$1/N$ correction in holographic Wilson loop from quantum gravity

We study $1/N$ corrections to a Wilson loop in holographic duality. Extending the AdS/CFT correspondence beyond the large $N$ limit is an important but a subtle issue, as it needs quantum gravity corrections in the gravity side. To find a physical property of the quantum corrected geometry of near-horizon black 0-branes previously obtained by Hyakutake, we evaluate a Euclidean string worldsheet hanging down in the geometry, which corresponds to a rectangular Wilson loop in the $SU(N)$ quantum mechanics with 16 supercharges at a finite temperature with finite $N$. We find that the potential energy defined by the Wilson loop increases due to the $1/N$ correction, therefore the quantum gravity correction weakens the gravitational attraction.


Introduction
Whether the AdS/CFT correspondence [1][2][3] works beyond the large N limit is one of the central problems in holography and quantum gravity.This is simply because the question leads to the consistency of having the holographic principle as a definition of quantum gravity.In spite of the importance, the difficulty in calculating the quantum gravity corrections to the AdS/CFT observables prevented us from the explicit check of the validity of the AdS/CFT beyond the large N limit.
A nontrivial check was made in Ref. [4,5] at which the energy of the near horizon geometry of black 0-branes was shown to coincide with that of the dual SU (N ) supersymmetric quantum mechanics at finite temperature, to the first nontrivial correction order in the 1/N 2 expansion.The analysis on the gravity side was based on the quantum-corrected near horizon geometry obtained by Hyakutake [6], therefore this nontrivial result shows that the geometry is a good test ground for the AdS/CFT correspondence beyond the large N limit. 1  The finite N AdS/CFT offers interesting issues, among which here we mention the phase transition.The Hawking-Page transition [9] in AdS/CFT is known [10] to correspond to confinement/deconfinement transition which is a first order transition at the large N limit.On the other hand, theories such as QCD at N = 3 has a cross-over phase transition, 1 To obtain nontrivial 1/N terms in the gravity side, one needs to break at least a part of supersymmetries, as AdS5 × S 5 is expected to have no correction due to the largest number of supersymmetries.See for example Ref. [7] for the check of the spectra at the 1/N 2 level for an orbifolded S 5 .See also Ref. [8] for recent discussions on the 1/N corrections to the AdS5 blackhole entropy.
thus the finite N drastically changes the thermal behavior.Even if one includes the 1/N 2 correction to the gravity metric, intuitively the Hawking-Page transition is expected to persist, and the phase transition is still at the first order, which causes an issue about how the finite N effect should be seen in the gravity side.Interestingly, a gravity geometry inversely obtained to reproduce QCD lattice data [11] using a deep learning technique [12] has a weak repulsive wall just outside the black hole horizon, suggesting the coexistence of confinement and deconfinement phases in gravity. 2   To find any local structure of the quantum-corrected black hole geometry, we need some probe.In this paper we evaluate a holographic Wilson loop of the SU (N ) quantum mechanics with 16 supercharges at a finite temperature.The gravity dual is a Euclidean string worldsheet ending on the contour of the Wilson loop [13].Generally the rectangular Wilson loop is related to a potential energy of a quark and an antiquark pair, and here we consider the W-bosons, by separating two of the D0-branes from the remaining N D0-branes which compose the black hole 3 .The quantum gravity corrections due to the geometry provides the 1/N 2 corrections to the potential energy.We will find that the resultant contribution to the potential energy is positive, meaning that the gravitational attraction is weakened due to the quantum gravity corrections.This appears to be consistent with the general argument above to make the phase transition weaker.
In addition to the correction due to the bulk quantum effect which we treat in this paper, as for the Wilson loop there exists another correction of the same order O(1/N 2 ), that is a higher genus correction of the Euclidean string worldsheet for the probe.This effect has been explicitly calculated in [14] for the case of a circular Wilson loop 4 .This effect, although at the same order, is difficult to calculate in our case and so we concentrate on the bulk quantum gravity correction.
