Measurement of the bulk radioactive contamination of detector-grade silicon with DAMIC at SNOLAB

Abstract

We present measurements of bulk radiocontaminants in the high-resistivity silicon CCDs from the DAMIC at SNOLAB experiment. We utilize the exquisite spatial resolution of CCDs to discriminate between α and β decays, and to search with high efficiency for the spatially-correlated decays of various radioisotope sequences. Using spatially-correlated β decays, we measure a bulk radioactive contamination of 32Si in the CCDs of 140 30 μBq/kg, and place an upper limit on bulk 210Pb of < 160~μBq/kg. Using similar analyses of spatially-correlated bulk α decays, we set limits of < 11 μBq/kg (0.9 ppt) on 238U and of < 7.3 μBq/kg (1.8 ppt) on 232Th. The ability of DAMIC CCDs to identify and reject spatially-coincident backgrounds, particularly from 32Si, has significant implications for the next generation of silicon-based dark matter experiments, where β's from 32Si decay will likely be a dominant background. This capability demonstrates the readiness of the CCD technology to achieve kg-scale dark matter sensitivity.