A.J. Cole

Cross talk and diaphony in neutron detectors

Abstract A neutron which enters a detector can be scattered into a neighbouring detector. If the neutron is registered in each detector the effect will be calle

Gas chambers for identification of charged particles in 4π systems

Abstract Gas ionization chambers of a special shape adapted for 4π detector systems are presented. Different anode wire configurations are discussed for three working gases: Ar + methane(10%), isobutane, and tetrafluoromethane.

Effect of the detector response on measurements performed with heavy-ion 4π detectors

Abstract We discuss the effect of geometrical efficiency and detection energy thresholds of a typical heavy-ion 4π detector (AMPHORA at the ISN) on measurements at energies near 35 MeV/nucleon. The study is based on simulation data generated by two different models: a microscopic interaction code which describes central as well as peripheral collisions, and a statistical code that describes the emission of pre-equilibrium nucleons followed by evaporation from an equilibrated incomplete-fusion system. Two reactions are studied, 32 S+ 27 Al at 37.5 MeV/nucleon and 40 Ca+ 40 Ca at 35 MeV/nucleon. We have investigated the effect of the incomplete (and selective) detection of the charged particles on several variables (parallel momentum, multiplicities, charge distribution), momentum distribution variables and moments of the event-by-event charge distribution. The results show that the response of the detector severely distorts the variable distributions and that a selection is required to obtain a set of data that represents the original ensemble. Total detected charge ( Z P + Z T ) selection can give, depending on the system, an acceptable representation of some of the variables in central and semi-peripheral reactions but the effect of the detector depends strongly on the kinematics of the studied reaction. The optimum application of this selection appears to be associated to relatively light systems studied under conditions of inverse kinematics.

Percolation and fragmentation of excited atomic nuclei

We present an analysis which aims at explaining the similarities (and differences) which exist between a simple bond percolation process on a cubic lattice and the fragmentation of highly excited atomic nuclei. Emphasis is placed on discussing percolation in terms of concepts which are well known in nuclear physics such asQ-value and particle emission thresholds. Similarities and differences between the bond percolation process and nuclear fragmentation are discussed. An approximate expression for the microcanonical partition sum (number of microstates) corresponding to any given percolation partition is shown to provide a good starting point for predicting fragment size distributions.