Black Holes and Extra Dimensions

Black Holes and Extra Dimensions

Jonathan Feng

UC Irvine

UCSD Particle Seminar

28 January 2003

January 2003 UCSD Feng 2

The Standard Model• Many interesting problems, but one obvious one: where’s

gravity?

Gravity is weak, becomes strong at MD ~ 1018 GeV, far beyond experiment

• Suppose SM confined to D = 4, but gravity propagates in n extra dimensions of size L:

For r L, Fgravity ~ 1/r2

For r L, Fgravity ~ 1/r2+n


…

gravity

EM

Str

engt

h

rMD-1

Gravity in Extra Dimensions


Strong Gravity at the Electroweak Scale

• If D > 4, MD < 1018 GeV possible

Suppose MD is 1 TeV, the electroweak unification scale

• The number of extra dims n then fixes L

• n=1 excluded by solar system, but n=2, 3,… are allowed by tests of Newtonian gravity

Arkani-Hamed, Dimopoulos, Dvali (1998)


Tests of Newtonian GravitySt

reng

th o

f D

evia

tion

R

elat

ive

to N

ewto

nain

Gra

vity

Long, C

han, Price; H

oyle et al.


Kaluza-Klein States

• Extra dimensions of size L towers of Kaluza-Klein particles with masses ~ L-1

• Large extra dims light states

• KK states may appear at colliders, in astrophysics (supernova cooling, etc.), …

f

f f ’

f ’graviton

_ _


Black Holes

• BH production requires strong gravity, masses or energies above MD

• In 4D, MD ~ 1018 GeV, BHs confined to astrophysics, form by accretion

• But in extra D with MD ~ 1 TeV, BHs may be produced in elementary particle collisions


• A Schwarzschild BH (Q = J = 0) has radius

• In classical GR, expect a BH to form when two partons pass within rs of each other:

• Assume this, and that MBH = s1/2.

BHs from Particle Collisions

Banks, Fischler (1999)

Myers, Perry (1986)

^


• Classic study for 4D, b = 0 collision:

MBH ~ 0.8 s1/2

D’Eath, Payne (1992)

• Heuristic argument for b > 0: J > 0 rs rKerr: ~ 0.64 classical

Anchordoqui, Feng, Goldberg, Shapere (2001)

• Classic study generalized to b > 0:

> 0.64 classical ; MBH > 0.71s1/2 for b = 0, MBH > 0.45s1/2 for b = bmax

Eardley, Giddings (2001)

• And to D > 4:

> 1.05 classical ; MBH > 0.6s1/2 for b = 0, MBH > 0.1s1/2 for b = bmax

Yoshino, Nambu (2002)Ida, Oda, Park (2002)

BH Formation


For low mass black holes, brane, quantum gravity corrections are important. Require:

• Small statistical fluctuations in number of degrees of freedom

• Little back reaction from radiationPreskill, Schwarz, Shapere, Trivedi (1991)

Both require large entropy S ~ rs2+ n .

• BH lifetime >> MBH-1

For n=6, S(5MD) = 27, S(10MD) = 59

(5MD) = 10MBH -1, (10MD) = 12MBH

–1

Giddings, Thomas (2001)

• Brane effects negligible

Semi-classical analysis only valid for MBH > MBHmin = few MD .

Semi-classical Validity


Black Holes at CollidersWhat is the production rate?

• LHC: ECOM = 14 TeV

pp BH + X

• Find as many as 1 BH produced per second

• Note, however, extreme sensitivity to MBH

min. Dimopoulos, Landsberg (2001)Rizzo (2001)


Event Characteristics• For microscopic BHs,

~ 10-27 s, decays are essentially instantaneous

• TH ~ 100 GeV, so multiplicity ~ 10

• j : l : : ,G = 75 : 15 : 2 : 8

Emparan, Horowitz, Myers (2000)

• Signal: spherical events with hard leptons, photons De Roeck (2002)


Black Holes from Cosmic Rays

• Cosmic rays – the high energy frontier

• Observed events with 1019 eV ECOM ~ 100 TeV

• But meager fluxes! Can we harness this energy?

