XSophe

Research Quality CW EPR Simulations

: Multi-frequency CW-EPR Simulations

For research level quality yet ease of handling, XSophe provides the means for the simulation and analysis of CW and Pulse EPR spectra.. With a variety of simulation strategies, XSophe is poised to handle the complex systems present in modern research environments. This highly-developed simulation suite features an easy to use interface to assist in defining the spin system, interactions, and experimental parameters for spectrum simulation.

The XSophe simulation suite is intended to provide an easy-to-use yet powerful simulation environment for CW-EPR. The graphical environment allows rapid definition of the spin system, the spin Hamiltonian, instrumental parameters, and optimization parameters. Simulation visualization is based on Xepr which provides a feature rich environment for data processing, manipulation, and comparison.

The versatile simulations available include conventional experiments and special 2D experiments:

Continuous Wave – EPR spectra
Orientation Dependent CW-EPR spectra
Energy Level Diagrams
Transition Surfaces

Field vs.
- Goniometer angle
- Temperature
- Microwave Frequency

Spectra are simulated based on full Matrix Diagonalization with the Sophe partitioning scheme. Further, the superhyperfine interactions may be treated with 1st or 3rd order perturbation theory. This methodology imposes no limitations on the spin systems to be simulated:

Isolated Systems
Magnetically Coupled Systems
Unlimited Electron Spins

Unlimited Nuclear Spins
Multiple Nuclear Isotopes

Similarly, XSophe imposes no limitations on the CW-EPR spectrum to be simulated:

Solution Spectra
Powder Spectra
Single Crystal Spectra
Symmetry
Isotropic

Axial
Orthorhombic
Monoclinic
Triclinic

The ultimate in data analysis is achievable through direct optimization routines for the simulation of experimental spectra:

Hooke and Jeeves
Simplex
Simulated Annealing

Raw Data Comparison
FFT Spectral Comparison