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March 20, 2008UT Relativity Seminar Spin-boost vs. Lorentz Transformations Application to area invariance of Black Hole horizons Sarp Akcay
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March 20, 2008UT Relativity Seminar Foreword Area invariance of a black hole’s (BH) 2-dim. Apparent horizon (AH) under Lorentz trans. is well known. But hard to show explicitly. Usual derivation is based on spin-boost transformations. It turns out that spin-boost trans. do not always yield meaningful trans. on a BH spacetime. Meaning: not all spin-boosts are physical boosts. Spin-boost derivation is not a reliable way to show AH area invariance under Lorentz boosts.
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March 20, 2008UT Relativity Seminar How we shall proceed Area invariance: The area of Black Hole’s (BH) apparent horizon (AH) is invariant under Lorentz transformations. Tetrad formalism: a basis of 4 lin. indep. vectors → a tetrad → null tetrad Special transformation: Null rotation of a null tetrad looks like a Lorentz boost, called a Spin-Boost transformation (type III rotation). AH geometry (metric) remains invariant under spin- boost transformations. (→ area invariance) Spin-boost is not really a Lorentz boost? (Poisson).
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March 20, 2008UT Relativity Seminar Area Invariance of AH BH event horizon (EH) is a 3-dim. null surface in spacetime. (see fig.1) AH is a 2-dim. cross section of EH at a t = constant slice. Any t will do, S 2 topology. Area of AH is invariant under Lorentz transformations. Null directions do not contribute to the area. (see fig. 2)
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March 20, 2008UT Relativity Seminar Area Invariance of AH contd. Explicitly shown in gr-qc:0708.0276 for Kerr BH w/ arbitrary boost. Area = ∫(det h AB ) 1/2 = 4π(r + 2 + a 2 )+ ∫ sinφ dφ Same answer as unboosted Kerr BH.
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March 20, 2008UT Relativity Seminar Usual derivation for Area Invariance Let ℓ α be a geodesic tangent to EH, λ be the affine parameter for ℓ α i.e. ℓ β ∂ β ℓ α = ∂ℓ α /∂λ Lorentz transformations change the parametrization of the null vector: 2-metric → where and e α A gets a null contribution under the transformation Therefore h AB remains invariant i.e. 2-metric is invariant.
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March 20, 2008UT Relativity Seminar Questions? 1. Why did g α β remain invariant? (no bars?) Under a type III rotation (spin-boost), g α β remains invariant Given a null tetrad e µ (a) = (ℓ µ, n µ, m µ, m µ *) for a spacetime: e (a) 2 = 0 and ℓ∙n = -1, m∙m* = 1 (by choice) The metric is given by g α β = - ℓ α n β – n α ℓ β + m α m β * + m α *m β A type III rotation on the tetrad is as follows: ℓ µ → A -1 ℓ µ, n µ → An µ, m µ → e iθ m µ, m µ * → e -iθ m µ * Metric is invariant under type III rotation
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March 20, 2008UT Relativity Seminar Questions 2. Why a type III rotation? It looks like a Lorentz boost Construct unit timelike T µ = (ℓ µ + n µ )/ √2 unit spacelike s µ = (ℓ µ - n µ )/ √2 Type III rotation transforms these Letting v/c ≡ β = (A 2 – 1)/ (A 2 + 1) we get Boost along s µ
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March 20, 2008UT Relativity Seminar So Far Spin-boost transformation gives Lorentz boost along spacelike vector s µ. 2-metric h AB remains invariant under spin- boost transformation. But the 2-metric from slide 4 is not invariant yet gives invariant area. What is going on?
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March 20, 2008UT Relativity Seminar Spin-Boost in Schwarzschild Spacetime Apply the spin-boost formalism to Schwarzschild (Sch.) spacetime 4-metric: Null tetrad: (ℓ µ, n µ, m µ, m µ *) ℓ µ is null, tangent to EH, geodesic with λ = r This gives Under spin-boost trans. → Boost along r
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March 20, 2008UT Relativity Seminar Spin-Boost for Sch. Spacetime contd. Obvious choice for a tetrad in Sch. spacetime gives boost along radial direction r. Boost along radial direction makes no sense. Let us pick another tetrad Start by first picking the spacelike boost direction s µ. Use ADM formalism to pick timelike T µ. Construct the null tetrad from these.
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March 20, 2008UT Relativity Seminar Spin-Boost for Sch. Spacetime contd. Boost along x-direction i.e. X µ = (0, 1, 0, 0) s µ must be unit spacelike, therefore in KS coord. (t, x, y, z) Unit timelike T µ is obtained from 3+1 ADM breakdown. ℓ µ is given by ℓ µ = (T µ + s µ )/ √2
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March 20, 2008UT Relativity Seminar Spin-Boost for Sch. Spacetime contd. Put this ℓ µ into geodesic eqtn. in Sch. spacetime Not geodesic! Worse: this is not tangent to the Sch. event horizon located at r = 2M. Easy to see this in Sch. spherical coordinates (x = r sinθ cosφ) → can not be used
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March 20, 2008UT Relativity Seminar Observations Under spin-boost transformation, null vectors tangent to EH yield radial boost directions. Boost direction must be rectilinear. Picking an a priori rectilinear direction results in null vectors that are not tangent to EH, thus can not be used to show the area invariance.
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March 20, 2008UT Relativity Seminar Conclusions Although Spin-boost trans. look like regular Lorentz boosts, this is not always the case. Certain choice of null tetrads give radial boost directions. 2-metric h AB remains invariant under spin-boost but does NOT under Lorentz-boost. Spin-boost derivation is not the correct way to show area invariance of AHs. However, Area of AH still is invariant.
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