1,653 research outputs found
Beam-beam simulation code BBSIM for particle accelerators
A highly efficient, fully parallelized, six-dimensional tracking model for
simulating interactions of colliding hadron beams in high energy ring colliders
and simulating schemes for mitigating their effects is described. The model
uses the weak-strong approximation for calculating the head-on interactions
when the test beam has lower intensity than the other beam, a look-up table for
the efficient calculation of long-range beam-beam forces, and a self-consistent
Poisson solver when both beams have comparable intensities. A performance test
of the model in a parallel environment is presented. The code is used to
calculate beam emittance and beam loss in the Tevatron at Fermilab and compared
with measurements. We also present results from the studies of two schemes
proposed to compensate the beam-beam interactions: a) the compensation of
long-range interactions in the Relativistic Heavy Ion Collider (RHIC) at
Brookhaven and the Large Hadron Collider (LHC) at CERN with a current-carrying
wire, b) the use of a low energy electron beam to compensate the head-on
interactions in RHIC
Perturbation theory of the space-time non-commutative real scalar field theories
The perturbative framework of the space-time non-commutative real scalar
field theory is formulated, based on the unitary S-matrix. Unitarity of the
S-matrix is explicitly checked order by order using the Heisenberg picture of
Lagrangian formalism of the second quantized operators, with the emphasis of
the so-called minimal realization of the time-ordering step function and of the
importance of the -time ordering. The Feynman rule is established and is
presented using scalar field theory. It is shown that the divergence
structure of space-time non-commutative theory is the same as the one of
space-space non-commutative theory, while there is no UV-IR mixing problem in
this space-time non-commutative theory.Comment: Latex 26 pages, notations modified, add reference
F1: An Eight Channel Time-to-Digital Converter Chip for High Rate Experiments
A new TDC chip has been developed for the COMPASS experiment at CERN. The resulting ASIC offers an unprecedented degree of flexibility and functionality. Its capability to handle highest hit and trigger input rates as well as its low power consumption makes it an ideal tool for future collider and fixed target experiments. First front-end boards equipped with the F1 chip have been used recently at testbeam experiments at CERN. A functional description and specification for this new TDC chip is presented.A new TDC chip has been developed for the COMPASS experiment at CERN. The resulting ASIC offers an unprecedented degree of flexibility and functionality. Its capability to handle highest hit and trigger input rates as well as its low power consumption makes it an ideal tool for future collider and fixed target experiments. First front-end boards equipped with the F1 chip have been used recently at testbeam experiments at CERN. A functional description and specification for this new TDC chip is presented
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