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Flexible for any mechanism up to second-order chemical reaction. User can type in his mechanism. No divergence problem in simulation. No overflow problem in simulation. Fast simulation. Linear sweep, CV, DC, normal pulse, differential pulse, square wave voltammetries. Multi-cyclic voltammetry, cyclic differential pulse voltammetry. It outputs current, resistance, conductivity and surface concentration. You can compare your data with theoretical peak values to see if your experimental conditions reach theoretical limit or not. It manually and auto separates overlapped peaks into individuals, and extract real peak from voltammogram with noise and baseline. So you can exactly determine peaks. You can change preconcentration conditions for stripping voltammetry. It manually and auto fits the simulated voltammograms into experimental data, and extracts kinetic parameters from experimental data. You can export simulated data into your favor program (e.g. MS Excel). You can copy-n-paste the voltammogram into your document. Semi-derivative is useful for CV. It can change a shape of reversible CV into symmetric peak so easy to determine peak. planar, spherical, semi-spherical, cylindrical, semi-cylindrical, microdisk, thin film, and rotating electrodes. It shows tip for help when you put mouse cursor over a label.
Table 2.1 Features ----------------------------------------------------------------------------- version Public Student Standard Full competitor digital simulation y y y y y analytical simulation y y y y n theoretical peak y y y y n Techniques: LSV, CV y y y y y DC y y y y n normal pulse y y y y n differential pulse y y y y n cyclic DPV y y y y n square wave y y y y n Output: current y y y y y resistance y y y y n conductivity y y y y n surface concentration y y y y y Effect: chemical mechanisms y y y y y noise y y y y y charge current y y y y y resistance y y y y y electrolyte y y y y n preconcentration y y y y n pre-equilibration y y y y y conductivity y y y y n Analysis: derivative y y y y n integral y y y y n semi-derivative y y y y n semi-integral y y y y n manual fit n y y y y auto fit n n y y y manual separate n n n y n auto separate n n n y n Electrode: planar y y y y y (micro)spherical y y y y y (micro)hemispherical y y y y y (micro)cylindrical y y y y y (micro)hemicylindrical y y y y y microdisc y y y y n thin film y y y y y rotating disc y y y y y tip y y y y n import data n y y y y export data n y y y n ----------------------------------------------------------------------------- note: y = yes, n = no. price may be changed.
File menu
Input menu
Run menu
Display menu
Analysis menu
Help menu
Some menus will be activated only after you click the Simulate submenu or load data because they require data.
Chapter 4 4.1 Techniques window 1) Linear sweep and cyclic voltammetry The shapes of DC and normal pulse polarogram are S-shape. The shapes of differential pulse and square wave voltammograms usually are peak-shape. But there is effect of the DC term on differential pulse voltammogram. 4.2 Mechanism window User can type in his mechanism in Digital Simulation section. In order to faster computation, you should type in reactants only without products if chemical reaction is irreversible.
Instrumental Parameters Section: E start: starting potential (V). t pulse: pulse time or pulse width for pulse voltammetry (s). t drop: mercury dropping time or pulse length for pulse voltammetry (s). Noise: ratio of noise to maximum signal (%). C dl: double layer capacitor for charge current (F). R: resistance (Ohm). Scan: Single: single scan. Cycles: cyclic scan, e.g. cyclic voltammetry (CV). 2 Cycles: 2-cycle scan. Electrode Section: Planar: planar electrode. Preconcentration Section: E pre: preconcentration potential (V).
4.3 Chemicals Window Species Section: D: diffusion coefficient (cm2/s). Heterogeneous Reaction Section: ks: heterogeneous standard rate constant (cm/s). a: electron transfer coefficient. n: electron number. E°: standard electrode potential (V). Homogeneous Reaction Section: kf: forward chemical reaction rate constant.
A simplest way to play simulation is just to click the Simulate submenu under the Run menu. It uses the default values to simulate a linear sweep voltammogram. Notice that some menu (e.g. the Display menu and the Analysis menu) will be activated only after run simulation or load data because they require data. 5.1.1 Effect of Electrode Size - Microelectrode Simulation technology for microelectrode is the same as for macro electrode, but the electrode size is very small, e.g. electrode radius is 1e-4 cm. A shape of voltammogram will be changed. Note that the planar electrode geometry is not available for microelectrode.
After run first simulation, click the Display menu, and click the Option submenu. Select the Overlap choice, then run second simulation.
Semi-derivative is useful for CV. It can change a shape of CV into symmetric peak if CV is reversible.
5.4 Extracting Parameters by Curve Fitting 5.4.1 Fitting to Simulation Curve In order to extract kinetic parameters, you can fit a simulation curve to another simulated or experimental curve. You should manual fit before auto fit. The manual fit shows how well your initial guess values work. It can retrieve any of 20 parameters (concentration C, standard electrode potential E°, and the heterogeneous standard rate constant ks) from voltammogram by curve fitting. If it diverged, you should change their initial values, then try again. e.g. run simulation with all default values, then change the C value from 1e-3 to 2e-3 in the Species section, click the Auto Fit menu. You will see the fitted value of 0.001 in the C fitted field next to the C text field. 5.4.2 Fitting to Experimental Curve It is similar to fit simulated curve. But you should input your experimental values of E start, E end, E step, etc. into the Experimental section. Polar requires data are in SI unit and first peak is positive value. If your experimental data are not, please convert your experimental data.
