A Lunar Microbial Survival Model for Predicting the Forward Contamination of the Moon.

The surface conditions on the Moon are extremely harsh with high doses of ultraviolet (UV) irradiation (26.8 W center dot m(-2) UVC/UVB), wide temperature extremes (-171 degrees C to 140 degrees C), low pressure (10(-10) Pa), and high levels of ionizing radiation. External spacecraft surfaces on the Moon are generally >100 degrees C during daylight hours and can reach as high as 140 degrees C at local noon. A Lunar Microbial Survival (LMS) model was developed that estimated (1) the total viable bioburden of all spacecraft landed on the Moon as similar to 4.57 x 10(10) microbial cells/spores at contact, (2) the inactivation kinetics of Bacillus subtilis spores to vacuum as approaching -2 logs per 2107 days, (3) the inactivation of spores on external surfaces due to concomitant low-pressure and high-temperature conditions as -6 logs per 8 h for local noon conditions, and (4) the ionizing radiation by solar wind particles as approaching -3 logs per lunation on external surfaces only. When the biocidal factors of solar UV, vacuum, high-temperature, and ionizing radiation were combined into an integrated LMS model, a -231 log reduction in viable bioburden was predicted for external spacecraft surfaces per lunation at the equator. Results indicate that external surfaces of landed or crashed spacecraft are unlikely to harbor viable spores after only one lunation, that shallow internal surfaces will be sterilized due to the interactive effects of vacuum and thermal cycling from solar irradiation, and that deep internal surfaces would be affected only by vacuum with a degradation rate of -0.02 logs per lunation.