Kampert, Swordy (2001)


Cosmic Neutrinos

Feng, Shapere (2001)

Many possible UHE particles – use neutrinos:

Ndominates SM processes, since all partons contribute

pN<< pp. Protons are hopeless


The Signal

• Vertical atm. depth: 10 mwe

Horizontal atm. depth: 360 mwe

• BH: uniform at all depths

pN X: at top of atmosphere

• Signal: deep inclined showers; atmosphere filters out proton, nucleus background

Feng, Shapere (2001)


Deep Inclined Showers

Coutu, Bertou, Billior (1999)


Rates


• Guaranteed: photoproduction

• Choose most conservative: Protheroe, Johnson

Fluxes

Stecker (1979)Hill, Schramm (1985)

Protheroe, Johnson (1996)


• Additional sources may exist (for example, to solve the GZK problem)

• Below consider only photoproduction; other sources may increase rates by 2 orders of magnitude

Other Sources


• Showers may be detected by ground arrays and air fluorescence

Current: AGASA (ground),HiRes (air fluor.)

Future: Auger (both)

Apertureshtt p://w

ww

.auger. org


Auger Observatory


Apertures

Capelle, Cronin, Parente, Zas (1998)Diaz, Shellard, Amaral (2001)

Anchordoqui, Feng, Goldberg, Shapere (2001)HiRes Collaboration (1994)


• Lower bounds on MD from absence of BHs at AGASA and HiRes for MBH

min = MD .

• For n > 3, MD > 1.5 – 2.0 TeV, most stringent bounds to date

Current Bounds: AGASA, HiRes



For MBHmin ~ 10 MD ,

well into classical regime, bounds are comparable to or exceed all other bounds

MBHmin Dependence

Lower bounds on MD for n=1,...,7 from below

xmin = MBHmin/MD


Future Prospects: Auger

• Auger begins 2004 — can detect ~100 black holes in 3 years

• Provides first chance to see black holes from extra dimensions

mD (

TeV

)

Number of BHs at Auger for n = 7, MBHmin = MD


Comparison with LHC

• LHC predictions extremely sensitive to MBH

min

• No Auger BHs, MBHmin

>5 MD no LHC BHs

• Of course, we could see events! ...


Black Hole Identification

• How will you know if you’ve created one?


S. Harris


BHs vs. SM

• BH rates may be 1000 times SM rate. But

– large BH large rate

– large flux large rate

• However, consider Earth-skimming neutrinos:

– large flux large rate

– large BH small rateBertou et al. (2001)

Feng, Fisher, Wilczek, Yu (2001)


Quasi-horizontal (dashed) and Earth-skimming showers (dotted) in 5 years.

SM explanation (BH=0) excluded at high CL.


What You Could Do With A Black Hole If You Made One

• Discover extra dimensions

• Test Hawking evaporation, BH properties

• Explore last stages of BH evaporation, quantum gravity, information loss problem

• ……


Additional Possibilities

• Under-ice: AMANDA/IceCube

• Radio: RICE, ANITA

• Space-based: EUSO/OWL

• These may provide BH branching ratios, angular distributions, etc.

Anchordoqui, Goldberg (2001)Emparan, Masip, Rattazzi (2001)

Uehara (2001)Ringwald, Tu (2001)

Ahn, Cavaglia, Olinto (2002)Kowalski, Ringwald, Tu (2002)

Jain, Kar, Panda, Ralston (2002)Alvarez-Muniz, Feng, Halzen, Han, Hooper (2002)

Anchordoqui, Feng, Goldberg (2002)Iyer Dutta, Reno, Sarcevic (2002)

Anchordoqui, Goldberg, Shapere (2002)McKay, etal. (2002)

...

Jonathan Feng

If not... "The use of the 4th dimension was a very opportune discovery for the spiritualists and the theologians who were in a quandry about the location of hell." Ernest Mach (1884)


Conclusions

• Gravity is either intrinsically weak or is strong but diluted by extra dimensions

• If gravity is strong at ~ 1 TeV, we will find black holes in cosmic rays and colliders


MD (

TeV

)

Jonathan Feng

If not... "The use of the 4th dimension was a very opportune discovery for the spiritualists and the theologians who were in a quandry about the location of hell." Ernest Mach (1884)

Documents

Black Holes and Extra Dimensions