Silicon p-i-n diode-neutron dosimeters were irradiated with monoenergetic neutrons having energies from 0.36 to 4.77 MeV. The variation with neutron energy of the damage coefficient for diode storage time, Â¿T = Â¿(l/Ts)/Â¿, and diode forward voltage sensitivity at constant current, S = Â¿Vf/Â¿, were determined and found to be equal. Since Â¿T; and S are linearly related to the damage coefficient for high level lifetime, Â¿T; = Â¿(1/Â¿)/Â¿, the variation with neutron energy of Â¿T was also determined. Theoretically, it has been hypothesized that Â¿T is proportional to NÂ¿r(En), the average number of active recombination centers added per cm3 per neutron of energy En incident per cm2. It was further hypothesized that NÂ¿r(En) is proportional to Â¿(En), the average energy given to lattice atoms per cm3 per neutron of energy En incident per cm2. The theory of Lindhard, Nielson, Scharff, and Thomsen together with published values for differential neutron-silicon scattering, was used to calculate Â¿(En). Comparison of theoretical and experimental results shows that Â¿T, S, and Â¿(En) do indeed have substantially the same neutron energy dependence.