SLIDES
Slide files are .pdf, unless explicitly identified as .ppt
Talks require 30 minutes, unless (20 minutes) mentioned explicitly.
Any talk can last 60 minutes, or an arbitrarily long time.

TURNAROUND IN CYCLIC COSMOLOGY (20 minutes)
1-3. title. outline. 4-10. Historical context. 11-19. Vanishing entropy of contraction.
20-33. Constraints on deflation. 34-47. Multifluid models. 48-49. Summary.

STUDIES IN NEUTRINO MASSES AND MIXING
1-2. title. outline. 3-25. Zee model. 26-39. Two zero textures.
40-52. FGY model. 53. summary.

RELATIONS BETWEEN STANDARD MODEL PARAMETERS FROM T' SYMMETRY
1-2. title. outline. 3. References. 4-5. Historical context. 6-12. Neutrino mixing. 13-14.Tetrahedral T.
15-18. Binary tetrahedral T'. 19-32. T' as flavor symmetry: A Model.
33-35. Formulas relating standard model parameters. 36. Summary.

ENTROPY AND INTERMEDIATE MASS BLACK HOLES IN HALOS
1-2 title. outline 3. references. 4-7. entropy of the universe.
8-12. upper limit on gravitational entropy. 13-14 lower limit on gravitational entropy.
15-31. most likely value of entropy. 32-35 intermediate comments. 36-41. intermediate mass black holes (IMBHs).
42-43. Cosmological entropy considerations. 44-47. Observation of IMBHs. 48. summary.

BINARY TETRAHEDRAL GROUP (T') AND CABIBBO ANGLE
1. Title. 2. Outline. 3. References. 4-7. Introduction on renormalizability.
8-13. $A\_4$ symmetry. 14-21. Minimal A_4 model. 22-23. T' symmetry.
24-26. Minimal T' model. 27-31. Cabibbo angle. 32-34. Higgs boson decay.
35-42. Neutrino mixing angles. 43-44. Summary.

PHENOMENOLOGY BEYOND THE STANDARD MODEL
1-2. title. outline. 3-16. quiver theory. 17-28. conformality phenomenology.
29-48. 4TeV unification. 49-64. quadratic divergences.
65-77. anomalies for U(1)s. 78-88. Dark matter. 89.summary.

QUIVER GAUGE THORY AND CONFORMALITY AT TeV SCALE (20 minutes)
1-7,10-13,15-17,20-22,27,29,32-34,40-41,45-46,48-49,
52-53,55-56,58-60,65-69,71-72,74-75,78-79,81,87-89.  subset of previous talk.

BLACK HOLES AS DARK MATTER
1-2 title. outline 3. references. 4-7. entropy of the universe.
8-12. upper limit on gravitational entropy. 13-14 lower limit on gravitational entropy.
15-31. most likely value of entropy. 32-35 intermediate comments. 36-41. intermediate mass black holes (IMBHs).
42-43. Cosmological entropy considerations. 44-47. Observation of IMBHs. 48. summary.

BINARY TETRAHEDRAL GROUP AND PREDICTIONS FOR PMNS AND KM ANGLES
1. Title. 2. Outline. 3. References. 4-7. Introduction on renormalizability.
8-13. $A\_4$ symmetry. 14-21. Minimal A_4 model. 22-23. T' symmetry.
24-26. Minimal T' model. 27-31. Cabibbo angle. 32-34. Higgs boson decay.
35-42. Neutrino mixing angles. 43-44. Summary.

CYCLIC COSMOLOGY AND INFINITE PAST
1. Title. 2. Outline. 3. References. 4-10. Historical context.
11-15. Expansion phase. 16-23. Turnaround. 24-28. Contraction phase.
29-30. Bounce. 31-39. Entropy. 40-46. Vanishing entropy of contracting universe.
47-61. Infinite past. 62-64. Summary.

AXIGLUON AS EXPLANATION OF TOP ASYMMETRY IN P-PBAR COLLISIONS
1. Title. 2. Contents. 3. References. 4-10. Introduction.
11-15. Chiral Color with Flavor Nonuniversality. 16-18. Forward-Backward Asymmetry.
19-25. Numerical results. 26-29. Discussion.

PRIMORDIAL BLACK HOLES AS ALL DARK MATTER
1. Title. 2. Outline. 3. References. 4-7. Entropy of the Universe.
8-13. Intermediate-Mass Black Holes (IMBHs). 14-15.Cosmological Entropy Considerations.
16-20. Observation of IMBHs. 21-38. Formation of Black Holes. 39-40. Summary.

DID TIME BEGIN? WILL TIME END?           Alternative powerpoint version: ppt
Preamble (3 slides).
1. Why do Many Other Scientists Believe Time Began at a Big Bang?
1'.  Four pictures, Gerard 't Hooft.
2. Smoothness of the Universe.
3. Structure in the Universe.
4. Dark Matter and Dark Energy.
4'.  Four pictures, Nambu sensei.
5. Composition of the Universe's Energy.
5'.  Four pictures, Yang Zhenning.
6. Possible Futures of the Universe.
7. Advantages of Cyclic Cosmology.
8. Summary of Answers to the Questions: Did Time Begin? Will Time End?
Postamble (3 slides).     Total = 26 slides.

HOLOGRAPHIC PRINCIPLE AND THE SURFACE OF LAST SCATTER.
1. Title. 2. Outline. 3. References. 4-9. Accelerating expansion.
10-15. Dark energy problem. 16-21. Emergent gravity.
22-24. Holographic principle. 25-31. Observable Universe.

HUNTING FOR NEW PHYSICS WITH UNITARITY BOOMERANGS
1. Title. 2. Outline. 3. References. 4-7. Introduction.
8-15. Unitarity Boomerang. 16-22. Kobayashi-Maskawa parametrization.
23-27. Diminution of Errors. 28-39. Optimal Boomerang,
40-43. CP Violation. 44-48. Hunting for New Physics.

DISCUSSION OF COSMIC ACCELERATION
1. Title. 2. Outline. 3. References.
4-9. Accelerating Expansion. 10-15. Dark Energy Problem.
16-21. Emergent Gravity. 21-24. Holographic Principle.
25-31. Observable Universe. 32-37. Plots of Z*.

SEEKING EVOLUTION OF DARK ENERGY
1. Title. 2. Outline. 3. Reference. 4-9. Introduction.
10-14. Evolutionary Dark Energy Models.
15-21. Analysis of the Models. 22-26. Slowly Varying Criteria.
27-31. Discussion and Conclusions. 32-34. Figures (five).

THE LITTLE RIP
1. Title. 2. Outline. 3. References. 4-6. Introduction
7-16. The conditions for a futute singularity.
17-20. Little rip models. 21-23. Disintegration.
24-26. Discussion.


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