The organization of this paper is as follows.First in Sec. 2, we review the quantumcorrected gravity geometry of the black 0-branes in type IIA string theory given by Hyakutake [6], and see that the parameters, N and the temperature, needs to satisfy certain inequalities so that the quantum corrections are dominant against α corrections.Furthermore, we study the reality condition of the spacetime metric, and the spacetime region where the analysis is valid.In Sec. 3, we evaluate the Wilson loop and its 1/N correction due to the quantum correction of the spacetime geometry in the gravity side.The obtained potential energy shows that the attractive force of the gravity is weakened by the 1/N correction.Sec. 4 is for our summary and discussions, and Appendix A is a review of the details of the quantum corrected geometry [6] which we use in this paper.

Spacetime conditions
In this section, we briefly review the result of [6] for introducing the target space of our interest, and analyze necessary conditions for our worldsheet analyses in the later sections to be valid.

Review: Quantum correction of the near horizon black 0-brane geometry
Here we introduce the quantum-corrected near horizon geometry of the black N 0-branes obtained in Ref. [6].Let us describe first the geometry without the quantum correction, that is a near-horizon solution of the type IIA supergravity [19]: Here φ is the dilaton field, while the Ramond-Ramond 1-form is omitted.λ is the 't Hooft coupling of the dual gauge theory, the SU (N ) quantum mechanics with 16 supercharges The radial coordinate is U ≡ r/l 2 s in which we rescaled the original supergravity coordinate r by the string length l s , thus having the dimension of energy.U 0 is a parameter determining the event horizon of the geometry and resultantly the temperature, The dimensionless coordinate Ũ0 and the dimensionless temperature T ≡ T /λ 1/3 were introduced for convenience.According to Ref. [6], in order to obtain the quantum-corrected geometry, one makes use of the fact that the black 0-brane solution (2.1) is a dimensionally reduced M-wave solution [20] in 11-dimensional supergravity.At the 11 dimensions, some higher derivative corrections to the Einstein-Hilbert action are known, thus derive the 1-loop quantum corrections to the type IIA supergravity in string theory.The geometry solving the corrected 11-dimensional supergravity provides the quantum corrected black 0-brane solution at the dimensional reduction.The obtained geometry is [6] ) (2.5) Here x ≡ U/U 0 is a dimensionless radial coordinate, and the functions H i , F 1 are defined in Appendix A. In the limit N → ∞, those functions reduce to the original uncorrected geometry (2.1), consistently.Note that the location of the horizon of the geometry, originally at x = 1, is shifted to some x = 1 in this coordinate system.

Constraints on the temperature and N
The higher derivative corrections of the gravity consist of quantum corrections and stringy corrections.In Ref. [6], a condition for finding that the quantum corrections are dominant against the stringy corrections was calculated, These inequalities are derived by the comparison of the various terms in the entropy of the black hole. 5The parameter s ( 1) introduced here is a small constant to quantify the hierarchy among the magnitudes of the correction terms.In this paper we use s = 0.1 below, together with c 1 = 0.779 [6] and c 2 = 0.00459 [4].We note that the heat capacity of the geometries (2.4) and (2.1) is positive when (2.6) is satisfied, so these spacetimes are thermodynamically stable [6].
In addition to the inequalities (2.6) found in Ref. [6], we find a new inequality to be satisfied for a consistent geometry.The location of the horizon x = x h is determined by a solution of the equation F 1 (x h ) = 0, while the other metric factors H i (x) could vanish in the region x > x h .This leads to an inconsistency, because H i (x) = 0 means that the perturbative correction is comparable to the original uncorrected metric.Furthermore, since the metric (2.4) includes a square root of H i (x), the metric becomes imaginary.Therefore we have to require for our geometry and the corrections to be consistent.This inequality is rephrased in terms of N and T .A straightforward numerical evaluation shows that a condition ensures the constraints for the metric functions (2.7) (see Appendix A).So we choose this inequality (2.8) as a necessary condition for ( T , N ) to be satisfied.In Fig. 1, we plot all the inequalities including (2.6).We have to choose a set of values ( T , N ) from the allowed region shown in Fig. 1.

