82,217 research outputs found
Adaptive Ising Model and Bacterial Chemotactic Receptor Network
We present a so-called adaptive Ising model (AIM) to provide a unifying
explanation for sensitivity and perfect adaptation in bacterial chemotactic
signalling, based on coupling among receptor dimers. In an AIM, an external
field, representing ligand binding, is randomly applied to a fraction of spins,
representing the states of the receptor dimers, and there is a delayed negative
feedback from the spin value on the local field. This model is solved in an
adiabatic approach. If the feedback is slow and weak enough, as indeed in
chemotactic signalling, the system evolves through quasi-equilibrium states and
the ``magnetization'', representing the signal, always attenuates towards zero
and is always sensitive to a subsequent stimulus.Comment: revtex, final version to appear in Europhysics Letter
Octet Baryon Charge Radii, Chiral Symmetry and Decuplet Intermediate States
We compute the octet baryon charge radii to O(1/Heavy^3) in heavy baryon
chiral perturbation theory. We examine the effect of including the decuplet of
spin-3/2 baryons explicitly. We find that it does no t improve the level of
agreement between the HBchiPT and experimental values for the Sigma^- charge
radius.Comment: 9 pages, 2 figures. Uses axodraw.sty, include
SU(N) Fermions in a One-Dimensional Harmonic Trap
We conduct a theoretical study of SU(N) fermions confined by a
one-dimensional harmonic potential. Firstly, we introduce a new numerical
approach for solving the trapped interacting few-body problem, by which one may
obtain accurate energy spectra across the full range of interaction strengths.
In the strong-coupling limit, we map the SU(N) Hamiltonian to a spin-chain
model. We then show that an existing, extremely accurate ansatz - derived for a
Heisenberg SU(2) spin chain - is extendable to these N-component systems.
Lastly, we consider balanced SU(N) Fermi gases that have an equal number of
particles in each spin state for N=2, 3, 4. In the weak- and strong-coupling
regimes, we find that the ground-state energies rapidly converge to their
expected values in the thermodynamic limit with increasing atom number. This
suggests that the many-body energetics of N-component fermions may be
accurately inferred from the corresponding few-body systems of N
distinguishable particles.Comment: 15 pages, 6 figure
- …