The symmetry energy at the time of the production of intermediate mass fragments(IMFs) is studied using experimentally observed IMF multiplicities combined with quantum statistical model calculations(QSM of Hahn and St cker).The ratios of difference in chemical potentials between neutrons and protons relative to the temperature,(μn-μp)/T,and the double ratio temperature,T,were extracted experimentally in the reactions of64,70Zn,64Ni+58,64Ni,112,124Sn,197Au,232Th at 40A MeV.The extracted(μn-μp)/TTscales linearly with δNN,where δNN is the asymmetry parameter,(N-Z)/A,of the emitting source and(μn-μp)/T=(11.1 1.4)δNN0.21 was derived.The experimentally extracted(μn-μp)/T and the double ratio temperatures are compared with those from the QSM calculations.The temperatures-,T,and densities,ρ,extracted from the(μn-μp)/T values agreed with those from the double ratio thermometer which used the yield ratios of d,t,h and α particles.However the two analyses of the differential chemical potential analysis and the initial temperature analysis end up almost identical relation between T and ρ.T=5.25±0.75 MeV is evaluated from the(μn-μp)/Tanalysis,but no density determination was possible.From the extracted T value,the symmetry energy coefficient Esym =14.6±3.5 MeV is determined for the emitting source of T=5.25±0.75 MeV. The symmetry energy at the time of the production of intermediate mass fragments (IMFs) is studied using experimentally observed IMF multiplicities combined with quantum statistical model calculations (QSM of Hahn and St cker). The ratios of difference in chemical potentials between neutrons and protons relative (μn-μp) / T, and the double ratio temperature, T, were extracted experimentally in the reactions of 64,70 Zn, 64Ni + 58,64Ni, 112,124Sn, 197Au, 232Th at 40A MeV. - μp) / TTscales linearly with δNN where δNN is the asymmetry parameter, (NZ) / A, of the emitting source and (μn-μp) / T = (11.1 1.4) δNN0.21 was derived. -μp) / T and the double ratio temperatures are compared with those from the QSM calculations. The temperatures-, T, and densities, ρ, extracted from the (μn-μp) / T values ​​agreed with those from the double ratio thermometer which used the yield ratios of d, t, h and α particles. Both of the two analyzes of the differential chemi cal potential analysis and the initial temperature analysis end up almost identical relation between T and ρ.T = 5.25 ± 0.75 MeV is evaluated from the (μn-μp) / Tanalysis, but no density determination was possible. Symmetry energy coefficient Esym = 14.6 ± 3.5 MeV is determined for the emission source of T = 5.25 ± 0.75 MeV.