Valid spacetime region
Up to now we have looked at some necessary conditions for the quantum gravity corrections to be a dominant correction and for the spacetime to make sense.In this subsection, we obtain conditions about valid spacetime regions, by assuming that string perturbation makes sense.
As is found in the supergravity metric (2.1), black p-brane supergravity solutions except for p = 3 are not scale invariant, and resultantly there appears spacetime regions where quantum gravity corrections or stringy corrections grow to overwhelm the consistency of string perturbation theory.Perturbation consistency requires g s e φ 1. (2.10) Allowed regions in ( T , N ) plot.Blue region shows that for H 2 (x h ) > 0. Red region shows (2.6) with s = 0.1.We also show the region (Yellow) where the heat capacity is negative and thus the spacetime is thermodynamically unstable.
The first inequality (2.9) means that the typical gravitational curvature scale ρ is much larger than the string scale so that stringy corrections are perturbative, and the second inequality (2.10) means that the string coupling is small enough such that string perturbation theory makes sense.
In our case, as ρ we may take the curvature scale of S 8 , so using the solution (2.4) we rephrase (2.9) and (2.10) as (2.12) These provides a region in the spacetime at which the string perturbation makes sense.
Because the left hand side of (2.11) has a positive power in x and that of (2.12) has a negative one, these inequalities provide the upper bound and the lower bound of x, respectively.
To evaluate the spacetime region concretely for our later purpose, we assume a threshold value r (< 1) for the left hand sides of the inequalities and define the upper bound x u and the lower bound x l for the radial coordinate x,6 horizon < l a t e x i t s h a 1 _ b a s e 6 4 = " f t 5 x P L q M 6 Z P y k I M M e F e G I u 5 Solutions of these equations for a given small r, we obtain a spacetime region at which the string perturbation expansion makes sense. 7Fig. 2 Left explains the inequalities for our choice of N = 456 and T = 0.02 with r = 0.1.
In summary, the quantum-corrected geometry (2.4) can be used for ( T , N ) satisfying (2.6) and (2.8), in the region (2.15).In the next section, we calculate the holographic Wilson loop by putting a probe string in the valid region of the spacetime given by a valid ( T , N ).

1/N corrections to Wilson loop
In this section, we calculate a holographic Wilson loop of the supersymmetric quantum mechanics at a finite temperature, using a string worldsheet in the quantum-corrected geometry (2.4).

Set-up for the Wilson loop
We follow the original proposal [13,21] for the holographic calculation of the Wilson loop.We have to make sure that the string worldsheet in the curved geometry exists only in the region where the calculation is valid, (2.15).For this purpose, we put two probe Dbranes at x = x u , and consider a fundamental string hanging down from there.See Fig. 2 Right.These D-branes can be D0-branes.In that case, the Wilson loop we consider is in a background of a nontrivial scalar expectation value: The (N + 2) × (N + 2) matrix Φ I is separated into SU (N ) sector and two U (1) sectors, and the vacuum expectation values φ I 1 and φ I 2 (I = 1, 2, • • • , 9) provide the location of the two probe D0-branes. 8We assume (φ I 1 ) 2 = (φ I 2 ) 2 , and the angle between the two vectors φ 1 and φ 2 is denoted as φ.
