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+ current, cathodic ic + potential, V - potential, V - current, anodic

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Presentation on theme: "+ current, cathodic ic + potential, V - potential, V - current, anodic"— Presentation transcript:

1 + current, cathodic ic + potential, V - potential, V - current, anodic ia

2 + current, cathodic ic Reduction + potential, V - potential, V Oxidation - current, anodic ia

3 + current, cathodic ic When no electroactive species is present,
no current flows, no ic nor ia This is what background electrolyte should look like. + V - V +1.0 V -1.0 V - current, anodic ia

4 Initially no current flows
+ current, cathodic ic Starting at a + V, Initially no current flows + V - V +1.0 V -1.0 V - current, anodic ia

5 is present ic will increase + current, cathodic ic
If a reducible species is present ic will increase + current, cathodic ic + V - V +1.0 V -1.0 V - current, anodic ia

6 And continue to increase + current, cathodic ic
+ V - V +1.0 V -1.0 V - current, anodic ia

7 Until all of the species is reduced. ic has reached a maximum.
+ current, cathodic ic + V - V +1.0 V -1.0 V - current, anodic ia

8 Then ic decreases until… + current, cathodic ic
+ V - V +1.0 V -1.0 V - current, anodic ia

9 background current level. + current, cathodic ic
It again reaches the background current level. + current, cathodic ic + V - V +1.0 V -1.0 V - current, anodic ia

10 Now the potential is reversed + current, cathodic ic
- current, anodic ia

11 And as V is more positive, The reduced species can be Re-oxidixed
+ current, cathodic ic + V - V +1.0 V -1.0 V - current, anodic ia

12 So ia decreases to a maximum + current, cathodic ic
+ V - V +1.0 V -1.0 V - current, anodic ia

13 Where all has been oxidized, + current, cathodic ic
+ V - V +1.0 V -1.0 V - current, anodic ia

14 Then ia decreases, back to the background level. + current, cathodic
- current, anodic ia

15 Important features: + current, cathodic ic +1.0 V -1.0 V
Ec + V - V +1.0 V -1.0 V - current, anodic ia Ea

16 + current, cathodic ic E1/2 is ~ EoRed +1.0 V -1.0 V - current, anodic
Ec E1/2 is ~ EoRed E1/2 + V - V +1.0 V -1.0 V - current, anodic ia Ea

17 + current, cathodic ic Using an Fe(3+) heme, Fe is electroactive,
(and also the heme!) … All Fe(3+) + V - V +1.0 V -1.0 V - current, anodic ia

18 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
A little Fe(2+) formed + V - V +1.0 V -1.0 V - current, anodic ia

19 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
more Fe(2+) formed + V - V +1.0 V -1.0 V - current, anodic ia

20 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
Largest cathodic current, Max rate of Fe(2+) formed + V - V +1.0 V -1.0 V - current, anodic ia

21 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
Little Fe(3+) left; Less Fe(2+) forms; Decrease in ic + V - V +1.0 V -1.0 V - current, anodic ia

22 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
all Fe(2+) now + V - V +1.0 V -1.0 V - current, anodic ia

23 + current, cathodic ic + V - V +1.0 V -1.0 V - current, anodic ia

24 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
A little Fe(2+) is re-oxidized to Fe(3+) +1.0 V -1.0 V - current, anodic ia

25 + current, cathodic ic + V - V +1.0 V -1.0 V - current, anodic ia

26 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
Nearly all Fe(2+) has been oxized - current, anodic ia

27 + current, cathodic ic +1.0 V -1.0 V - current, anodic ia
All back to Fe(3+). Cycle could be run again, many times. - current, anodic ia

28 Important features: + current, cathodic ic +1.0 V -1.0 V
Ec + V - V +1.0 V -1.0 V - current, anodic ia Ea

29 E1/2 for Fe(3+/2+) reduction
+ current, cathodic ic Ec E1/2 for Fe(3+/2+) reduction E1/2 + V - V +1.0 V -1.0 V - current, anodic ia Ea

30 the black box Working Electrode:
Where the redox reaction action occurs

31 the black box Working Electrode:
Where the redox reaction action occurs Reference Electrode: Defines “0” potential for the cell. We use Ag/AgCl

32 the black box Working Electrode:
Where the redox reaction action occurs Auxilliary Electrode: Needed to complete circuit. We use a Pt wire Reference Electrode:

33 At start of CV experiment…
the black box Working Electrode: Where the redox reaction action occurs Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) At start of CV experiment…

34 Moving up the cathodic current peak…
black box Working Electrode: Where the redox reaction action occurs Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Moving up the cathodic current peak…

35 Still moving up the cathodic current peak…
black box Working Electrode: Where the redox reaction action occurs Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Still moving up the cathodic current peak…

36 After the maximum cathodic current peak…
black box Working Electrode: Where the redox reaction action occurs Fe(2+) Fe(2+) Fe(3+) Fe(3+) Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) After the maximum cathodic current peak…

37 Moving down the anodic current peak…
black box Working Electrode: Where the redox reaction action occurs Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Moving down the anodic current peak…

38 Sill moving down the anodic current peak…
black box Working Electrode: Where the redox reaction action occurs Fe(2+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Sill moving down the anodic current peak…

39 At end of CV experiment…
the black box Working Electrode: Where the redox reaction action occurs Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) Fe(3+) At end of CV experiment…

40 In your CV scans of Fe(porphyrin)Cl, you will see: + ic - V + V Interpretation???? - ia

41 How is the range of Heme Potentials
in Respiration adjusted?

42 The Question asked: Can changing Heme substituents vary Fe(3+/2+) redcution potentials?

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