Entropy of the Vacuum - Beyond Center3/14/19 1 Entropy of the Vacuum Ted Jacobson University of...
11
3/14/19 1 Entropy of the Vacuum Ted Jacobson University of Maryland Based on arxiv:1505.04753 (TJ) and arxiv:1812.01596 (TJ & Manus Visser) Beyond Center Workshop, 17 February 2019 Quantum Gravity: Back to Basics Black hole entropy General relativity and quantum field theory ensure that Bekenstein’s generalized entropy locally satisfies the second law, despite the fact that entropy can be tossed into a black hole. S gen = A H /4~G + S out S gen = A H /4~G ⇤ + S out,<⇤ More precisely, if we include outside field modes up to a cutoff energy Λ, …which strongly suggests that black hole entropy is, in some UV completed sense, entanglement entropy of the vacuum, and that area is a measure of entanglement. Moreover, requiring the Clausius relation dS H = dQ/T U for all local acceleration horizons, or, equivalently, stationarity (maximization?) of S gen , implies the Einstein equation. The vacuum entanglement entropy area density is 1/(4hbar G); more entanglement implies smaller G, i.e. increased spacetime “stiffness”.
Transcript of Entropy of the Vacuum - Beyond Center3/14/19 1 Entropy of the Vacuum Ted Jacobson University of...
-
3/14/19
1
EntropyoftheVacuum
TedJacobsonUniversityofMaryland
Basedonarxiv:1505.04753(TJ)andarxiv:1812.01596 (TJ&ManusVisser)
Beyond Center Workshop, 17 February 2019
Quantum Gravity: Back to Basics
Blackholeentropy General relativity and quantum field theory ensure that Bekenstein’s generalized entropy locally satisfies the second law, despite the fact that entropy can be tossed into a black hole.
Sgen = AH/4~G+ Sout
Sgen = AH/4~G⇤ + Sout,
-
3/14/19
2
A~BB~
A
`c
N.B.CutoffonproperseparaMonofpairs,whichisLorentzinvariant.
At `c scale, energy uncertainty is �E ⇠ ~/`c.
Causalstructurefluctuates,blurssubsystem,cuSngoffentanglemententropyatthePlanckscale.
WHY IS VACUUM ENTANGLEMENT ENTROPY FINITE?
Gravity is strong at this scale when `c . rg ⇠ G�E ⇠ ~G/`c
i.e. when `c . `P
AdS/CFT appears to provide a realization of these dreams:
The Ryu-Takayanagi formula (& its time-dependent generalization)
relates CFT entanglement entropy to bulk acceleration horizon entropy,
with a nonzero Newton constant, 1/G ~ # fields of CFT < ∞.
The bulk Einstein equation can be derived from RT formula together with
CFT entropy properties.
-
3/14/19
3
§ Is the AdS boundary essential?
§ How locally can notions of black hole thermodynamics be applied?
§ Thermodynamics of dS static patch?
§ A small causal diamond in any spacetime is a small deformation of a maximally symmetric causal diamond, and the Einstein equation is equivalent to the first law for such diamonds. Is this because entanglement entropy is maximized in vacuum?
§ Can this shed light on the cosmological constant problem?
Origin of the first law of black hole mechanics
1972,Bekenstein:ThefirstlawfromvaryingparametersintheKerr-NewmansoluMon.Didn’tknowthat,liketheangularvelocityofthehorizonΩandtheelectostaMcPotenMalΦ,thequanMtyκisanintensivevariable,northatithadtheinterpretaMonofsurfacegravity.1972,Bardeen,Carter&Hawking:DerivedthefirstlawbyvariaMonoftheSmarrFormulawhichtheyobtainedfromanidenMtywiththeKillingvector,andtheEinsteinequaMon.Onestepwastoprove,assumingthedominantenergycondiMon,thatκisconstantonthehorizon.(AproofassumingonlyacertainsymmetrybutnoenergycondiMonexists(Carter,Racz&Wald),andtheproofistrivialifoneassumesthefuturehorizonterminatesatabifurcaMonsurface,wheretheKillingvectorvanishes.)
dM =
8⇡GdA+ ⌦H dJ + � dQ
M = 2⌦HJ +1
4⇡GA+matter terms
-
3/14/19
4
1992,Sudarsky&Wald;1993,Wald;1994,Iyer&Wald:Thefirstlawforanydiffeomorphisminvarianttheory,withtheroleofentropyplayedbythehorizonNoetherchargeassociatedwiththehorizongeneraMng
Killingvector,andvalidforallperturbaMons(notjuststaMonaryones).