The Wilson loop operator relevant to this static string worldsheet is [13] where the contour C has a rectangular shape in x 0 and θ spacetime, of the size τ × φ.Here, θ is a coordinate for the equator of the spherical target space S 8 spanned by the angular part of the nine scalar fields Φ I .So, when dt/ds = 0, θ I (s) takes either φ I 1 /|φ 1 | or φ I 2 /|φ 2 |.This generalized Wilson loop corresponding to a fundamental string hanging down from the two separate probe D-branes was first considered in Ref. [13].We take a long rectangle limit τ → ∞ so that the Wilson loop has the meaning of the potential energy between two "W-bosons." The location of the two D0-branes is given by the vacuum expectation values φ I 1 and φ I 2 .To place these at x = x u in the holographic spacetime, we need a physical relation between the scalar field and the spacetime coordinate.The definition of x = x u is given in (2.13).This equation means that the curvature of the spacetime geometry is not large compared to stringy scale.More precisely, the amplitude of the worldsheet instanton wrapping an S 2 of the S 8 is 8 There should be a finite-temperature potential between the probe D0-branes and the N D0-branes, therefore the probe D0-branes are not stable.This problem would be absent for the case of other kinds of D-branes with different dimensionality.For example, one can additionally place probe D4-branes which form a bound state with the probe D0-branes, so that the location of the D0-branes in the target space can be fixed, like a flavor D-brane [22]. 9Note that the ordinary relation to identify 2πα |φ| as the bulk radial coordinate may be corrected by 1/N and the temperature, so in our setup to see the quantum gravity correction in the Wilson loop we do not use the ordinary relation.To find a relation between the vacuum expectation value and the bulk location, a physical observable is necessary, and here we propose that it could be the string worldsheet amplitudes.We do not know the precise analytic relation between our xu and |φ1|, and leave it for our future investigation.
x < l a t e x i t s h a 1 _ b a s e 6 4 = " K l J x = x u < l a t e x i t s h a 1 _ b a s e 6 4 = " u a 8 s i h 5 q O 3 l I 8 k v f N L j j + m K A p y c 7 / 7 n f O d + e 4 9 q q 0 L 1 2 O s G Z P a 2 j s 6 u + L d i Z 7 e v v 6 B 5 O D Q u m v 5 j s Z L m q V b z q a q u F w X J i 9 5 w t P 5 p u 1 w x V B 1 v q E e L g f 5 j Q p 3 X G G Z a 1 7 N 5 j u G s m + K P a E p H l G l 6 n y 1 w q F 2 E P 6 7 t N u K 2 J N 2 g c 9 3 V C t 0 V 9 0 e h 1 S p j D O H t k N e 2 E P 7 J Y 9 s f d f e 9 X D H o G X G q 1 q S 8 v t 8 s D x S P H t X 5 V B q 4 e D T 9 W f n j 3 s I R t 6 F e T d D p n g F F p L X z k 6 f S n O F c b r E + y K P Z P / S 9 Z k 9 3 Q C s / K q X e d 5 4 e I P P z a 5 q F E m u D 0 X D R q U / H 0 s P 8 H 6 V E a e z s j 5 m f T i r F I s 0 w v o S 0 + g H V N J P g < / l a t e x i t > horizon < l a t e x i t s h a 1 _ b a s e 6 4 = " f t 5 x P L q M 6 Z P y k I M M e F e G I u 5 < l a t e x i t s h a 1 _ b a s e 6 4 = " 9 k + j C M D g q h P 6 The bottom needs to satisfy x m > x l so that the string lies only in the valid spacetime region.

Evaluation of holographic Wilson loop and 1/N corrections
To calculate the string worldsheet area S NG , we note that there exists a turning point x = x m which determines the whole configuration of the string, see Fig. 3.The configuration of the string is given by a function θ(x) which can be obtained by integrating the Nambu-Goto equation of motion in the background geometry.Denoting t E as the Euclidean time, we find the worldsheet area of a string hanging down from the two D0-branes as Here, we have defined θ ≡ dθ/dx.The integrand does not depend on θ explicitly, so there exists a Noether invariant Since at the turning point x = x m we have dx/dθ = 0, this constant can be easily evaluated at x = x m .Using that, we can refine (3.4) so that the integrand is written only as an explicit function of x.The potential energy V ≡ lim τ →∞ S E /τ which is related to the Wilson loop as W (C) = e −τ V is obtained as For this to be interpreted as an observable in the quantum mechanics, we need to calculate the relation between x m and φ.It is obtained by an integration of θ obtained by (3.5) along the string.We find Both the potential V , (3.6), and the angle φ, (3.7), are expressed by x m , so eliminating x m from these two equations, we obtain the potential V (φ).
