Out-of-this-World Physics: From Particles to Black Holes

1. Out-of-this-World Physics: From Particles to Black Holes Greg Landsberg L.G.Landsberg SymposiumDecember 19, 2005

2. Outline • A Word on Hierarchies • Standard Model: Beauty and the Beast • How to Make Gravity Strong? • Looking for Extra Dimensions… • Production of Black Holes at Colliders Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

3. N.B. Large Hierarchies Tend to Collapse... Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

4. Hierarchy of the Standard Model Beauty … and the Beast RGE evolution Gravitational Force EM/Hypercharge Force Inverse Strength Weak Force Strong Force MPl MGUT vev 102 1019 1016 E [GeV] Extra dimensions might get rid of the beast while preserving the beauty! Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

5. But Keep in Mind… • Fine tuning (required to keep a large hierarchy stable) exists in Nature: • Solar eclipse: angular size of the sun is the same as the angular size of the moon within 2.5% (pure coincidence!) • Politics:Florida recount, 2,913,321/2,913,144= 1.000061 • Numerology: 987654321/123456789 = 8.000000073 (HW Assignment: is it really numerology?) • But: beware the anthropic principle • Properties of the universe are special because we exist in it • Don’t give up science for philosophy: so far we have been able to explain how the universe works entirely by science Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

6. Math Meets Physics • Math physics: some dimensionalities are quite special • Example: Laplace equation in two dimensions has a logarithmic solution; for any higher number of dimensions it obeys the power law • Some of these peculiarities exhibit themselves in condensed matter physics, e.g. diffusion equation solution allows for long-range correlations in 2D-systems (cf. flocking) • Modern view in topology: one dimension is trivial; two and three spatial dimensions are special (properties are defined by the topology); any higher number is not • Do we live in a special space, or only believe that we are special? Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

7. SM fields are localized on the (3+1)-brane; gravity is the only force that “feels” the bulk space What about Newton’s law? Ruled out for infinite extra dimensions, but does not apply for sufficiently small compact ones The ADD Model Gravity is fundamentally strong force, bit we do not feel that as it is diluted by the volume of the bulk G’N = 1/MD2; MD  1 TeV More precisely, from Gauss’s law: Amazing as it is, but no one has tested Newton’s law to distances less than  1mm (as of 1998) Thus, the fundamental Planck scale could be as low as 1 TeV for n > 1 Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

8. Longitudinal ED Gravitational Force Real GUT Scale Inverse Strength EM/Hypercharge Force Virtual Image Weak Force MPl=1/GN Strong Force L ~ 1 TeV M’Pl MZ MS M’GUT MGUT logE • Simultaneously, another idea has appeared: • Explore modification of the RGE in (4+n)-dimensions to achieve low-energy unification of the gauge forces[Dienes, Dudas, Gherghetta, PL B436, 55 (1998)] • To achieve that, allow gauge bosons (g, g, W, and Z) to propagate in an extra dimension, which is “longitudinal” to the SM brane and compactified on a “natural” EW scale: R ~ 1 TeV-1 Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

9. Randall-Sundrum Scenario x5 SM brane r AdS5 f k: AdS curvature SM brane(f = p) Planck brane (f = 0) Reduced Planck mass: • Randall-Sundrum (RS) scenario[PRL 83, 3370 (1999); PRL 83, 4690 (1999)] • + brane – no low energy effects • +– branes – TeV Kaluza-Klein modes of graviton • Low energy effects on SM brane are given by Lp; for krc ~ 10, Lp ~ 1 TeVandthe hierarchy problem is solvednaturally G AdS Planck brane Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

10. ADD Model: Pro:“Eliminates” the hierarchy problem by stating that physics ends at a TeV scale Only gravity lives in the “bulk” space Size of ED’s (n=2-7) between ~100 mm and ~1 fm Black holes at the LHC and in the interactions of UHE cosmic rays Con: Doesn’t explain why ED are so large TeV-1 Scenario: Pro:Lowers GUT scale by changing running of the couplings Only gauge bosons (g/g/W/Z) “live” in ED’s Size of ED’s ~1 TeV-1 or ~10-19 m Con: Gravity is not in the picture Differences Between the Models G x5 Planck brane SM brane RS Model: • Pro: A rigorous solution to the hierarchy problem via localization of gravity • Gravitons (and possibly other particles) propagate in a single ED, w/ special metric • Con:Size of ED as small as ~1/MPl or ~10-35 m Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

