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Time dispersion in quantum mechanics

Time dispersion in quantum mechanics. John Ashmead. Quantum mechanics: space is fuzzy, particles do not have a well-defined position in space. Special relativity: time and space are interchangeable. Therefore, should time should be fuzzy as well?. problem clock in a box paths slits

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Time dispersion in quantum mechanics

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  1. Time dispersion in quantum mechanics John Ashmead Quantum mechanics: space is fuzzy, particles do not have a well-defined position in space. Special relativity: time and space are interchangeable. Therefore, should time should be fuzzy as well?

  2. problem clock in a box paths slits but wait there’s more … IS Time Fuzzy? Arrival in 33 slides

  3. Without including relativistic effects, errors of 11km/day! Slowing due to relativistic speed: -1x10-10 Speed up due to blueshift: +5x10-10 Sagnac effect: due to rotating Earth Relativity & the GPS Neil Ashby. Physics Today 2002 May 41-47

  4. accelerated electron radiates once its energy is gone, it spirals into the nucleus maybe 10-14 seconds Life span of an atom

  5. Hi Ya Goldilocks! Δp large Δp medium Δp small Δr large poten Δr medium poten Δr small poten Uncertainty & atoms

  6. Near a black hole, time is stretched At Schwarzschild radius, time and space (seem to) exchange roles Perhaps time stretches out to infinite future? Black Hole poses for photo — and about time!

  7. Minkowski diagram

  8. now have the uncertainty in time now weight the box — exactly Einstein: Violates ΔΕΔt≥1 Einstein’s clock in a box

  9. Bohr’s response • To measure energy ΔΕ we add a test weight Δm over a time T • Implies uncertainty Δpz ≤ gΔmT • Implies Δz ≥1/gΔmT • Implies red shift (Δt/T)=g Δz. • Implies Δt=gT Δz ≥1/Δm • Bohr: Implies ΔΕΔt≥1

  10. Radical Conservatism “Wheeler’s often unconventional vision of nature was grounded in reality through the principle of radical conservatism, which he acquired from Niels Bohr: Be conservativeby sticking to well-established physical principles, but probe them by exposing their most radical conclusions.” – Kip Thorne

  11. show ellipsoid, then fuzzball Here come the Fuzz

  12. Too small to see, i.e. Planck time Too big, we would already have seen. Time of milliseconds, even micro seconds, would have been seen. Size so tiny we can’t see in foreseeable future! First, prove Yourself Wrong! Hi Ya Goldilocks! Size so large we should have seen already! What is the estimated size of the effects? Hello, Goldilocks!

  13. In comes a photon, traveling at c = 3x108m/sec Bohr radius of atom is a0=5x10-11m That works out to .2 attoseconds 1 attosecond = 10-18 seconds But Ossiander et al (2016) did experiment at .025 attoseconds! Bohr Radius in Time a0=5x10-11m

  14. Nicolas Gisin something I can prove wrong Look, I don’t care what your theory of time is. Just give me something I can prove wrong

  15. Alice walks her dog from A to B She takes one path Her dog can take many paths And being a quantum dog, takes all at once In space: left & right, forwards & backwards. And in time? What are path integrals?

  16. Paths in time as well as space Paths Paths in space only

  17. Hi Ya Goldilocks! Balancing Act Kinetic energy (fast moving, close to nucleus) Potential energy (slow moving, far from nucleus)

  18. lines with fuzz The river valley Space Time Space

  19. Simple and complex Paths • Straight • Early & from behind • Back from future • Back from future and behind Time Space

  20. Time-of-Arrival • slow train arrives at the station with wide dispersion in time • so adding a bit of “width in time” to each car doesn’t have much effect

  21. Single Slit/Bullets

  22. Single Slit/Waves

  23. QM waves are complex And we are using a finite slit So actual pattern is much “wavier” Single Slit/Quantum Mechanics

  24. No uncertainty principle in time/energy Fast shutter constricts gate Arbitrarily small dispersion Single slit in Standard QM (SQM)

  25. Uncertainty principle in time/energy Diffraction Arbitrarily large dispersion Falsifiable Single slit in QM with Time (TQM)

  26. Same basic approach (more math) Lets us look at high energies And more complicated (& interesting) experiments And, make sure this makes sense Two (or more) Particles

  27. Tinkertoy Arbitrarily complex Anchor for calculations Feynman diagrams

  28. small effect but lots of possibilities like being eaten by mice Advanced Loopiness

  29. How to weigh a mouse • show loop/aircraft carrier/loop

  30. opening wave function is limited in time entangled with next and with next chain keeps loop integral finite bridge of mice Advanced Loopiness II

  31. Consistent: effects usually at scale of attoseconds Falsifiable: no free parameters, large enough to measure. Simple: complete symmetry between time and space, measure mice without use of aircraft carriers Scope: any quantum experiment varying at time scale of attoseconds Fruitful: lots of experiments, lots of interesting tech, no null experiments. How to think about Weird things

  32. Uses • Quantum gravity without costs & risks of black holes • New communication channels, new circuit elements, as memristors • Attosecond chemistry; attoseconds are the time scale for electron/molecule interactions • Attosecond biology; better understanding of DNA, protein formation, … • Let’s take a flyer on the future; you never know where the lightning will strike!

  33. Gisin - Quantum Chance Carroll - From Here to Eternity Susskind & Friedman - Quantum Mechanics Clegg et al - 30-second Quantum Theory Halpern - Quantum Labyrinth Ashmead - Time dispersion in quantum mechanics - (2019 J. Phys.: Conf. Ser. 1239 012015) References 2019 J. Phys.: Conf. Ser. 1239 012015   https://doi.org/10.1088/1742-6596/1239/1/012015

  34. IS Time Fuzzy? Is time fuzzy? We still don’t know,…but we can find out. Thanks! • Ferne Welch • Jonathan Smith • Nicolas Gisin — for the goal! • IARD: especially Martin Land & Larry Horwitz • Balticon 2019 & Miriam Kelly • And you! Arrival in 33 slides Destination in Zero Slides

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