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Dark Energy: current theoretical issues and progress toward future experiments A. Albrecht

Dark Energy: current theoretical issues and progress toward future experiments A. Albrecht UC Davis PHY 262 (addapted from: Colloquium at University of Florida Gainesville January 15 2009).

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Dark Energy: current theoretical issues and progress toward future experiments A. Albrecht

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  1. Dark Energy: current theoretical issues and progress toward future experiments A. Albrecht UC Davis PHY 262 (addapted from: Colloquium at University of Florida Gainesville January 15 2009)

  2. 95% of the cosmic matter/energy is a mystery. It has never been observed even in our best laboratories Ordinary Matter (observed in labs) Dark Matter (Gravitating) Dark Energy (accelerating)

  3. American Association for the Advancement of Science

  4. American Association for the Advancement of Science …at the moment, the nature of dark energy is arguably the murkiest question in physics--and the one that, when answered, may shed the most light.

  5. “Basically, people don’t have a clue as to how to solve this problem.” - Jeff Harvey “Right now, not only for cosmology but for elementary particle theory, this is the bone in our throat.” - Steven Weinberg “… would be No. 1 on my list of things to figure out.” - Edward Witten ‘This is the biggest embarrassment in theoretical physics” - Michael Turner “… Maybe the most fundamentally mysterious thing in basic science.” - Frank Wilczek

  6. QUANTUM UNIVERSE THE REVOLUTION IN 21ST CENTURY PARTICLE PHYSICS

  7. Questions that describe the current excitement and promise of particle physics. 2HOW CAN WE SOLVE THE MYSTERY OF DARK ENERGY? QUANTUM UNIVERSE THE REVOLUTION IN 21ST CENTURY PARTICLE PHYSICS

  8. “Most experts believe that nothing short of a revolution in our understanding of fundamental physics will be required to achieve a full understanding of the cosmic acceleration.” Dark Energy Task Force (DETF) astro-ph/0609591

  9. “Of all the challenges in cosmology, the discovery of dark energy poses the greatest challenge for physics because there is no plausible or natural explanation…” ESA Peacock report

  10. 2008 US Particle Physics Project Prioritization Panel report Dark Energy

  11. 2008 US Particle Physics Project Prioritization Panel report Dark Energy

  12. 2008 US Particle Physics Project Prioritization Panel report LSST JDEM Dark Energy

  13. (EPP 2010) ASPERA roadmap BPAC Q2C

  14. (EPP 2010) ASPERA roadmap BPAC Q2C

  15. ?

  16. Cosmic acceleration Accelerating matter is required to fit current data Preferred by data c. 2003  Amount of w=-1 matter (“Dark energy”) “Ordinary” non accelerating matter Supernova  Amount of “ordinary” gravitating matter (Includes Dark Matter)

  17. Cosmic acceleration Accelerating matter is required to fit current data Preferred by data c. 2003  Amount of w=-1 matter (“Dark energy”) “Ordinary” non accelerating matter Supernova  Amount of “ordinary” gravitating matter (Includes Dark Matter)

  18. Cosmic acceleration Accelerating matter is required to fit current data Kowalski, et al., Ap.J.. (2008) Preferred by data c. 2008  Amount of w=-1 matter (“Dark energy”) “Ordinary” non accelerating matter BAO  Amount of “ordinary” gravitating matter (Includes Dark Matter)

  19. Cosmic acceleration Accelerating matter is required to fit current data Suzuki, et al., Ap.J.. (2011) Preferred by data c. 2011  Amount of w=-1 matter (“Dark energy”) “Ordinary” non accelerating matter BAO  Amount of “ordinary” gravitating matter (Includes Dark Matter)

  20. Dark energy appears to be the dominant component of the physical Universe, yet there is no persuasive theoretical explanation. The acceleration of the Universe is, along with dark matter, the observed phenomenon which most directly demonstrates that our fundamental theories of particles and gravity are either incorrect or incomplete. Most experts believe that nothing short of a revolution in our understanding of fundamental physics* will be required to achieve a full understanding of the cosmic acceleration. For these reasons, the nature of dark energy ranks among the very most compelling of all outstanding problems in physical science. These circumstances demand an ambitious observational program to determine the dark energy properties as well as possible. • From the Dark Energy Task Force report (2006) • www.nsf.gov/mps/ast/detf.jsp, • astro-ph/0690591 *My emphasis

  21. Dark energy appears to be the dominant component of the physical Universe, yet there is no persuasive theoretical explanation. The acceleration of the Universe is, along with dark matter, the observed phenomenon which most directly demonstrates that our fundamental theories of particles and gravity are either incorrect or incomplete. Most experts believe that nothing short of a revolution in our understanding of fundamental physics* will be required to achieve a full understanding of the cosmic acceleration. For these reasons, the nature of dark energy ranks among the very most compelling of all outstanding problems in physical science. These circumstances demand an ambitious observational program to determine the dark energy properties as well as possible. • From the Dark Energy Task Force report (2006) • www.nsf.gov/mps/ast/detf.jsp, • astro-ph/0690591 DETF = a HEPAP/AAAC subpanel to guide planning of future dark energy experiments *My emphasis More info here

  22. This talk • Part 1: • A few attempts to explain dark energy •  Motivations, problems and other comments •  Theme: We may not know where this revolution is taking us, but it is already underway: • Part 2 • Planning new experiments • - DETF • - Next questions

  23. Some general issues: Properties: Solve GR for the scale factor a of the Universe (a=1 today): • Positive acceleration clearly requires • (unlike any known constituent of the Universe) or • a non-zero cosmological constant or • an alteration to General Relativity.