11. ADD Model: Winding modes with energy spacing ~1/r, i.e. 1 meV – 100 MeV Can’t resolve these modes – they appear as continuous spectrum TeV-1 Scenario: Winding modes with nearly equal energy spacing ~1/r, i.e. ~TeV Can excite individual modes at colliders or look for indirect effects Kaluza-Klein Spectrum RS Model: • “Particle in a box” with a special metric • Energy eigenvalues are given by zeroes of Bessel function J1 • Light modes might be accessible at colliders Gravitational couplingper mode; many modes E E E ~MGUT ~MPl ~1 TeV GN for zero-mode; ~1/Lp for others … ge … Mi Mi M1 M0 M0 Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

12. EWSB from extra dimensions: Hall, Kolda [PL B459, 213 (1999)](lifted Higgs mass constraints) Antoniadis, Benakli, Quiros [NP B583, 35 (2000)](EWSB from strings in ED) Cheng, Dobrescu, Hill [NP B589, 249 (2000)](strong dynamics from ED) Mirabelli, Schmaltz [PR D61, 113011 (2000)](Yukawa couplings from split left- andright-handed fermions in ED) Barbieri, Hall, Namura [hep-ph/0011311](radiative EWSB via t-quark in the bulk) Flavor/CP physics from ED: Arkani-Hamed, Hall, Smith, Weiner [PRD 61, 116003 (2000)](flavor/CP breaking fields on distant branes in ED) Huang, Li, Wei, Yan [hep-ph/0101002](CP-violating phases from moduli fields in ED) Neutrino masses and oscillations from ED: Arkani-Hamed, Dimopoulos, Dvali, March-Russell [hep-ph/9811448](light Dirac neutrinos from right-handed neutrinos in the bulk or light Majorana neutrinos from lepton number breaking on distant branes) Dienes, Dudas, Gherghetta [NP B557, 25 (1999)](light neutrinos from right-handed neutrinos in ED or ED see-saw mechanism) Dienes, Sarcevic [PL B500, 133 (2001)](neutrino oscillations w/o mixing via couplings to bulk fields) Many other topics from Higgs to dark matter Using the ED Paradigm Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

13. ED and Flavor Physics via gravity bulk gauge fields SM • ED models offer a powerful paradigm for explaining flavor sector and CP-violation • New amplitudes and phases could be transmitted to our world via gravity (or other bulk fields), thus naturally introducing small parameters needed for description of CP-violation, flavor physics, etc. • Some realizations of this class of models give realistic CKM matrix (e.g., Arkani-Hamed, Hall, Smith, Weiner[PRD 61, 116003 (2000)]) • The idea of “shining” mentioned in the original ADD papers could explain why these effects were stronger in early universe “shining” bulk “CP-brane” SM big bang Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

14. Flavor Physics from Geometry Quark singletsof 3 generations Quark doubletsof 3 generations • Arkani-Hamed/Schmaltz [Phys. Rev. D61, 033005 (2000)] – split fermions embedded in a “fat” brane • Wave-functions of different families of quarks and leptons are spatially offset, thus the overlap areas are reduced exponentially • A fruitful paradigm to build models of flavor and mixing with automatically suppressed FCNC and stable proton • Possible to construct realistic CKM matrices via geometry of extra brane • Similar attempts in Randall-Sundrum class of models • In some of these models LFV decays of kaons are predicted and could be sought Huber [NP 666, 269 (2003)] Branco/de Gouvea/Rebelo[Phys. Lett. B506, 115 (2001)] Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

