STOCHASTIC METHODS FOR THE NEUTRON TRANSPORT EQUATION II: ALMOST SURE GROWTH
成果类型:
Article
署名作者:
Harris, Simon C.; Horton, Emma; Kyprianou, Andreas E.
署名单位:
University of Auckland; Universite de Lorraine; University of Bath
刊物名称:
ANNALS OF APPLIED PROBABILITY
ISSN/ISSBN:
1050-5164
DOI:
10.1214/20-AAP1574
发表日期:
2020
页码:
2815-2845
关键词:
large numbers
STRONG LAW
superprocesses
摘要:
The neutron transport equation (NTE) describes the flux of neutrons across a planar cross-section in an inhomogeneous fissile medium when the process of nuclear fission is active. Classical work on the NTE emerges from the applied mathematics literature in the 1950s through the work of R. Dautray and collaborators (Methodes Probabilistes Pour les equations de la Physique (1989) Eyrolles; Mathematical Analysis and Numerical Methods for Science and Technology. Vol. 6: Evolution Problems. II (1993) Springer; Mathematical Topics in Neutron Transport Theory: New Aspects (1997) World Scientific). The NTE also has a probabilistic representation through the semigroup of the underlying physical process when envisaged as a stochastic process (cf. Methodes Probabilistes pour les equations de la Physique (1989) Eyrolles; Introduction to Monte-Carlo Methods for Transport and Diffusion Equations (2003) Oxford Univ. Press; IMA J. Numer. Anal. 26 (2006) 657-685; Publ. Res. Inst. Math. Sci. 7 (1971/72) 153-179). More recently, Cox et al. (J. Stat. Phys. 176 (2019) 425-455) and Cox et al. (2019) have continued the probabilistic analysis of the NTE, introducing more recent ideas from the theory of spatial branching processes and quasi-stationary distributions. In this paper, we continue in the same vein and look at a fundamental description of stochastic growth in the supercritical regime. Our main result provides a significant improvement on the last known contribution to growth properties of the physical process in (Publ. Res. Inst. Math. Sci. 7 (1971/72) 153-179), bringing neutron transport theory in line with modern branching process theory such as (Ann. Probab. 44 (2016) 235-275; Ann. Probab. 43 (2015) 2545-2610). An important aspect of the proofs focuses on the use of a skeletal path decomposition, which we derive for general branching particle systems in the new context of nonlocal branching generators.
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