The purpose of our study is to compare the potential energy V 0 for the original large N limit with the metric (2.1) and the potential energy V for the metric with the 1/N correction, (2.4).To see it, here we write the expression for the large N limit: These are obtained just by replacing H 1 (x), H 2 (x) by H(x) and F 1 (x) by F (x). From these expressions we can calculate the potential energy V 0 (φ) for the large N limit.Let us calculate the change of the potential energy by the 1/N correction, Our procedures for numerically evaluating this correction are as follows.First, based on the argument given in Sec.2.2, we choose an appropriate set (N, T ) to determine the spacetime geometry.Next, we calculate x u and x l by solving (2.13) and (2.14) to find the valid region of the spacetime, as shown in Fig. 2. In the valid region we vary x m , and numerically calculate (3.6), (3.7), (3.8) and (3.9) for each x m comprehensively, to finally evaluate the quantity ∆V N, T (φ).
As an example, we choose (N, T ) = (456, 0.02), and show our result ∆V N, T in Fig. 4. For any value of φ the energy correction ∆V is found to be positive, thus the gravitational attraction is weakened by the quantum gravity correction.Therefore, we conclude that the   x p v d q s N q 9 l q q V a T a T p w p f Q 1 j 4 A / c u Z A A = = < / l a t e x i t > 1/N correction provides a repulsive force.For some other values of (N, T ) we evaluate the potential energy corrections and found again that they are positive, so, as far as we search, the result is robust.
In a sense it is reasonable to expect that the quantum gravity correction may work as a screening of the gravitational force, thus weakening the total gravitational effect.An interesting note is that in Ref. [6] the quantum gravity correction to the D0-brane potential due to the corrected spacetime (2.4) was found to be positive.This means that both the D0brane and the fundamental string feel a repulsive force by the quantum gravity correction of the spacetime.
Let us finally check that the calculated correction ∆V behaves correctly as 1/N 2 .The quantum gravity correction of the metric (2.4) is governed by the small parameter ≡ π 6 2 7 3 2 1 N 2 .So, the combination ∆V N, T / should not depend on N .In Fig. 5, we plot ∆V N, T / for N = 1050, 2735, 4000 with fixed T = 0.01.As expected, the plots with different N are found to be on top of each other.

Summary
In this paper we calculated the 1/N corrections to the rectangular Wilson loop in the SU (N ) quantum mechanics with 16 supercharges at finite temperature, by using the gauge/gravity correspondence.The 1/N correction corresponds to the quantum gravity correction in the gravity side, so we introduced the quantum corrected near horizon geometry of the black 0-brane solution (2.4) given in Ref. [6].We put a probe fundamental string in the geometry, then the traditional holographic dictionary provided in Refs.[13,21] gave us the expectation value of the 1/N corrected Wilson loop.For the configuration of our probe string, see Fig. 2 and Fig. 3.
For the holographic computations we needed to study the consistency conditions.First, we had to choose appropriate temperature and N as shown in Fig. 1 so that the quantum gravity corrections are dominant against other corrections (see (2.6)) and also that the spacetime metric is real, (2.7).Second, in some regions of the spacetime the background metric cannot be trusted as the correction overwhelmes the classical geometry, so we need to work in a restricted spacetime region (2.15).The conditions for the region are given by (2.9) and (2.10), and we adopt the threshold value r = 0.1 to set the boundaries of the region.This determines the end points of the probe string, which are on two probe D0-branes whose location corresponds to the vacuum expectation values of the scalar field determined by the magnitude of the worldsheet instantons.