15. Tabletop Gravity Experiments • Sub-millimeter gravity measurements could probe only n=2 case only within the ADD model • The best sensitivity so far have been achieved in the U of Washington torsion balance experiment – a high-tech “remake” of the 1798 Cavendish experiment • R < 0.16 mm (MD > 1.7 TeV) • Sensitivity vanishes quickly with the distance – can’t push limits further down significantly • Started restricting ADD with 2 extra dimensions; can’t probe any higher number • Ultimately push the sensitivity by a factor of two in terms of the distance • No sensitivity to the TeV-1 and RS models [J. Long, J. Price, hep-ph/0303057] E.Adelberger et al. PRL 86, 1418 (2001) ~ ~ Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

16. Supernova cooling due to graviton emission – an alternative cooling mechanism that would decrease the dominant cooling via neutrino emission Tightest limits on any additional cooling sources come from the measurement of the SN1987A neutrino flux by the Kamiokande and IMB Application to the ADD scenario [Cullen and Perelstein, PRL 83, 268 (1999); Hanhart, Phillips, Reddy, and Savage, Nucl. Phys. B595, 335 (2001)]: MD > 25-30 TeV (n=2) MD > 2-4 TeV (n=3) Distortion of the cosmic diffuse gamma radiation (CDG)spectrumdue to the GKK gg decays [Hall and Smith, PRD 60, 085008 (1999)]: MD > 100 TeV (n=2) MD > 5 TeV (n=3) Overclosure of the universe, matter dominancein the early universe[Fairbairn, Phys. Lett. B508, 335 (2001); Fairbairn, Griffiths, JHEP 0202, 024 (2002)] MD > 86 TeV (n=2) MD > 7.4 TeV (n=3) Neutron star g-emission from radiative decays of the gravitonstrapped during the supernova collapse[Hannestad and Raffelt, PRL 88, 071301 (2002)]: MD > 1700 TeV (n=2) MD > 60 TeV (n=3) Caveat: there are many known (and unknown!) uncertainties, so the cosmological bounds are reliable only as an order of magnitude estimate Still, n=2 is largely disfavored Astrophysical and Cosmological Constraints Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

17. Collider Signatures for Large ED Real Graviton Emission Monojets at hadron colliders g g g q GKK GKK g q Single VB at hadron or e+e- colliders V GKK V V GKK GKK GKK V Virtual Graviton Effects Fermion or VB pairs at hadron or e+e- colliders f f V GKK GKK f f V • Kaluza-Klein gravitons couple to the energy-momentum tensor, and therefore contribute to most of the SM processes • For Feynman rules for GKK see: • [Han, Lykken, Zhang, PRD 59, 105006 (1999)] • [Giudice, Rattazzi, Wells, NP B544, 3 (1999)] • Since graviton can propagate in the bulk, energy and momentum are not conserved in the GKK emission from the point of view of our 3+1 space-time • Depending on whether the GKK leaves our world or remains virtual, the collider signaturesinclude single photons/Z/jets with missing ETorfermion/vector boson pairproduction • Graviton emission: direct sensitivity to the fundamental Planck scale MD • Virtual effects: sensitive to the ultraviolet cutoff MS, expected to be ~MD (and likely < MD) • The two processes are complementary Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

18. L’EPilogue (Large ED) Virtual Graviton Exchange All limits are in TeV LEP Combined: 1.2/1.1 TeV Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

19. ee  g + GKKat LEP g + MET final state MP > 1.4-0.5TeV (ADLO), for n=2…7 qq/gg  q/g + GKKat the Tevatron jets + MET final state Z(nn)+jets is irreducible background Challenging signature due to large instrumental backgrounds from jet mismeasurement, cosmics, etc. DØ pioneered this search and set limits [PRL, 90 251802 (2003)] MP > 1.0-0.6 TeV for n=2…7 Later, CDF achieved slightly betterlimits Expected reach for Run II/LHC: Colliders: Graviton Emission 85 pb-1 g q GKK [PRL 90, 251802 (2003)] q Theory: [Giudice, Rattazzi, Wells, Nucl. Phys. B544, 3 (1999) and corrected version, hep-ph/9811291] [Mirabelli, Perelstein, Peskin, PRL 82, 2236 (1999)] Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

