Radon exhalation from building materials for decorative use.

Long-term exposure to radon increases the risk of developing lung cancer. There is considerable public concern about radon exhalation from building materials and the contribution to indoor radon levels. To address this concern, radon exhalation rates were determined for 53 different samples of drywall, tile and granite available on the Canadian market for interior home decoration. The radon exhalation rates ranged from non-detectable to 312 Bq m(-2) d(-1). Slate tiles and granite slabs had relatively higher radon exhalation rates than other decorative materials, such as ceramic or porcelain tiles. The average radon exhalation rates were 30 Bq m(-2) d(-1) for slate tiles and 42 Bq m(-2) d(-1) for granite slabs of various types and origins. Analysis showed that even if an entire floor was covered with a material having a radon exhalation rate of 300 Bq m(-2) d(-1), it would contribute only 18 Bq m(-3) to a tightly sealed house with an air exchange rate of 0.3 per hour. Generally speaking, building materials used in home decoration make no significant contribution to indoor radon for a house with adequate air exchange.

A new digital autoradiographical method for identification of Pu particles using an imaging plate.

An autoradiographical method using an imaging plate (IP) was developed to identify rapidly the density of plutonium (Pu) particles on filter samples. Photostimulated luminescence (PSL) signals were obtained by exposing IPs to filter samples collecting Pu particles and naturally occurring radon decay products, respectively. Search and analysis of the alpha-induced PSL signals presented the time-dependent growth of PSL intensity from the Pu particles and the range of PSL intensities from radon decay products, making it possible to discriminate Pu particles from radon decay products using an empirical Pu-discrimination level, and then to quantify the Pu activities on a particle-by-particle basis. The method is useful for a fast screening of filter samples for Pu particles because it requires no special skills and tedious procedures during its use, gives a low discriminable activity for individual Pu particles with a relatively short exposure time, and allows us to measure a large number of filter samples at the same time.