Our final result for the 1/N correction ∆V to the potential energy (which is the negative logarithm of the Wilson loop) is shown in Fig. 4 Right.It turned out that the correction is positive for any angle φ between the two end points of the probe string.This means that the 1/N correction weakens the potential.In the gravity side, the quantum gravity correction works as a repulsive force, like a screening effect of the attractive gravitational force.
Finally, we make comments on future directions.The important check of holography concerning our results can be made by explicit calculations in the gauge theory side.The D0-brane system admits numerical calculations of the observables [23][24][25][26], so we hope to see how the quantum gravity effect may be seen in gauge theories.Due to the validity region of the spacetime, we had to put two probe D0-branes in the valid region so that the Euclidean string worldsheet lies safely for the calculation.The precise location of the probe D0-branes needs to be specified by the string instanton amplitudes, which would be a challenge for the precise numerical matching check of the AdS/CFT correspondence for our case.
The understanding of the quantum gravity corrections is quite essential in holography.For example, the correction to the entanglement entropy of the boundary theory is given by bulk spacetime entanglement [27].The corrections we considered in this paper has also been discussed in Ref. [27] as a sub-leading correction.A unified understanding of the quantum gravity corrections is necessary for a further investigation of the quantum gravity in the AdS/CFT correspondence, and our finding of the gravitational screening may serve as a hint for it.

A Quantum gravity corrections to the near horizon geometry
Here we provide an explicit expression of the quantum-corrected geometry (2.4) obtained in Ref. [6].The functions H i , F 1 used to define the geometry are given as  with the dimensionless Ũ0 ≡ U 0 /λ The functions H i and F 1 approach H and F in the limit N → ∞ or at large x.Near x ∼ 1, the correction terms are effective.See Fig. 6 for the behavior of the functions with the quantum corrections.
8 s D x S P H t X 5 V B q 4 e D T 9 W f n j 3 s I R t 6 F e T d D p n g F F p L X z k 6 f S n O F c b r E + y K P Z P / S 9 Z k 9 3 Q C s / K q X e d 5 4 e I P P z a 5 q F E m u D 0 X D R q U / H 0 s P 8 H 6 V E a e z s j 5 m f T i V D S y O E Y x h k m a y y w W s Y I c S t R R 4 A R n O J e G p K y 0 I C 2 1 S q V Y p B n G l 5 B W P w D o n J P p < / l a t e x i t > x = x l < l a t e x i t s h a 1 _ b a s e 6 4 = " r o 3 m 4 R d b i e b k 8 u 0 w

Figure 2 .
Figure 2. Left: Plot of the left hand sides of (2.11) and (2.12), for N = 456 and T = 0.02.A larger N results in a wider region in x.Right: Valid spacetime region (White) and our probe string configuration.The shaded regions are excluded for use as the string perturbation breaks down.