Select the Preconcentration in the Experiential Parameters window. Change the preconcentration potential value in the E pre text field, and preconcentration time in the t pre text field. The preconcentration potential value usually is -0.2/n V to specie’s standard electrode potential. The preconcentration time usually is a number of minutes. You should enter your electrode constant into the P cont text field, and your mercury film thickness into the Length field in the Electrode section of the Experimental window if you use a planar mercury film electrode.
Chapter 6 Q: Which platforms can Polar run on? The 32-bit version needs Microsoft Visual Basic 6 runtime DLL files (e.g. msvbvm60.dll, comdlg32.ocx) in the same directory as Polar or in the directory \windows\system for Windows 3.11 or 95, or in the directory \winnt\system32 for Windows NT. The 16-bit version needs Microsoft Visual Basic 4 runtime DLL files (e.g. vb40016.dll and oc25.dll) in the same directory as Polar or in the directory \windows\system for Windows 3.1, or in the directory \winnt\system for Windows NT. Q: Where can I download these dll? A: Microsoft Visual Basic 6 runtime DLL files are from http://www.simtel.net/simtel.net/win95/dll.html, where msvbvm60.dll is inside simvb6-3.zip. Microsoft Visual Basic 4 16-bit runtime DLL files are from http://www.simtel.net/simtel.net/win3/dll.html.Q: When I click the Simulate menu, I got error: No data. A: I guess you are running it under non-English version of Windows. Please change language setting to English in the Regional Setting of the Control Panel, and restart Polar. Or try it under English version of Windows. Some non-English versions of Windows have problem to run English version program. Q: I cannot save a file. A: You miss the Microsoft Visual Basic 6 runtime DLL file comdlg32.ocx. Q: When I installed to run setup.exe, an error occured: >c:\windows\system\MSRD2x35.dll Shall I (Abort, Retry, Ignore)? A: Ignore. Do not worry about MSRD2x35.dll. Running Polar did not use it, setup.exe check it only. Q: Still have install problem? A: I suggest you close all programs (include Office, Mail) before install Polar. If you still have problem, try to register file msvbvm60.dll by double click or type following command in DOS: Cd \windows\system Q: Why are some menus grey? A: Some menus will be activated only after you click the Simulate menu or load data because they need data. Q: I cannot see any chemical reaction in Public version. Is this part of the program not finished yet or is it only available in the registered version? A: There is only one chemical reaction available in the Public version. You can change chemical reaction rate kf, e.g. 1010. The registered versions include common mechanisms. Please read document for details. Q: Does it include my mechanism? A: If your mechanism is missing, please send your requirement into author. Author may add your mechanism into new version special for you. Q: Can it fit data by curve fitting? A: Yes. As easy as just point and click. Q: Can I change graph into other program Lotus 123 or Excel? A: Yes. You export data in text file, then read data into Lotus 123 or Excel. Q: Some submenus semi-derivative, semi-integral, derivative, and integral, seem to not work sometime. How can I do? A: You should first click the Next submenu under the Plot menu, then try semi-derivative submenu. Q: How much does registration cost? A: About $100. Q: How can I get registered version? A: You will receive it if you send author register fee by check or money order. Q: What are difference among Public, Standard and Professional, and Full versions? A: The Public version is for teaching, the Standard version is for average users, the Professional version is for professionals, and the Full version is for special users. Q: When I run the SWV with default conditions as a digital simulation, it does not appear to give the correct curve. Why? Because default conditions are for linear sweep and CV only. For SWV, DC, NPV and DPV, you should change scan rate v to 0.01. For SWV you should calculate correct scan rate by v=E step/t pulse before run digital simulation. Q: Is it possible to click on a point and then have displayed both the current and potential for the point? Also, does it have any zoom features? Q: How does it compare to competitors? A: Polar has advantages over competitors:
[1] W. Huang, T. Henderson, A.M. Bond and K.B. Oldham, Curve fitting to resolve overlapping voltammetric peaks: model and examples, Anal. Chim. Acta, 1995, 304, 1-15. [2] W. Huang and B. Hibbert, Computers & Chem., 1995, 19(4), 433. [3] W. Huang and B. Hibbert, Computers & Chem., 1995, 19(4), 435. [4] W. Huang and B. Hibbert, Polar 2.0 for Windows: simulator of voltammogram, Chem. in Aus., 1996, 131. [5] J. Mo, P. Cai, W. Huang and F. Yun, Theory and application on multiple semidifferential electrochemical stripping analysis with thin mercury film formed in situ, Acta Chimica Sinica, 1984, 42(6), 556-561, CA 101: 162712. |
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