B Liu1, J Xu, T Liu, X Ouyang. 1. School of Nuclear Science & Engineering, North China Electric Power University, Beijing, China. Liu_Bin@ncepu.edu.cn
Abstract
OBJECTIVE: To simulate the neutron-based sterilisation of anthrax contamination by Monte Carlo N-particle (MCNP) 4C code. METHODS: Neutrons are elementary particles that have no charge. They are 20 times more effective than electrons or γ-rays in killing anthrax spores on surfaces and inside closed containers. Neutrons emitted from a (252)Cf neutron source are in the 100 keV to 2 MeV energy range. A 2.5 MeV D-D neutron generator can create neutrons at up to 10(13) n s(-1) with current technology. All these enable an effective and low-cost method of killing anthrax spores. RESULTS: There is no effect on neutron energy deposition on the anthrax sample when using a reflector that is thicker than its saturation thickness. Among all three reflecting materials tested in the MCNP simulation, paraffin is the best because it has the thinnest saturation thickness and is easy to machine. The MCNP radiation dose and fluence simulation calculation also showed that the MCNP-simulated neutron fluence that is needed to kill the anthrax spores agrees with previous analytical estimations very well. CONCLUSION: The MCNP simulation indicates that a 10 min neutron irradiation from a 0.5 g (252)Cf neutron source or a 1 min neutron irradiation from a 2.5 MeV D-D neutron generator may kill all anthrax spores in a sample. This is a promising result because a 2.5 MeV D-D neutron generator output >10(13) n s(-1) should be attainable in the near future. This indicates that we could use a D-D neutron generator to sterilise anthrax contamination within several seconds.
OBJECTIVE: To simulate the neutron-based sterilisation of anthrax contamination by Monte Carlo N-particle (MCNP) 4C code. METHODS: Neutrons are elementary particles that have no charge. They are 20 times more effective than electrons or γ-rays in killing anthrax spores on surfaces and inside closed containers. Neutrons emitted from a (252)Cf neutron source are in the 100 keV to 2 MeV energy range. A 2.5 MeV D-D neutron generator can create neutrons at up to 10(13) n s(-1) with current technology. All these enable an effective and low-cost method of killing anthrax spores. RESULTS: There is no effect on neutron energy deposition on the anthrax sample when using a reflector that is thicker than its saturation thickness. Among all three reflecting materials tested in the MCNP simulation, paraffin is the best because it has the thinnest saturation thickness and is easy to machine. The MCNP radiation dose and fluence simulation calculation also showed that the MCNP-simulated neutron fluence that is needed to kill the anthrax spores agrees with previous analytical estimations very well. CONCLUSION: The MCNP simulation indicates that a 10 min neutron irradiation from a 0.5 g (252)Cf neutron source or a 1 min neutron irradiation from a 2.5 MeV D-D neutron generator may kill all anthrax spores in a sample. This is a promising result because a 2.5 MeV D-D neutron generator output >10(13) n s(-1) should be attainable in the near future. This indicates that we could use a D-D neutron generator to sterilise anthrax contamination within several seconds.
Authors: A D Pannifer; T Y Wong; R Schwarzenbacher; M Renatus; C Petosa; J Bienkowska; D B Lacy; R J Collier; S Park; S H Leppla; P Hanna; R C Liddington Journal: Nature Date: 2001-11-08 Impact factor: 49.962
Authors: Timothy D Read; Scott N Peterson; Nicolas Tourasse; Les W Baillie; Ian T Paulsen; Karen E Nelson; Hervé Tettelin; Derrick E Fouts; Jonathan A Eisen; Steven R Gill; Erik K Holtzapple; Ole Andreas Okstad; Erlendur Helgason; Jennifer Rilstone; Martin Wu; James F Kolonay; Maureen J Beanan; Robert J Dodson; Lauren M Brinkac; Michelle Gwinn; Robert T DeBoy; Ramana Madpu; Sean C Daugherty; A Scott Durkin; Daniel H Haft; William C Nelson; Jeremy D Peterson; Mihai Pop; Hoda M Khouri; Diana Radune; Jonathan L Benton; Yasmin Mahamoud; Lingxia Jiang; Ioana R Hance; Janice F Weidman; Kristi J Berry; Roger D Plaut; Alex M Wolf; Kisha L Watkins; William C Nierman; Alyson Hazen; Robin Cline; Caroline Redmond; Joanne E Thwaite; Owen White; Steven L Salzberg; Brendan Thomason; Arthur M Friedlander; Theresa M Koehler; Philip C Hanna; Anne-Brit Kolstø; Claire M Fraser Journal: Nature Date: 2003-05-01 Impact factor: 49.962