Che-min Shen

transcript

Che-min Shen

In collaboration with Dr. Keisuke Izumi and Prof. Pisin Chen

The boundary effect of anomaly-induced action

National Taiwan University,Leung Center for Cosmology and Particle Astrophysics.

arXiv:1505.00959Phys. Rev. D 92, 024035 (2015)

• Scenario: Quantum field in curved spacetime

• Goal: Compute of some system.

• Method: Anomaly-induced action

• (Our work) Improvement: Including the Boundary term in the above action

Outline

Quantum fields in curved spacetime –Standard approach

Consider the simplest case, a scalar field in curved spacetime with the Lagrangian :

2 2 21 1( R )

2 2g g m

2( + ) (x) 0m R The equation of motion:

Solving a complete solution set: {u (x) | all k}k

†*(x) [a (x) a (x)]k kk kdk u u Quantize the scalar field:

The vacuum state is thus defined by: a 0 0i

However, there is no unique way to choose a complete solution set, therefore the concept of “vacuum” is ambiguous in general.

Conformally coupled scalar field in n-dim:

4(n 1)

and m = 0.

Schwarzschild metric and its various coordinates

“Hartle-Hawking” coordinates

“Unruh” coordinates

“Boulware” coordinates

The dashed lines are (TH,RH) coordinate. The dashed lines are (t,r) coordinate. The dashed lines are (TU,RU) coordinate.4

Quantum fields in curved spacetime –Different choises of vacuum states for Schwarzschild metric

Quantization by different mode expansion:

(i) Boulware vacuum state:

(ii) Hartle-Hawking vacuum state:

(iii)Unruh vacuum state:

Quantum fields in curved spacetime –Renormalization by Path integral

[ ][D ]effS Se e Compute the (one-loop) effective action Seff by path integral :

Derive the expectation value of stress tensor from Seff:

By the DeWitt-Schwinger expansion, this effective Lagrangian in n-dim can be expanded as

The singularities of the gamma function are simple poles at zero and the negative integers

PS: The UV divergence here is independent of choice of quantum state. 6

Conformal anomaly & Anomaly-induced action…1

• In conformal theory, the stress tensor is traceless in general.

• However, after renormalization, due to the counter terms the conformal symmetry is broken and it results in an nonzero trace of stress tensor, which is the so-called conformal anomaly.

• For example, in 2-dim:

First Consider the Wess-Zumino action, which was first found by Polyakov:

Recall the divergent term of one-loop Seff in 2-dim :

• By using conformal symmetry and the counter terms, the anomaly-induced action can be built.

• People expected and checked that the stress tensor from above action can be used to describe renormalized stress tensor corresponding to various quantum states. [2][3]

2-dim Anomaly-induced action (Polyakov action [1]):

where the auxiliary scalar field should satisfy the field equation:

[1] A. M. Polyakov, Phys. Lett. B 103, 207 (1981).[2] R. Balbinot, A. Fabbri and I. L. Shapiro, Nucl. Phys. B 559, 301 (1999).[3] E. Mottola and R. Vaulin, Phys. Rev. D 74, 064004 (2006).

Take the Schwarzschild metric as an example:

(The most general solutions which result in stationary stress tensor)

(i) A = B = 0 Boulware vacuum solution:

(iii) A = -B = -1/(4M)

(ii) A = 0, B = 1/(2M) Hartle-Hawking vacuum solution:

Unruh vacuum solution:

ˆ= B T B

ˆH T H

ˆU T U

However, the correspondence between the solutions and the vacuum states of quantum fields is missing.10

Motivation: Include boundary contribution -> Recover the reference between solution and vacuum

• Introduce the boundary part of divergent terms. [4][5]

• Rederive the anomaly-induced action again now with boundary effect.

• The key concept: take boundary term into consideration will recover some information of specific frames and therefore we expect this can give us guidance to the relation between solutions from anomaly-induced action and the corresponding vacuum states.

[4] T. P. Branson and P. B. Gilkey, Commun. Part. Di. Eq. 15, 245 (1990).[5] I. G. Avramidi, Phys. Atom. Nucl. 56, 138 (1993) [Yad. Fiz. 56N1, 243 (1993)].

Improvement: Anomaly-induced action with boundary effect …1

where the auxiliary scalar field should satisfy the original equation and an additional boundary constraint:

The boundary effect of anomaly-induced actionChe-Min Shen, Keisuke Izumi, Pisin Chen, Phys. Rev. D 92, 024035 (2015)

• The anomaly-induced action with boundary term:

At first, consider “Boulware” boundary:

The most general solutions which result in “stationary” stress tensor is

When A2=0, the result is indeed the Boulware vacuum solution.A2 characterizes the thermal excitation based on the Boulware vacuum.

Similarly, by considering the “Hartle-Hawking” and “Unruh” boundaries, we will get:

The Hartle-Hawking vacuum solution and the corresponding thermal excitation states (which is parametrized by AH):

The Unruh vacuum solution and the corresponding thermal excitation states Can also be solved by considering the corresponding boundary:

Note: When A2 = 1/(2M), the “Boulware” result shown in last page is the same as that of the Hartle-Hawking vacuum state. This fact is consistent with the usual understanding that HH vacuum is thermal state at Hawking temperatureof Boulware observer (static observer).

• Anomaly-induced action is an useful approach to solve

• However, the correspondence between its solutions and the vacuum states of original quantum field which we are interested in is missing.

• We take boundary effect into consideration and expect that it will introducesome information related to frame and thus the corresponding vaccumstate.

• The extended version of anomaly-induced action now really become an independent formalism to solve , the thermal excited states as well.(The solutions abtained from the previous action need to be tuned and thus is unable to do this.)

• We are working on 4-dimentional case, and already finished most of it. The next work will be on arxiv soon.

Summary

Thank you

Che-min Shen

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