remove argon with cryogenic distillation after the calibration proves that $${}^{37}$$ 37 Ar can be considered as a regular calibration source for multi-tonne xenon detectors. 

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2. A cosmologically consistent millicharged dark matter solution to the EDGES anomaly of possible string theory origin

   https://doi.org/10.1007/JHEP12(2021)148  

   Aboubrahim, Amin ; Nath, Pran ; Wang, Zhu-Yao ( December 2021 , Journal of High Energy Physics)

   A bstract Analysis of EDGES data shows an absorption signal of the redshifted 21-cm line of atomic hydrogen at z ∼ 17 which is stronger than expected from the standard ΛCDM model. The absorption signal interpreted as brightness temperature T 21 of the 21-cm line gives an amplitude of $$ -{500}_{-500}^{+200} $$ − 500 − 500 + 200 mK at 99% C.L. which is a 3.8 σ deviation from what the standard ΛCDM cosmology gives. We present a particle physics model for the baryon cooling where a fraction of the dark matter resides in the hidden sector with a U(1) gauge symmetry and a Stueckelberg mechanism operates mixing the visible and the hidden sectors with the hidden sector consisting of dark Dirac fermions and dark photons. The Stueckelberg mass mixing mechanism automatically generates a millicharge for the hidden sector dark fermions providing a theoretical basis for using millicharged dark matter to produce the desired cooling of baryons seen by EDGES by scattering from millicharged dark matter. We compute the relic density of the millicharged dark matter by solving a set of coupled equations for the dark fermion and dark photon yields and for the temperature ratio of the hidden sector and the visible sector heat baths. For the analysis of baryon cooling, we analyze the evolution equations for the temperatures of baryons and millicharged dark matter as a function of the redshift. We exhibit regions of the parameter space which allow consistency with the EDGES data. We note that the Stueckelberg mechanism arises naturally in strings and the existence of a millicharge would point to its string origin. 

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3. Dirac Fermion Kinetics in 3D Curved Graphene

   https://doi.org/10.1002/adma.202005838  

   Tanabe, Yoichi ; Ito, Yoshikazu ; Sugawara, Katsuaki ; Koshino, Mikito ; Kimura, Shojiro ; Naito, Tomoya ; Johnson, Isaac ; Takahashi, Takashi ; Chen, Mingwei ( October 2020 , Advanced Materials)

   3D integration of graphene has attracted attention for realizing carbon‐based electronic devices. While the 3D integration can amplify various excellent properties of graphene, the influence of 3D curved surfaces on the fundamental physical properties of graphene has not been clarified. The electronic properties of 3D nanoporous graphene with a curvature radius down to 25–50 nm are systematically investigated and the ambipolar electronic states of Dirac fermions are essentially preserved in the 3D graphene nanoarchitectures, while the 3D curvature can effectively suppress the slope of the linear density of states of Dirac fermion near the Fermi level are demonstrated. Importantly, the 3D curvature can be utilized to tune the back‐scattering‐suppressed electrical transport of Dirac fermions and enhance both electron localization and electron–electron interaction. As a result, nanoscale curvature provides a new degree of freedom to manipulate 3D graphene electrical properties, which may pave a new way to design new 3D graphene devices with preserved 2D electronic properties and novel functionalities.

    

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4. Low-energy effective theory and anomalous Hall effect in monolayer $\mathrm{WTe}_2$

   https://doi.org/10.21468/SciPostPhys.12.4.120  

   Nandy, Snehasish ; Pesin, Dima ( January 2022 , SciPost Physics)

   We develop a symmetry-based low-energy theory for monolayer \mathrm{WTe}_2 W T e 2 in its 1T ^{\prime} ′ phase, which includes eight bands (four orbitals, two spins). This modelreduces to the conventional four-band spin-degenerate Dirac model nearthe Dirac points of the material. We show that measurements of the spinsusceptibility, and of the magnitude and time dependence of theanomalous Hall conductivity induced by injected or equilibrium spinpolarization can be used to determine the magnitude and form of thespin-orbit coupling Hamiltonian, as well as the dimensionless tilt ofthe Dirac bands. 

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5. Low energy electronic recoils and single electron detection with a liquid Xenon proportional scintillation counter

   https://doi.org/10.1088/1748-0221/18/07/P07027  

   Qi, Jianyang ; Hood, Noah ; Kopec, Abigail ; Ma, Yue ; Xu, Haiwen ; Zhong, Min ; Ni, Kaixuan ( July 2023 , Journal of Instrumentation)

   Liquid xenon (LXe) is a well-studied detector medium to search for rare events in dark matter and neutrino physics. Two-phase xenon time projection chambers (TPCs) can detect electronic and nuclear recoils with energy down to kilo-electron volts (keV). In this paper, we characterize the response of a single-phase liquid xenon proportional scintillation counter (LXePSC), which produces electroluminescence directly in the liquid, to detect electronic recoils at low energies. Our design uses a thin (10–25 μm diameter), central anode wire in a cylindrical LXe target where ionization electrons, created from radiation particles, drift radially towards the anode, and electroluminescence is produced. Both the primary scintillation (S1) and electroluminescence (S2) are detected by photomultiplier tubes (PMTs) surrounding the LXe target. Up to 17 photons are produced per electron, obtained with a 10 μm diameter anode wire, allowing for the highly efficient detection of electronic recoils from beta decays of a tritium source down to ∼ 1 keV. Single electrons, from photoemission of the cathode wires, are observed at a gain of 1.8 photoelectrons (PE) per electron. The delayed signals following the S2 signals are dominated by single-photon-like hits, without evidence for electron signals observed in the two-phase xenon TPCs. We discuss the potential application of such a LXePSC for reactor neutrino detection via Coherent Elastic Neutrino Nucleus Scattering (CEνNS).

    

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