1.
CH3I summary
This file includes some ideas about dissociation of
CH3I inside a cluster, as suggested previously by Petros
It seems to be the only explanation of the very fast iodine
Updated: (i.e. from , „Re: CH3I experiments and analysis;UPDATES”
Prediction calc:

2. Transition 1: CH3 (set 1 and set 2)
20 and , CH3I at nm, CH3 fragments

3. Transition 1: CH2 (set 1, space charge)
, CH3I at nm, CH2 fragments

4. Transition 1: CH2 (set 2)
, CH3I at nm, CH2 fragments

5. Transition 1: CH2 (set 3)
, CH3I at nm, CH2 fragments

6. Transition 1: Iodine (set 2, irises low) and Iodine (set 3)
, CH3I at nm, I fragments, irises low and

7. Transition 1: photoelectrons
, CH3I at nm, photoelectrons

8. Off resonance and Transition 1: CH3

9. Off resonance and Transition 1: iodine

10. Off resonance and Transition 1: photoelectrons

11. Transition 2: CH3 (set 1, VMI), CH3 (set 2, space charge) and CH3 (set 3, space charge)
20 and , CH3I at nm, CH3 fragments

12. Transition 2: CH3 (set 4) and CH3 (set 2, space charge)
and , CH3I at nm, CH3 fragments

13. Transition 2: CH2 (set 2) and CH3 (set 1, space charge)
and , CH3I at nm, CH2 fragments

14. 2
, CH3I at nm, I

15. 2 (MOPO)
CH3I_ nm photoelectrons

16. 2 (dye laser)
9(10), 15 are the strongest
CH3I_ nm photoelectrons

17. 3
, CH3I at nm, CH3 fragments

18. 3
02 and , CH3I at nm, CH3 fragments

19. 3
, CH3I at nm, I fragments

20. 3
9(10), 15 are the strongest
, CH3I at nm, photoelectrons

21. 4 a
x KER’s, only 3 was recorded at 13-10
, CH3I at nm, CH3 fragments

22. 4 a
z KER’s
, CH3I at nm, CH3 fragments

23. 4 a
, CH3I at nm, I fragments

24. 4 a
9(10), 15, I*+3hv=I+
, CH3I at nm, photoelectrons

25. 4 b
, CH3I at nm, CH3 fragments

26. 4 b
, CH3I at nm, I fragments

27. 4 b
9(10), 12 are the strongest
, CH3I at nm, photoelectrons

28. 4 c
Channels 7 and 8
, CH3I at nm, CH3 fragments

29. 4 c

30. 4 c
, CH3I at nm, photoelectrons

31. 6
, CH3I at nm, CH3

32. 6
, CH3I at nm, I

33. 6
, CH3I at nm, photoelectrons

34. 6 (set2)
3.187E-5
, CH3I at nm, photoelectrons

35. 7
, CH3I at nm, CH3 fragments

36. 7
, CH3I at nm, I fragments

37. 7
, CH3I at nm, photoelectrons

38. 8
, CH3I at nm, CH3

39. 8
, CH3I at nm, I fragments

40. 8
, CH3I at nm, I fragments

41. 8
, CH3I at nm, photoelectrons

42. 9
, CH3I at nm, I fragments

43. 9
, CH3I at nm, photoelectrons

44. 9 (set 2)
, CH3I at nm, photoelectrons

45. 9 (set 3)
, CH3I at nm, photoelectrons

46. 9a
, CH3I at nm, CH3

47. 9a
, CH3I at nm, I

48. 9a
, CH3I at nm, photoelectrons

49. Transition 10: CH3 (no signal)
, CH3I at nm, CH3

50. Transition 10: iodine
, CH3I at nm, iodine

51. Transition 10: photoelectrons
, CH3I at nm, photoelectrons

52. Transition 11: CH3 (set 1, VMI)
, CH3I at nm, CH3

53. Transition 11: CH3 (set 2)
, CH3I at nm, CH3

54. 11
, CH3I at nm, I

55. 11
, CH3I at nm, photoelectrons

56. 12
, CH3I at nm, CH3 fragments

57. Off resonance and 12
, CH3I at nm, I fragments and , CH3I at nm

58. 22-09-2017, CH3I at 286.586 nm, photoelectrons12
Difference between peaks ~0.17 eV
OPLA vibrations of CH3 (3p 2A2), 1323 cm-1 or
Def. vibrations of CH3 (X), 1402 cm-1
, CH3I at nm, photoelectrons

59. Off resonance
, CH3I at nm, CH3

60. Off resonance
, CH3I at nm, photoelectrons

61. Off resonance
, CH3I at nm, photoelectrons