. 3 )
so the instanton correction is exp[−S inst ].This instanton correction should have a counterpart in the quantum mechanics, which in principle determines the vacuum expectation value |φ 1 | and |φ 2 |, even with the 1/N corrections, by the relation 2/r = S inst . 9 r 9 K 3 S r u i z O u 3 d n r a n V u g v G r 0 W K c O I s m d 2 x 7 r s i d 2 z F / b x a 6 + 2 1 8 P 1 0 qJ V 7 m m 5 W Q 6 e z m f e / 1 X V a X V w + K X 6 0 7 O D C t Y 9 r y p 5 N z 3 G P Y X S 0 z e P L 7 u Z j X S 0 v c R u 2 C v 5 v 2 Y d 9 k g n 0 J t v y m 2 K p 6 / + 8 G O S i x Z l 3 N u z c U K D E n + O p R / k 4 j F x J S a m V i O J u D + y M S x g E c s 0 l z U k s I s k s t S R 4 w z n u B C m h V V h U 9 j q l Q o D v m Y O3 0 L Y + Q T + 5 p I 4 < / l a t e x i t > V D S y O E Y x h k m a y y w W s Y I c S t R R 4 A R n O J e G p K y 0 I C 2 1 S q V Y p B n G l 5 B W P w D o n J P p < / l a t e x i t > x = x l < l a t e x i t s h a 1 _ b a s e 6 4 = " r o 3 m 4 R d b i e b k 8 u 0 w M 8 L L K y t o F 8 4 = " > A A A C k H i c h V H L S s N A F D 2 N r 1 p f V T e C m 2 J R X J W J C h Z B V N y I q z 6 M C i o l i a M O 5 k W S l t b S H 3 D j U s W V g g v x E 1 y 6 8 Q d c 9 B P E p Y I b F 9 6 k A V F R b 0 j m z L n 3 3 J y Z q z m G 8 H z G m j G pr b 2 j s y v e n e j p 7 e s f S A 4 O r X t 2 2 d W 5 o t u G 7 W 5 q q s c N Y X H F F 7 7 B N x 2 X q 6 Z m 8 A 3 t c D n I b 1 S 4 6 w n b

e l 1 SFigure 3 .
Figure 3.The configuration of the fundamental string in the space spanned by the coordinates (x, θ).string hangs down from the end points at x = x u .It reaches x = x m at the bottom.The bottom needs to satisfy x m > x l so that the string lies only in the valid spacetime region.
t e x i t s h a 1 _ b a s e 6 4 = " c z 9 W 0 / v v d p a L A X i 4 g u k w B K w b q t 4 = " > A A A C k X i c h V H L S s N Q E D 3 G 9 7 v q R n A j F s V V m a j 4 A q H o R h B E W 1 s F L S W J t x p N k 5C k h V r 8 A V f u R F 0 p u B A / w a U b f 8 B F P 0 F c V n D j w k k a E C 3 W C c k 9 9 8 y c y b l 3 V N v Q X Y + o 0 i Q 1 t 7 S 2 t X d 0 d n X 3 9 P b 1 R w Y G 0 6 5 V c D S R 0 i z D c n Z U x R W G b o q U p 3 u G 2 L E d o e R V Q 2 y r x y t + f r s o H F e 3 z C 2 v Z I t M X j k w 9 Z y u K R 5 T 6 f W l G S L K R q I U o y B G 6 4 E c g i j C 2 L A i j 9 j D P i x o K C A P A R M e Y w M K X H 5 2 I Y N g M 5 d B m T m H k R 7 k B U 7 R x d o C V w m u U J g 9 5 u 8 B 7 3 Z D 1 u S 9 3 9 M N 1 B r / x e D X Y e U o x u m F 7 q l K z / R A r / T 5 Z 6 9 y 0 M P 3 U u J V r W m F n e 0 / G 0 5 + / K v K 8 + r h 8 F v V 0 L O H H O Y D r z p 7 t w P G P 4 V W 0 x d P L q r J x c R 4 e Y J u 6 Y 3 9 3 1 C F n v g E Z v F d u 9 s U i e