Dear IFFEFIT user I do some EXAFS simulations (FEFF8.4) of small pure Cu clusters (fcc bulk structure) and then I try to compare them with experimental data. The simulations are performed on all the shells, then all the contribution are added according to the number of atoms per shell (so the total xmu of a cluster of 19 atoms is = [xmu0+12*xmu1+6*xmu2]/19 where xmu0 is the xmu of the atom in the center of the cluster and xmu1 of the atoms in the first shell and xmu2 for the second shell). The first and obvious result concerns the peaks amplitude of the FT which is proportional to the number of atoms involved in the simulations. I have calculated the EXAFS spectra from the xmu.dat files. As you know in EXAFS simulations there is not pre-edge so finally is not easy to find the right value of E0. In the Athena.prj file I attached you can easily see this effect changing the absorption energy of Cu Bulk 4 from 8988.430eV to 8988.431eV. The amplitude of the first peak of the FT changes from 100 to 60! In order to overcome this problem I recalculated the FT using the chi.dat and not the xmu.dat. In the Athena file you can find the 8 simulations based on the xmu.dat (and they are called Cu bulk 1.... Cu bulk 8) and on the chi.dat (called CHI_Cu bulk 1....8). Of course they refer to the same cluster and they were calculated in the same way. Since these simulations, calculated on the Chi.dat, are very different from those calculated on xmu.dat, some questions rise. Moreover if you compare the FT of the simulations Chi_Cu bulk 5 and Chi_Cu Bulk 6 you can see that the amplitude of the first peak is larger for the smaller cluster. 1. Should I use the spectra I got from the xmu.dat or from the chi.dat? 2. Are the difference between Chi_Cu 5 and Chi Cu 6 (even if small) due to the E0 calculation? 3. How shall I behave if the first derivative of some simulations does not show a peak where it is "reasonably" expected (compare Cu Bulk 4 and Cu Bulk 7) 4. Do you have any other suggestions? Thank you in advance for any suggestion, Best regards Sebastiano Cammelli