DiffeomorphisminvarianceisresponsiblefortyingtogethervariaEonsofsurfaceintegralsatinfinityandatthehorizon.BlackholethermodynamicsisinEmatelyconnectedtodiffinvariance.
ThefirstlawindeSigerspaceMmeGibbons&Hawking,1977
TheyobtainedthisbyfirstderivingaSmarrformula,thenvarying.
-
3/14/19
5
ThefirstlawindeSigerspaceMmeGibbons&Hawking,1977
NNNN
ThefirstlawindeSigerspaceMmeGibbons&Hawking,1977
A
NNNN
NegaMvetemperature!(suggestedbyKlemm&Vanzo,2004);pickedupbynobody…
NegaMvetemperaturerequiresafinitedimensionalHilbertspace……andthereareindependentreasonstothinkthedSHilbertspaceisfinitedimensional:finiteentropy(Banks&Fischler,…)
-
3/14/19
6
FailedagemptstoincreasetheentropyofthedSstaMcpatch
1. Putablackholeinside.Fails:AC+AHdecreases!
2. Putmagerwithentropyinside.Fails:magerhaslessentropythanablackholeforthesamemass.
SuggeststhatentropyofthedSvacuumismaximal.
Thisiscloselyrelatedtothemaximalvacuumentanglementhypothesis,thatthegeneralizedentropyofsmallgeodesicballsismaximalatfixedvolumeinMinkowskispaceMme,wrtvariaMonsofthestateawayfromtheMinkowskivacuum(TJ,2015).
Butisn’ttheGibbons-HawkingtemperatureofdSposiEve??Yes,indeed.ThedSvacuumisathermalstatewithrespecttotheHamiltoniangeneraMngMmetranslaMononthestaMcpatch.ThiswasfoundintheoriginalGibbons-Hawkingpaper,anditisadSanalogoftheDavies-UnruheffectintheRindlerwedgeofMinkowskispaceMme.
TGH = ~c/2⇡, c = H =p
⇤/3
Sodoesn’tthiscontradictthefirstlawofdS?No!ThemagerentropyaddstothedShorizonentropy,formingthestatementthatBekenstein’sgeneralizedentropyisstaEonary:
TGHdSm = �TGHdSBH =) dSgen = 0
-
3/14/19
7
Exceptincertainlimits,theyadmitonlyaconformalKillingvector.ThemetriccanbepresentedasaconformalfactorMmes(hyperbolicspace)x(Mme):
Maximallysymmetriccausaldiamonds(TJ,2015;TJ&ManusVisser,2018)
Remarkably,theslicesofconstantsformaCMCfoliaMon:
⇣ = @sisaconformalKillingvector,withunitsurfacegravity,andan“instantanous”trueKillingvectorats=0.
Firstlawformaximallysymmetriccausaldiamonds(TJ,2015;TJ&ManusVisser,2018)
ASmarrformulaandaFirstLawcanbederivedusingthediff.NoethercurrentàlaWald.FirstLawhasanaddiMonalterm,sinceckvnotakv:
Vistheball’svolume,kistheoutwardextrinsiccurvatureofitsedge.IndS,k=0.
Thevolumetermis;ithasthisgeometricformthankstoaminormiracle:d(divς)hasconstantnorm~κkonΣ(i.e.ats=0).ThatitisproporMonaltothevolumevariaMonispresumablyrelatedtotheYorkMme(-K)Hamiltonianbeingthevolume.
��Hgrav⇣
ThelasttermisthethermodynamicvolumeMmesthepressurevariaMon.ItappearedintheGHSmarrformula,andwasintroducedandinterpretedbyKastor,RayandTraschen(2009)intheAdSblackholeseSng.
�Hmatter⇣ =1
8⇡G(� �A+ k �V � V⇣ �⇤)
V⇣ =
Z
⌃⇣ · ✏
-
3/14/19
8
Comments on the First Law
• ThediamondhasnegaMvetemperatureasforthedSstaMcpatch.
• Thevolumeoftheballcanbedefinedinagaugeinvariantwayasthevolumeofthemaximalslicewithfixedboundary.ThismightbeimportantwhenextendingthisrelaMontoasecondordervariaMon.
