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CHEMICAL BOND  & SPECTROSCOPY I CHM6470

CHEMICAL BOND  & SPECTROSCOPY I CHM6470. Prof. Valeria D. Kleiman  Office 311A CLB  Tel: 392-4656  e-mail: kleiman@chem.ufl.edu. CLASS WEBSITE www.chem.ufl.edu/~kleiman/6470. Meeting time and place MWF 10:40-11:30 am CLB 313.

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CHEMICAL BOND  & SPECTROSCOPY I CHM6470

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  1. CHEMICAL BOND  & SPECTROSCOPY I CHM6470 Prof. Valeria D. Kleiman  Office 311A CLB  Tel: 392-4656  e-mail: kleiman@chem.ufl.edu CLASS WEBSITE www.chem.ufl.edu/~kleiman/6470 Meeting time and place MWF 10:40-11:30 am CLB 313 "Elements of Quantum Mechanics" by Mike Fayer. Oxford University Press    ISBN 0 19 514195 4

  2. Grading • homework (about 10-12) (35%) • 2 progress tests (30%) • term paper (15%) Due November 22nd • biographical paper  (5%) Due October 17th • class participation (15%)

  3. QM Description of the behavior of particles @ the atomic scale Absolute vs Relative size CM: Size is relative  There is always a measurement which produces a disturbance small enough not to change the object QM: Size is absolute  There is a limit to the disturbance used for a measurement. At some point, the object is so small that we cannot measure it without disturbing it!

  4. Experiment with bullets 1 2 Detector moves in x direction Bullets do not break  detector sees always WHOLE bullets. If gun’s firing rate is slower, we detect less WHOLE bullets, but never ½ bullet  Bullets arrive in identical “lumps” Measure the # bullets arriving at x, by unit time  P(x)

  5. Bullets If slit 1 is closed and 2 is open What is the probability that a bullet which passes through the holes 2 will arrive at xn? P2 The max of P2 is aligned with slit 2 1 2 P2

  6. Bullets If slit 2 is closed and 1 is open What is the probability that a bullet which passes through the holes 2 will arrive at xn? P1 The max of P1 is aligned with slit 1 P1 1 2

  7. Bullets P12= P1+P2 1 2 If slit 1 and 2 are open What is the probability that a bullet which passes through either hole 2 will arrive at xn? P12 The max of P12 is aligned in the center P12= P1+P2

  8. Experiment H2O waves Detector measures the height of the wave when it arrives at xn  Intensity = h2 = rate at which energy reaches the detector Intensity can vary CONTINUOUSLY  No “lumps” 1 2

  9. Waves If slit 1 is closed and 2 is open What is the intensity measured at xn? I2 = |h2| 1 2 I2

  10. Waves If slit 2 is closed and 1 is open What is the intensity measured at xn? I1 = |h1| 1 I1 2

  11. Waves xa, in phase Individual peaks add I12  xb out of phase Individual peaks cancel each other I12  I12 I1+I2 If slit 2 and 1 are open What is the intensity measured at xn? 1 2

  12. Waves Interference 1 2

  13. Experiment with electrons 1 2 Source: electron gun, tungsten wire heated by current, wall at – voltage Detector: geiger or e- multiplier connected to a speaker It clicks every time an e- reaches the detector, making a sound

  14. Electrons 1 2 Clicks are not uniformly distributed  “average rate” At different positions, we hear a different rate, but the volume (size) of each click is always the same T  the rate is , but volume is = (same size) T  the rate is , but volume is = (same size) If there are 2 detectors, you never hear 2 clicks at the same time  e- behaves as “lumps” WHOLE e- arrives at the detector

  15. Electrons If slit 2 is open and 1 is closed What is the probability that an e- which passes through hole 2 will arrive at xn? P2 1 2 P2

  16. Electrons If slit 2 is closed and 1 is open What is the probability that an e- which passes through hole 1 will arrive at xn? P1 P1 1 2

  17. Electrons 1 2 INTERFERENCE PATTERN! If both slits are open…

  18. How do we explain the interference? • Possibility 1 • e- do not go through slit 1 or slit 2, but they “split” between the 2 slits • NOT TRUE, e- always arrive in “lumps” (one click, same volume) • Possibility 2 • Closing one slit increases the P of e- going through the other slit • NOT TRUE, at x=0, P1< ½ P12  When we closed 2, P1 did not increased If we recall the math associated with waves, we say that Pe-1= |f1|2Pe-2= |f2|2and Pe-12= |f1+ f2|2 • e-arrive in “lumps” like particles probability of arrival has interference  like waves