20. Tevatron: Virtual Graviton Effects f f V GKK GKK f f V • Expect an interference with the SM fermion or boson pair production • High-mass, low |cosq*| tailis a characteristic signature of LED [Cheung, GL, PRD 62 076003 (2000)] • Best limits on the effective Planck scale come from new DØ Run II data: • MPl > 1.1-1.6 TeV (n=2-7) • Combined with the Run I DØ result: • MPl > 1.1-1.7 TeV – tightest to date • Sensitivity in Run II and at the LHC: Run II, 200 pb-1 Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

21. Interesting Candidate Events • While the DØ data are consistent with the SM, the two highest-mass candidates have anomalously low value of cosq* typical of ED signal: Event Callas: Mee = 475 GeV, cosh* = 0.01 Event Farrar: Mgg = 436 GeV, cosh* = 0.03 Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

22. Intermediate-size extra dimensions with TeV-1 radius Introduced byAntoniadis[PL B246, 377 (1990)]in the string theory context; used byDienes, Dudas, Gherghetta[PL B436, 55 (1998)]to allow for low-energy unification Expect ZKK, WKK, gKK resonances at the LHC energies At lower energies, can study effects of virtual exchange of the Kaluza-Klein modes of vector bosons Current indirect constraintscome fromprecision EWmeasurements:1/r ~ 6 TeV No dedicated experimental searches at collidersto date TeV-1 Extra Dimensions Antoniadis, Benaklis, Quiros [PL B460, 176 (1999)] ZKK Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

23. While the Tevatron sensitivity is inferior to indirect limits, it explores the effects of virtual KK modes at higher energies, i.e.complementary to those in the EW data DØ has performed the first dedicated search of this kind in the dielectron channel based on 200 pb-1 of Run II data (ZKK, gKK  e+e-) The 2D-technique similar to the search for ADD effects in the virtual exchange yields the best sensitivity in the DY production [Cheung, GL,PRD 65, 076003 (2002)] Data agree with the SM predictions, which resulted in the following limit: 1/R > 1.12 TeV @ 95% CL R < 1.75 x 10-19 m First Dedicated Search for TeV-1 Extra Dimensions 200 pb-1, e+e- Event Callas Interference effect 1/R = 0.8 TeV Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

24. Randall-Sundrum Model Observables • Need only two parameters to define the model:k and rc • Equivalent set of parameters: • The mass of the first KK mode, M1 • Dimensionless coupling • To avoid fine-tuning and non-perturbative regime, coupling can’t be too large or too small • 0.01 ≤ ≤ 0.10is theexpected range • Gravitons are narrow Expected Run II sensitivity in DY Drell-Yan at the LHC M1 Davoudiasl, Hewett, Rizzo [PRD 63,075004 (2001)] Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

25. First Search for RS Gravitons Already better limits than sensitivity for Run II, as predicted by phenomenologists! [PRL 95, 091801 (2005)] Assume fixed K-factor of 1.3 for the signal The tightest limits on RS gravitons to date Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

26. Black Holes on Demand NYT, 9/11/01 Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

27. Based on the work done with Dimopoulos a few years ago [PRL 87, 161602 (2001)]and a related study by Giddings/Thomas [PRD 65, 056010(2002)] Extends previous theoretical studies by Argyres/Dimopoulos/March-Russell [PL B441, 96 (1998)], Banks/Fischler [JHEP, 9906, 014 (1999)],Emparan/Horowitz/Myers [PRL 85, 499 (2000)] to collider phenomenology Big surprise: BH productionis not an exotic remote possibility, but the dominant effect! Main idea: when the c.o.m. energy reaches the fundamental Planck scale, a BH is formed;cross section is given by the black disk approximation: Geometrical cross section approximation was argued in early follow-up work by Voloshin [PL B518, 137 (2001) and PL B524,376 (2002)] More detailed studies showed that the criticism does not hold: Dimopoulos/Emparan – string theory calculations [PL B526, 393 (2002)] Eardley/Giddings – full GR calculations for high-energy collisions with an impact parameter [PRD 66, 044011 (2002)]; extends earlier d’Eath and Payne work Yoshino/Nambu - further generalization of the above work [PRD 66, 065004 (2002); PRD 67, 024009 (2003)] Hsu – path integral approach w/ quantum corrections [PL B555, 29 (2003)] Jevicki/Thaler – Gibbons-Hawking action used in Voloshin’s paper is incorrect, as the black hole is not formed yet! Correct Hamiltonian was derived: H = p(r2 – M)  ~ p(r2 – H), which leads to a logarithmic, and not a power-law divergence in the action integral. Hence, there is no exponential suppression [PRD 66, 024041 (2002)] Theoretical Framework s ~ pRS2 ~ 1 TeV -2 ~ 10-38 m2 ~ 100 pb ^ parton M2 = s RS parton Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

