Home
Introduction
LISE's Documentation
Last Changes of the code
LISE++ utilities
Perspectives: next development steps
Download (East Lansing)
Spectrometers in World
Related topics
Personal pages of the authors code
LISE registration page
E-mail
Future development



Reaction mechanism tasks

  Revise the de-excitation cascade

  Improve the Initial Fissioning Nuclei (IFN) utility

  Develop a Monte Carlo treatment for the evaporation cascade

  Develop the ADA (Abrasion-Dissipation-Ablation) model

  Optimize multi-step reactions using reliable cross-section models (AA, dBE, ..)

  Implement an intranuclear cascade (INC) model

  Include angular momentum in analytical fusion-fission and fusion-evaporation calculations


General tasks

  Enhancement of the silent mode by adding new commands, features, and output options

  "Isomer" project: connect the isomer and gamma databases to generate decay schemes

  Parallelization of computationally intensive calculations

  Prepare comprehensive LISE++ documentation

  Create the interactive "TUNER" utility for optimization and tuning of ion-optical systems

  Implement the LSODA integrator in the Radiation Residue Calculator to improve numerical stability for stiff systems

  Develop a utility to generate laboratory-frame angular and energy distributions of light particles, starting with evaporation and extending later to abrasion, ablation, and multi-fragmentation processes

  Create a G-block (Group block) utility for grouping and ungrouping E-blocks, enabling conversion between extended and sector configurations for fast analytical calculations, Monte Carlo high-order optics transmission, and Distribution-mode experiment planning


Continue

  Update GEMINI++, ETACHA, AA sites for latest development (04/2026)

  GEMINI++, PACE4: calculate and plot energy and angular distributions of residual nuclei and emitted light particles

  Continue modernizing the legacy source code to C++23 standards for improved stability

  Complete the implementation of the Invariant Mass E (IME)-HOLE model for use in calculations, not only for plotting

  Create and optimize LISE++ configuration files for different spectrometers. The authors hope to receive help from experts at these laboratories regarding specific information (transport files, location and characteristics of detectors, primary-beam emittance, etc.).

  Continue work on the universal parameterization of the momentum distributions of projectile-fragmentation products.


Additional tasks

  Improve higher-order optics calculations

  Wedge inclination, including wedges with curved profiles

  Three-body relativistic kinematics calculator

  Develop a subroutine for reduced-dispersion calculations at large values of dP/P

  Expand the online help files

  Develop a database of experimental data from fragmentation and fission experiments

  Implement the timing component in the DF4 distribution class

  Revise the Monte Carlo treatment of gas-filled dipoles

  Enable insertion of material before the target to account for energy loss, straggling, and charge-state distributions


Statistics