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Posted:
6 years ago
4 oct. 2018, 05:57 UTC−4
I did this 4 years ago, wish this helps.
Lasse
I did this 4 years ago, wish this helps.
Lasse
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Posted:
6 years ago
5 oct. 2018, 01:43 UTC−4
I did this 4 years ago, wish this helps.
Lasse
Hi Lasse,
Thank you for your help. I also found your glucose oxidation example.
As I want to simulate the CV of EDL, I donot want to include electrode reactions. So I introduced the electrostatic interface to define a stern layer. And I defined a scan signal (E1) according to your method at the electrostatic interface. But I didnot get the correct CV curves for EDL. And if I defined a periodic scan signal (E2), the errors occured. Are there anything wrong with my settings? And my mph file is attached. Thank you!
Best,
Chi
>I did this 4 years ago, wish this helps.
>
>Lasse
Hi Lasse,
Thank you for your help. I also found your glucose oxidation example.
As I want to simulate the CV of EDL, I donot want to include electrode reactions. So I introduced the electrostatic interface to define a stern layer. And I defined a scan signal (E1) according to your method at the electrostatic interface. But I didnot get the correct CV curves for EDL. And if I defined a periodic scan signal (E2), the errors occured. Are there anything wrong with my settings? And my mph file is attached. Thank you!
Best,
Chi
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Posted:
6 years ago
5 oct. 2018, 01:48 UTC−4
EDL relaxes so fast that - in my opinion - what you need to do is to calculate the electrode capacitance at various potentials (i.e. surface charge). Current during CV is then scan rate*capacitance.
EDL relaxes so fast that - in my opinion - what you need to do is to calculate the electrode capacitance at various potentials (i.e. surface charge). Current during CV is then scan rate*capacitance.