IMMITTANCE SPECTROSCOPY Models, data fitting, and analysis

1. IMMITTANCE SPECTROSCOPYModels, data fitting, and analysis J. Ross Macdonald IMSPEMAS Workshop Warsaw 9/2003

2. MATERIAL/ELECTRODE CHARACTERIZATION WITH IS • Bulk resistivity and dispersion • Bulk dielectric constant • Mobile charge concentrations • Mobilities and valence numbers • Bulk dissociation and recombination rates • Electrode reaction rate constant • Electrode adsorption rate constant • Other fit-model parameters

7. IMMITTANCE SPECTROSCOPY • Impedance Spectroscopy • Dielectric Spectroscopy • Data Analysis • CNLS; INVERSION • LEVM ---- LEVMW V. 8

9. CNLS-LEVM-LEVMW • CNLS: Complex nonlinear least squares fitting. Fit complex data to a model whose parts satisfy the Kronig-Kramers transform relations • LEVMW: Windows version of LEVM, a free general CNLS fitting and inversion program. Download it and its manual from http://www.physics.unc.edu/~macd/ • LEVMW can accurately fit data to K0, K1, and many other models. It allows temporal response to be calculated from frequency response and vice versa

18. ELECTRODE EFFECTS AND SLOPES

24. BULK K0 AND K1 FIT RESULTS

36. NEARLY CONSTANT LOSS

41. CONCLUSIONS • The Moynihan original modulus formalism dispersion model is theoretically and experimentally incorrect and should be replaced by the corrected modulus formalism. • The corrected modulus formalism isisomorphic to the Scher-Lax microscopic model and leads to virtually independent of temperature and ionic concentration.

42. The variable-correlation assumption of the OMF and NCM is unsupported by fits of experimental data using the CK1 CMF model. • The cutoff model is much superior to all coupling models and requires no ad hoc assumptions. • Nearly-constant-loss behavior is likely to be associated with coupling between vibrating ions and induced dipoles of the bulk material. A microscopic model of the process is needed.