  24. Some general issues: Numbers: • Today, • Many field models require a particle mass of from

  25. Some general issues: Numbers: • Today, • Many field models require a particle mass of from Where do these come from and how are they protected from quantum corrections?

  26. Two “familiar” ways to achieve acceleration: 1) Einstein’s cosmological constant and relatives 2) Whatever drove inflation: Dynamical, Scalar field? Some general issues: Properties: Solve GR for the scale factor a of the Universe (a=1 today): • Positive acceleration clearly requires • (unlike any known constituent of the Universe) or • a non-zero cosmological constant or • an alteration to General Relativity.

  27. Some general issues: Properties: Solve GR for the scale factor a of the Universe (a=1 today): • Positive acceleration clearly requires • (unlike any known constituent of the Universe) or • a non-zero cosmological constant or • an alteration to General Relativity.

  28. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • Vacuum energy problem (we’ve gotten “nowhere” with this)  = 10120 Vacuum Fluctuations   0 ?

  29. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • The string theory landscape (a radically different idea of what we mean by a fundamental theory)

  30. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • The string theory landscape (a radically different idea of what we mean by a fundamental theory) “Theory of Everything” “Theory of Anything” ?

  31. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • The string theory landscape (a radically different idea of what we mean by a fundamental theory) Not exactly a cosmological constant

  32. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy Banks, Fischler, Susskind, AA & Sorbo etc

  33. “De Sitter Space: The ultimate equilibrium for the universe? Horizon Quantum effects: Hawking Temperature

  34. “De Sitter Space: The ultimate equilibrium for the universe? Horizon Quantum effects: Hawking Temperature Does this imply (via “ “) a finite Hilbert space for physics? Banks, Fischler

  35. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy  Equilibrium Cosmology Rare Fluctuation Dyson, Kleban & Susskind; AA & Sorbo etc

  36. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy  Equilibrium Cosmology Rare Fluctuation “Boltzmann’s Brain” ? Dyson, Kleban & Susskind; AA & Sorbo etc

  37. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy  Equilibrium Cosmology Rare Fluctuation This picture is in deep conflict with observation Dyson, Kleban & Susskind; AA & Sorbo etc

  38. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy  Equilibrium Cosmology Rare Fluctuation This picture is in deep conflict with observation (resolved by landscape?) Dyson, Kleban & Susskind; AA & Sorbo etc

  39. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy  Equilibrium Cosmology Rare Fluctuation This picture forms a nice foundation for inflationary cosmology Dyson, Kleban & Susskind; AA & Sorbo etc

  40. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics • De Sitter limit: Horizon  Finite Entropy  Equilibrium Cosmology Rare Fluctuation Perhaps saved from this discussion by instability of De Sitter space (Woodard et al) Dyson, Kleban & Susskind; AA & Sorbo etc

  41. Specific ideas: i) A cosmological constant • Nice “textbook” solutions BUT • Deep problems/impacts re fundamental physics is not the “simple option”

  42. Some general issues: Alternative Explanations?: Is there a less dramatic explanation of the data?

  43. Some general issues: Alternative Explanations?: Is there a less dramatic explanation of the data? • For example is supernova dimming due to • dust? (Aguirre) • γ-axion interactions? (Csaki et al) • Evolution of SN properties? (Drell et al) Many of these are under increasing pressure from data, but such skepticism is critically important.

  44. Some general issues: Alternative Explanations?: Is there a less dramatic explanation of the data? • Or perhaps • Nonlocal gravity from loop corrections (Woodard & Deser) • Misinterpretation of a genuinely inhomogeneous universe (ie. Kolb and collaborators)

  45. Specific ideas: ii) A scalar field (“Quintessence”) • Recycle inflation ideas (resurrect dream?) • Serious unresolved problems • Explaining/ protecting • 5th force problem • Vacuum energy problem • What is the Q field? (inherited from inflation) • Why now? (Often not a separate problem)

  46. Specific ideas: ii) A scalar field (“Quintessence”) Inspired by • Recycle inflation ideas (resurrect dream?) • Serious unresolved problems • Explaining/ protecting • 5th force problem • Vacuum energy problem • What is the Q field? (inherited from inflation) • Why now? (Often not a separate problem)

  47. Specific ideas: ii) A scalar field (“Quintessence”) Result? • Recycle inflation ideas (resurrect dream?) • Serious unresolved problems • Explaining/ protecting • 5th force problem • Vacuum energy problem • What is the Q field? (inherited from inflation) • Why now? (Often not a separate problem)

  48. Learned from inflation: A slowly rolling (nearly) homogeneous scalar field can accelerate the universe V

  49. Learned from inflation: A slowly rolling (nearly) homogeneous scalar field can accelerate the universe Dynamical V

  50. Learned from inflation: A slowly rolling (nearly) homogeneous scalar field can accelerate the universe Dynamical V Rolling scalar field dark energy is called “quintessence”

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