Probing cosmic histories in the lab

• Jessie Shelton (UIUC)

New Opportunities to Detect Axion Dark Matter

• Asher Berlin (Fermilab)

Improving dark matter sensitivities with new ionization detectors

• Daniel Egaña-Ugrinovic (Perimeter Institute)

New directions for direct detection with dielectrics

• Ben Lehmann (MIT)

The entanglement of quantum computing and dark matter searches

• Christopher Wilson (University of Waterloo)

Leveraging Quantum Sensors for Dark Matter Detection

• Daniel Baxter (University of Chicago)

Sub-GeV DM Detection using Superconducting Tunnel Junction Sensors

• Geon-Bo Kim (Lawrence Livermore National Laboratory)

Searching for sub-GeV dark matter with SuperCDMS

• Ziqing Hong (University of Toronto)

Reaching the meV Scale for Direct Detection with Quantum Sensors

• Noah Kurinsky (SLAC)

Latest results from the NEWS-G experiment

• Jean-Marie Coquillat (Queen's University)

QUEST-DMC: Probing Dark Matter with Nanowires, Superfluid Helium-3 and Quantum Sensors

• Paolo Franchini (University of Lancaster)

Expanding Dark Matter Direct Detection Reach Through Loops

• Melissa Diamond (Queen's University)

Thermal-ish targets for Dirac-ish dark matter

• Saniya Heeba (McGill University)

Update on the Montreal X17 Search Experiment

• Viktor Zacek (University of Montreal)

Progress Toward Low-Mass Dark Matter Detection with Superfluid He (HeRALD) and Polar Crystals (SPICE)

• David Osterman (University of Massachusetts)

We report on the recent progress of the SPICE/HeRALD (or TESSERACT) collaboration in developing detectors for dark matter masses down to 10MeV with the potential to upgrade for reach down to sub-MeV masses. SPICE and HeRALD are currently in an R&D phase of pushing the recoil energy thresholds of Transition Edge Sensors (TES) down to the sub-eV range, which can then be applied to well-motivated target materials. HeRALD uses superfluid 4He as a target, which has the advantage of a low-mass target nucleus and quantum evaporation-based detection of phonon energy. SPICE employs crystalline targets such as the polar crystals GaAs and Sapphire, which couple strongly to dark photon mediated DM. Both experiments are currently making pushes to reduce the ubiquitous low-energy excess background, which originates from spontaneous phonon emission by the calorimeter materials themselves and likely is the primary background in phonon-based detector experiments at eV-scales.

CUTE: A Cryogenic Underground TEst Facility at SNOLAB

• Andy Kubik (SNOLAB)

An Analytic Approach to Light Dark Matter Attenuation

• Christopher Cappiello (Queen's University)