  19. Watching electrons We watch the e- by adding a strong light source after they go through the slit Scattered light (flash) above x=0  Slit 1 Scattered light (flash) below x=0  Slit 2 1 2 One click  one flash and One flash one click e- go EITHER through 1 or 2

  20. Watching electrons P1’ P2’ We count : number of e- that went through Slit 1  P1’ (same as P1, when slit 2 is closed) number of e- that went through Slit 2  P2’ (same as P1, when slit 1 is closed) 1 2 When we are “watching”, e- come through just as expected! P12= P1 +P2

  21. Watching electrons P12 P1 +P2 Turn of the light and when we are “ not watching 1 2 light e- interaction changes the motion of the e-

  22. Watching electrons One flash one click but sometimes One click  NO flash light behaves in “lumps” Since watching the e- changes their motion, we try to look with a dim dim dim light source, so the interaction will not disturb the e- motion 1 2 If brightness  , the number of flashes goes  , but if there is a flash, it is always the same

  23. Watching electrons We count : number of e- that went through Slit 1  P1” (same as P1, when slit 2 is closed) number of e- that went through Slit 2  P2” (same as P1, when slit 1 is closed) P1” 1 2 P2”

  24. Watching electrons We count : number of e- that did not give a flash  P”12  INTERFERENCE! 1 2

  25. Watching electrons We can try keeping the brightness constant, changing only the l (longer l smaller momentum  less disturbance? 1 2

  26. Watching electrons We can try keeping the brightness constant, changing only the l (longer l smaller momentum  less disturbance? 1 2 For l ~ xslit 1-xslit 2 the flash becomes LARGE and FUZZY We cannot say whether the flash came from above or below x=0 For l < xslit 1-xslit 2  NO INTERFERENCE For l > xslit 1-xslit 2  INTERFERENCE

  27. Absolute size It is IMPOSSIBLE to design an apparatus to determine through which slit the e- goes THAT WILL NOT at the same time DISTURB the e- enough to DESTROY the INTERFERENCE pattern QM: Size is absolute  There is a limit to the disturbance used for a measurement. At some point, the object is so small that we cannot measure it without disturbing it! If we look, we can say that the e- goes either through 1 or 2 If we don’t look, we may not say that it goes through 1 or 2

  28. Summary • Probability of an event is given by |f|2 where f is a complex number (probability amplitude) • When an experiment can occur in alternative ways  INTERFERENCE f =f1+ f2 P = |f1 + f2|2 • If we determine WHICH pathway was taken  INTERFERENCE IS LOST

  29. Back to bullets 1 2 The associated l is so small, that the interference pattern is smoothed out. The resolution in P12 is not goof enough to see the peaks and valleys Why the bullets did not give interference pattern?

  30. Wave/particles What is the relation between those wave/particle properties? Each particle has an associated l. DeBroglie, (1924) proposed that particles with rest mass have • bullet (0.2 gr 500m/s) ~ 6.626x10-33m To obtain an interference pattern, we would need slits separated by 10-33m h defines the granular composition of our universe

  31. State of a system transmission || No transmission  a • State: a description of a system with as many conditions as theoretically possible without contradictions I transmitted = I || = Io I transmitted = I  = 0 I transmitted = Io cos2a

  32. Light as particles how much P|| or P is contained in Pa If we can measure 1 photon at the time: Input photon is polarized ||  light is transmitted, and output is || Input photon is polarized  light is NOT transmitted Input photon is polarized with angle a???? Observation: Sometimes the WHOLE photon is transmitted, and it is //polarized Sometimes nothing is transmitted Question: Is the photon jumping between polarizations? Answer: Superposition of states Any polarization Pa can be expressed as a superposition of 2 perpendicular states

  33. Projection When photons are observed, they are “forced”to be in either || or  polarization If we look, we can say that the photon is either|| or  If we don’t look, we may not say that it is || or  Each individual observation will be either || or , but after many observations, cos2a of those measurement will be || a is a state of polarization, which can also be described as sum of 2 other states (|| and )

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