Contact : François HUET
The SIMAD software can be used to simulate and adjust experimental electrochemical impedances, or more generally complex variable transfer functions, by the downhill simplex method, from a model based either on an equivalent circuit, or on electrochemical kinetic equations describing a reaction mechanism. The latter feature is not available in commercial electrochemical impedance fitting software.
The originality of the software lies in its ability to build impedance models in the form of a sequence of commands allowing analytical functions. The advantages are identical to those obtained with the use of a computer program without prior knowledge of a programming language. Most of the tools currently on the market offer libraries of pre-established elementary components (equivalent electrical circuits, diffusion models, etc.), limiting their use to simplified modeling of electrochemical impedances.
Compared to the initial version of the software available in 2012, new features have been developed, such as:
• the sensitivity coefficient of each parameter is calculated automatically at each adjustment: this coefficient was sorely lacking in the initial version
because its knowledge is essential for validating the value of the adjusted parameter.
• a “Consecutive adjustments” submenu allows several experimental impedance arrays to be adjusted automatically after having defined the adjustment
model.
• an "Operations" submenu for performing operations on experimental impedance arrays, e.g. calibrating an experimental file, removing electrolyte
resistance at all impedance frequencies, calculating the admittance of a measured impedance, adding or subtracting impedances, calculating complex
capacitance, etc.
• the parameters of a single analytical model can be adjusted simultaneously on several experimental impedance arrays measured at different potentials.
As an example, the figure below shows Simad's main page in which 2 experimental impedance arrays have been opened (highlighted in blue). They correspond to the impedances of the iron/H2SO4 system measured at potentials -0.91 V/SSE and -0.6 V/SSE, which have been fitted using the classical analytical model with 2 electrochemical reactions described at the top right of the page.
The following figure shows the plots of experimental and adjusted impedances in Nyquist and Bode diagrams, together with the relative errors obtained for each impedance.
