Last version:
, October 16th 2024 (last respin 2024.1.2) 06-May-2024
News:
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Fluka Release
(
16.10.2024
)
FLUKA 2024.1.2 has been
released.
New FLUKA reference, please read and cite it:
F. Ballarini et al.,
The FLUKA code: Overview and new developments,
EPJ Nuclear Sci. Technol. 10, 16 (2024)
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0 What is FLUKA?
FLUKA is a general purpose tool for calculations of particle transport
and interactions with matter, covering an extended range of
applications spanning from proton and electron accelerator shielding to
target design, calorimetry, activation, dosimetry, detector design,
Accelerator Driven Systems, cosmic rays, neutrino physics, radiotherapy
etc.
The highest priority in the design and development of FLUKA has always been
the implementation and improvement of sound and modern physical models.
Microscopic models are adopted whenever possible, consistency among all the
reaction steps and/or reaction types is ensured, conservation laws are enforced
at each step, results are checked against experimental data at single
interaction level. As a result, final predictions are obtained with a minimal
set of free parameters fixed for all energy/target/projectile combinations.
Therefore results in complex cases, as well as properties and scaling laws,
arise naturally from the underlying physical models, predictivity is provided
where no experimental data are directly available, and correlations within
interactions and among shower components are preserved.
FLUKA can simulate with high accuracy the interaction and propagation
in matter of about 60 different particles, including photons and electrons
from 1 keV to thousands of TeV, neutrinos, muons of any energy, hadrons
of energies up to 20 TeV (up to 10 PeV by linking FLUKA
with the DPMJET code) and all the corresponding antiparticles, neutrons down
to thermal energies and heavy ions. The program can also transport polarised
photons (e.g., synchrotron radiation) and optical photons. Time evolution and
tracking of emitted radiation from unstable residual nuclei can be performed
online.
FLUKA can handle even very complex geometries, using an improved version of the
well-known Combinatorial Geometry (CG) package. The FLUKA CG has been designed
to track correctly also charged particles (even in the presence of magnetic or
electric fields). Various visualisation and debugging tools are also available.
For most applications, no programming is required from the user.
However, a number of user interface routines (in Fortran 77) are
available for users with special requirements.
The FLUKA physical models are described in several journal and conference
papers; on the technical
side the stress has been put on four apparently conflicting
requirements, namely efficiency, accuracy, consistency and flexibility.
Efficiency has been achieved by having a frequent recourse to table look-up
sampling and a systematic use of double precision has had a great impact on
overall accuracy: both qualities have benefited from a careful choice of the
algorithms adopted. To attain a reasonable flexibility while minimising
the need for user-written code, the program has been provided with a
large number of options available to the user, and has been completely
restructured introducing dynamical dimensioning.
Another feature of FLUKA, probably not found in any other Monte Carlo
program, is its double capability to be used in a biased mode as well as a
fully analogue code. That means that while it can be used to predict
fluctuations, signal coincidences and other correlated events, a wide choice of
statistical techniques are also available to investigate punchthrough or other
rare events in connection with attenuations by many orders of magnitude.
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