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The program LISE++ has been developed
to calculate the transmission and yields of fragments produced and
collected
in a spectrometer. This code allows to simulate an experiment,
beginning
from the parameters of the reaction mechanism and finishing with the
registration
of products selected by a spectrometer. The program allows to quickly
optimize
the parameters of the spectrometer before or during the experiment. It
also makes it possible to estimate and work in conditions of maximum
output
of studied reaction products and their unambiguous identification.
Wedge
and Wien filter selections are also included in the program. The LISE++ package operating on Windows, macOS, Linux environment is a freeware software product with the .
LISE++ is
the generation of the LISE code,
which allows the creation of a spectrometer through the use of different "blocks".
The number of blocks used to create a spectrometer in LISE++ is
limited by operating memory of your PC and your imagination.
The LISE++ package has been ported to Qt-framework for compatibility with multiple operating systems. The benefits include 64-bit operation, cross-platform compatibility (Windows, macOS, Linux), and the ability to take advantage of future computational improvements. LISE++ version 15, created using the Qt framework, is named LISEcute++ to indicate a new generation different from the previous LISE++ Borland-based versions.
Built-in Energy loss, Time-of-Flight, Position, Angular, Charge, Cross-Section distribution plots and dE-E,
dE-TOF, Z-A/q, and dE-X two-dimensional plots allow to visualize the results of
the program calculations. An application of transport integral lies in
thebasis of fast calculations of the program for the estimation of
temporary evolution of distributions of phase space.
The LISE++
code may be applied at medium-energy and high-energy facilities
(fragment- and recoil-separators with
electrostatic
and/or magnetic selections). A number of these facilities, like A1900 and S800
at NSCL, ARIS, HRS, ISLA, SECAR
at FRIB, LISE3 and S3
at GANIL/SPIRAL2, FRS and SuperFRS at GSI/FAIR, RIPS and BigRIPS
at RIKEN, based on the separation of projectile-like
and fission fragments, fusion
residues are included or
might be easily added to the existing optical configuration files.
The Projectile Fragmentation, Fusion-Evaporation, Fusion-Fission, Coulomb Fission, and Abrasion-Fission assumed in this program as the production reaction
mechanism allows to simulate
experiments at beam energies above the Coulomb barrier.
Built-in powerful tools:
 Monte Carlo simulation of fragment transmission,
Monte Carlo simulation of fission fragment kinematics,
Ion Optics calculation and Optimization ,
LISE for Excel (32-bit)
LISE++ calculators:
"Physical Calculator",
"Relativistic Kinematics Calculator",
"Evaporation Calculator",
"Radiation Residue Calculator",
"Ion Mass calculator",
"Matrix calculator"
"Initial Fissile Nuclei analyzer"
Implemented codes:
«PACE4» (fusion-evaporation code),
«GEMINI++» (statistical code),
«MOTER» (raytracing-type program for magnetic optic system design)
«ETACHA4» (charge-state distribution code),
«Global» (charge-state distribution code),
«Charge» (charge-state distribution code),
«Spectroscopic Calculator" (of J.Kantele»)
LISE++ Utilities:
Loading ARIS settings
Stripper Foil Lifetime Utility,
Brho Analyzer,
Twinsol (solenoid) utility,
Units Converter,
ISOL Catcher,
Decay Analysis (includes Proton, Alpha, Cluster, Sp.Fission half-lives calculation),
Reaction Utilities (Characteristics, Converters, Plots),
«BI»- the
automatized search of two-dimensional peaks in spectra
Databases:
Nuclide and Isomeric State databases with utilities,
Large Set of Calculated Mass Tables (includes FRIB mass tables),
Ionization Energy database (used with the Ion Mass calculator),
Decay Branching Ratio database (used with the Radiation Residue calculator),
permit to work well below this energy limit, and this makes the program very attractive for all users dealing with physics of
heavy ions from 10 keV up to some GeV per nucleon.
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