29,846 research outputs found
The B36/S125 "2x2" Life-Like Cellular Automaton
The B36/S125 (or "2x2") cellular automaton is one that takes place on a 2D
square lattice much like Conway's Game of Life. Although it exhibits high-level
behaviour that is similar to Life, such as chaotic but eventually stable
evolution and the existence of a natural diagonal glider, the individual
objects that the rule contains generally look very different from their Life
counterparts. In this article, a history of notable discoveries in the 2x2 rule
is provided, and the fundamental patterns of the automaton are described. Some
theoretical results are derived along the way, including a proof that the speed
limits for diagonal and orthogonal spaceships in this rule are c/3 and c/2,
respectively. A Margolus block cellular automaton that 2x2 emulates is
investigated, and in particular a family of oscillators made up entirely of 2 x
2 blocks are analyzed and used to show that there exist oscillators with period
2^m(2^k - 1) for any integers m,k \geq 1.Comment: 18 pages, 19 figure
Baryons 2002: Outlook
Summary and outlook presented at the 9th International Conference on the
Structure of Baryons (BARYONS 2002), Jefferson Lab, March 3-8, 2002Comment: 10 pages, to be publ.in: Proceedings Int. Conf. BARYONS 2002,
Jefferson Lab., March 200
Enzyme economy in metabolic networks
Metabolic systems are governed by a compromise between metabolic benefit and
enzyme cost. This hypothesis and its consequences can be studied by kinetic
models in which enzyme profiles are chosen by optimality principles. In
enzyme-optimal states, active enzymes must provide benefits: a higher enzyme
level must provide a metabolic benefit to justify the additional enzyme cost.
This entails general relations between metabolic fluxes, reaction elasticities,
and enzyme costs, the laws of metabolic economics. The laws can be formulated
using economic potentials and loads, state variables that quantify how
metabolites, reactions, and enzymes affect the metabolic performance in a
steady state. Economic balance equations link them to fluxes, reaction
elasticities, and enzyme levels locally in the network. Economically feasible
fluxes must be free of futile cycles and must lead from lower to higher
economic potentials, just like thermodynamics makes them lead from higher to
lower chemical potentials. Metabolic economics provides algebraic conditions
for economical fluxes, which are independent of the underlying kinetic models.
It justifies and extends the principle of minimal fluxes and shows how to
construct kinetic models in enzyme-optimal states, where all enzymes have a
positive influence on the metabolic performance
Yukawa's Pion, Low-Energy QCD and Nuclear Chiral Dynamics
A survey is given of the evolution from Yukawa's early work, via the
understanding of the pion as a Nambu-Goldstone boson of spontaneously broken
chiral symmetry in QCD, to modern developments in the theory of the nucleus
based on the chiral effective field theory representing QCD in its low-energy
limit.Comment: 21 pages, 13 figures. Proc. Yukawa-Tomonaga Symposium, Kyoto, Dec.06;
to be publ. in Progr. Theor. Phys. Suppl. (Kyoto
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