
Use the python script and the information below to visualize the Faradaic efficiencies. It should look something like the example plot (THE EXAMPLE PLOT DOES NOT USE YOUR DATA, you have to plot it yourself, let me know if you have any issues).
In your report, use RHE potential, and explain (e.g. in the method section) what you actually measured and how to convert it. In general, describe every step and explain. 



OPTIONAL AND ONLY after you did the rest of the final report:
- If you want and it helps your report, you can use the LSVs in your analysis
- If you are interested in electrochemical surface area, the CVs are for measuring the anodic and cathodic currents at different scan speeds. If you plot the maximum current difference at any potential between anodic and cathodic scan against the scan speed, the slope indicates the capacitance. I did that for you and added the resulting plot to your data. Dividing by the capacitance of the glassy carbon (which you find below) gives an indication of surface area. Comparing this to the geometric area and discussing it, could be interesting. HOWEVER, you need an extensive discussion, especially with data that does not fully match the expectation/model ... I highly recommend you only look at this if you have a lot of time left. 



EXPERIMENTAL INFO:
Sample: 			GroupA cubes	

Ref drift: 			160 mV 
Ref drifts used:		130 mV <-- used for echem
Ref drift after Exp:		126 mV

capacitance of glassy carb.:	GC1 = (19.0+-1.9) uF/cm2
geometric area:			1.33 cm2

Voltage RHE			-1.2 V
Voltage Ref			-1.2 V - 0.606 V - 0.130 = -1.936 V

Duration CA: 			1 h

Electrolyte: 			0.1 M KHCO3
Electrolyte amount:		4 ml

Loading: 			15 ug

impedance Ru:			83 ohm

flow: 	start	1h		
	5.1	5.0		

collected volume electrolyte: 4 ml