28. Assumptions and Approximation • Fundamental limitation: our lack of knowledge of quantum gravity effects close to the Planck scale • Consequently, no attempts for partial improvement of the results, e.g.: • Grey body factors • BH spin, charge, color hair • Relativistic effects and time-dependence • The underlying assumptions rely on two simple qualitative properties: • The absence of small couplings; • The “democratic” nature of BH decays • We expect these features to survive for light BH • Use semi-classical approach strictly valid only for MBH» MP; only consider MBH > MP • Clearly, these are important limitations, but there is no way around them without the knowledge of QG Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

29. Schwarzschild radius is given by Argyres et al., hep-th/9808138 [after Myers/Perry, Ann. Phys. 172 (1986) 304]; it leads to: Hadron colliders: use parton luminosity w/ MRSD-’ PDF (valid up to the VLHC energies) Note: at c.o.m. energies ~1 TeV the dominant contribution is from qq’ interactions Black Hole Production [Dimopoulos, GL, PRL 87, 161602 (2001)] stot = 0.5 nb (MP = 2 TeV, n=7) LHC n=4 stot = 120 fb (MP = 6 TeV, n=3) Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

30. Black Hole Decay [Dimopoulos, GL, PRL 87, 161602 (2001)] Note that the formula for N is strictly valid only for N » 1 due to the kinematic cutoff E < MBH/2; If taken into account, it increasesmultiplicity at low N • Hawking temperature: RSTH = (n+1)/4p (in natural units  = c = k = 1) • BH radiates mainly on the brane [Emparan/Horowitz/Myers, hep-th/0003118] • l ~ 2p/TH > RS; hence, the BH is a point radiator, producing s-waves, which depends only on the radial component • The decay into a particle on the brane and in the bulk is thus the same • Since there are much more particles on the brane, than in the bulk, decay into gravitons is largely suppressed • Democratic couplings to ~120 SM d.o.f. yield probability of Hawking evaporation into g,l±, and n ~2%, 10%, and 5% respectively • Averaging over the BB spectrum gives average multiplicity of decay products: • Stefan’s law: t ~ 10-26 s Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

31. Black Hole Factory [Dimopoulos, GL, PRL 87, 161602 (2001)] Black-Hole Factory n=2 n=7 g+X Drell-Yan Spectrum of BH produced at the LHC with subsequent decay into final states tagged with an electron or a photon Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

32. Relationship between logTH and logMBH allows to find the number of ED, This result is independent of their shape! This approach drastically differs from analyzing other collider signatures and would constitute a “smoking cannon” signature for a TeV Planck scale Shape of Gravity at the LHC [Dimopoulos, GL, PRL 87, 161602 (2001)] Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

33. Black Hole Events • First studies already initiated by ATLAS and CMS • ATLAS –CHARYBDISHERWIG-based generator with more elaborated decay model [Harris/Richardson/Webber] • CMS – TRUENOIR [GL] Simulated black hole event in the CMS detector [A. de Roeck & S. Wynhoff] Simulated black hole event in the ATLAS detector [from ATLAS-Japan Group] Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes

34. Conclusions If you still think that gravity is weak force, you may be spending too much time in the lab! • Stay tuned – next generation of collider experiments has a good chance to solve the mystery of large extra dimensions! • If large extra dimensions are realized in nature, black hole production at future colliders is likely to be the first signature for quantum gravity at a TeV • Many other exciting consequences from effects on precision measurements to detailed studies of quantum gravity • If any of these new ideas is correct, we might see a true “Grand Unification” – that of particle physics, astrophysics and cosmology – in just a few years from now! Greg Landsberg - Out-of-this-World Physics: From Particles to Black Holes