The upper threshold in ballistic annihilation
Three-speed ballistic annihilation starts with infinitely many particles on the real line. Each is independently assigned either speed-$0$ with probability $p$, or speed-$\pm 1$ symmetrically with the remaining probability. All particles simultaneously begin moving at their assigned speeds and mutua...
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| Main Authors | , , |
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| Format | Journal Article |
| Language | English |
| Published |
28.05.2018
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| Subjects | |
| Online Access | Get full text |
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| Summary: | Three-speed ballistic annihilation starts with infinitely many particles on
the real line. Each is independently assigned either speed-$0$ with probability
$p$, or speed-$\pm 1$ symmetrically with the remaining probability. All
particles simultaneously begin moving at their assigned speeds and mutually
annihilate upon colliding. Physicists conjecture when $p \leq p_c = 1/4$ all
particles are eventually annihilated. Dygert et. al. prove $p_c \leq .3313$,
while Sidoravicius and Tournier describe an approach to prove $p_c \leq .3281$.
For the variant in which particles start at the integers, we improve the bound
to $.2870$. A renewal property lets us equate survival of a particle to the
survival of a Galton-Watson process whose offspring distribution a computer can
rigorously approximate. This approach may help answer the nearly thirty-year
old conjecture that $p_c >0$. |
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| DOI: | 10.48550/arxiv.1805.10969 |