• ThevariaMonofareaatfixedvolumehasadeficit,whilethevariaMonofvolumeatfixedareahasanexcess.
• A“small”diamondinanarbitraryspaceMmecanbeviewedasavariaMonofamaximallysymmetricspace,andthisvariaMonmustsaMsfythefirstlawifthespaceMmeisasoluMontoEinstein’seqn.Conversely,allthesefirstlawsmustimplytheEinsteinequaMon.
T = �TH = �~/2⇡
CommentsontheFirstLaw,contd.
• ThemagerHamiltonianvariaMoncanbetradedforanentanglemententropyvariaMon,combiningwiththeareatomakethegeneralizedentropyvariaMon.
-
3/14/19
9
�hKi = 2⇡~
Z�hTabi⇣ad⌃b
CFTEntanglemententropyinaMinkowskiball
⇢vac / e�KConsiderthegroundstateofaQFT,restrictedtothediamond:
�S = ��Tr(⇢ ln ⇢) = Tr(�⇢K) = �hKi
(Hislop&Longo’82,Casini-Huerta-Myers’11)
1/Unruhtemperature Conformalboostenergy
UsedalsobyLashkari,McDermog&vanRaamsdonk’13inholographicderivaMonoflinearizedEinsteinonAdS.
Kisthe“modularHamiltonian”.UnderastatevariaMontheentropyvariaMonis:
ForaCFT,Kislocal,=conformalboostenergy/Unruhtemperature:
=1
TH�hHmatter⇣ i�Smatter =
SemiclassicalFirstlawformaxsymmcausaldiamonds(TJ,2015;TJ&ManusVisser,2018)
�Hmatter⇣ =1
8⇡G(� �A+ k �V � V⇣ �⇤)
0 = T �Sgen +1
8⇡G(k �V � V⇣ �⇤)
ForaCFTcanbeexpressedasstaMonaryentropyatfixedVandΛ:
HoldsalsoforaQFTforsmalldiamond,withaquantummagercontribuMontoδΛ.HoldingVandnetΛfixedsMllcorrespondstostaMonaryentropy.
�hKi = 1TH
�hHmati+ V⇣ �X
Lorentzscalar,contributes“cosmological”term.
-
3/14/19
10
Entangledqbits
whichbytheEinsteinequaMonimplies
hence
Isvacuumentanglementmaximal?
Bychangingthestateofmagerandgeometry,canSbeincreasedwhileholdingthevolumefixed?
Assume S = SUV + SIR, with
�E & ~/`
SUV = SBH = A/4~G
�A|V . �~G
�Stot
. 0
“Highlyentropic”systemsalsocontributetothevacuumentropy,suppressingtheirentropychange.Infact,themaximumentropyforagivenenergyisdE/Tinathermalstate.Marolf&Sorkin‘03,Marolf,Minic&Ross‘03,Marolf‘04
(N.B.massmakesitevenhardertoincreasetheentropy.)
Underwehave
VariaMonofentanglemententropy
(�gab, �| i)
�S = �SUV + �SIR
=�A
4~G + �hKi
=0atconstantV,foraCFT.
HowaboutforfinitevariaMons?PosiEvityofrelaEveentropymeanshereposiEvityoftheconformalboostfreeenergyvariaEon:
�hKi � �SIR � 0
<
(onafixedalgebra)
-
3/14/19
11
UnderfinitevariaMons
VariaMonofentanglemententropy
(�gab, �| i)posiEvityofrelaEveentropyplustheEinsteinequaMonimplies
�Stot
|V 0
Maximal Vacuum Entanglement Entropy
N.B.OnlytheEinsteinHamiltonianconstraintequaMonisinvoked.Thatis,onlyrestricMontothephysicalphasespace.ThisisconsistentwiththenoMonthatthevacuumisanequilibriumstate,maximizingentropyoverALLstatesinthephasespace/Hilbertspace.
Conversely, one can “almost” derive the Einstein equation from maximal
vacuum entanglement.
Not yet clear if/how the argument can be extended to apply to
coherent states of matter (which appear to carry energy
without modifying entanglement entropy of matter).
BEYOND, two questions seem pressing:
Is there a well-defined partition function for a diamond?
(First, does the G-H dS partition function make sense?)
Is there a well-defined regional quantum gravity,
enclosed in a finite boundary?