s G f m x 2 U e K M f 3 s u T n l Q 8 u + x 1 I P 0 V E y e j s m b M 9 H 4 b D i y D o x g D J M 8 l z n E s Y o N p L j j E c 5 x i S t p S F q Q 4 t J y r V R q C j V D + B H S 2 h e P Q Z N F < / l a t e x i t > N = 2735 < l a t e x i t s h a 1 _ b a s e 6 4 = " 2 N H A V r 8 Q q v f w M o u j r s / u n W T o k A 4 = " > A A A C k X i c h V H L S s N A F D 2 N 7 3 f V j e B G L I q r M v G t I B T d C I L 0 Y a t Q R Z I 4 r d G 8 S K a F W v w B V + 5 E X S m 4 E D / B p R t / w E U / Q V w q u H H h T R o Q L e o Ny Z w 5 9 5 6 b M 3 N V x 9 A 9 w V g t I j U 1 t 7 S 2 t X d 0 d n X 3 9 P Z F + w d y n l 1 y N Z 7 V b M N 2 t 1 T F 4 4 Z u 8 a z Q h c G 3 H J c r p m r w T f V w x c 9 v l r n r 6 b a 1 I S o O 3 z G V o q U X d E 0 R R O X W l y b n p m Z 2 o z E W Z 0 G M N A I 5 B D G E k b S j 9 9 j G H m x o K M E E h w V B 2 I A C j 5 4 8 Z D A 4 x O 2 g S p x L S A / y H M f o J G 2 J q j h V K M Q e 0 r d I u 3 z I W r T 3 e 3 q B W q O / G P S 6 p B z B G H t i t + y V P b I 7 9 s w + f u 1 V D X r 4 X i q 0 q n U t d 3 b 7 T o Y y 7 / + q T F o F 9 r 9 U f 3 o W K G A + 8 K q T d y d g / F N o d X 3 5 6 O w 1 s 5 g e q 4 6 z a / Z C / q 9 Y j T 3 Q C a z y m 3 a T 4 u n L P / w 4 5 K J C G f / 2 P B z T o O S f Y 2 k E u c m 4 P B W X U 9 O x x G w 4 s n Y M Y x Q T N J c 5 J L C K J L L U 8 Q C n O M e F N C g t S A l p u V 4 q R U L N I L 6 F t P Y J q 1 S T U g = = < / l a t e x i t > N = 1050 < l a t e x i t s h a 1 _ b a s e 6 4 = " 7 / V u u D Y D T 4 M L 4 9 3 e s E y P k I 0 r x B 1 z 4 C e J S w Y 0 L J 2 l A t F g n J P f c M 3 M m 5 9 5 R b U N 3 P a L n B q m x q b m l t a 2 9 o 7 O r u 6 c 3 0 t e f d K 2i o 4 m E Z h m W k 1 I V V x i 6 K R K e 7 h k i Z T t C K a i G 2 F E P l / 3 8 T k k 4 r m 6 Z 2 1 7 Z F p m C k j f 1 n K 4 p H l P J t U W Z p i k b i V K M g h i u B X I I o g h j 3 Y r c Y x d 7 s K C h i A I E T H i M D S h w + U l D B s F m L o M K c w 4 j P c g L H K O D t U W u E l y h M H v I 3 z z v 0 i Fr 8 t 7 v 6 Q Z q j f 9 i 8 O u w c h i j 9 E S 3 9 E a P d E c v 9 P l n r 0 r Q w / d S 5 l W t a o W d 7 T 0 Z 3 P r 4 V 1 X g 1 c P + t 6 q u Z w 8 5 z A V e d f Z u B 4 x / C q 2 q L x 2 d v W 0 t b I 5 W x u i a X t n / F T 3 T A 5 / A L L 1 r N x t i 8 7 K O H 5 t d l D n j 3 5 6 L Y x 6 U / H s s t S A 5 E Z M n Y / L G V D Q + E 4 6 s D U M Y w T j P Z R Z x r G A d C e 5 4 g F O c 4 0 I a k O a l u L R U L Z U a Q s 0 A f o S 0 + g W T j Z N H < / l a t e x i t > V/✏ < l a t e x i t s h a 1 _ b a s e 6 4 = " L 8 9 v f B Z 3 q s L q O o D F i 5 I 8 y S B Y F w 6 O X 5 Y m F / s r A + y c P Z P / M / b I 7 u g E d u n V u l j g i y d / + H H J R Z k y w e 3 5 O K R B 6 d / H 8 h P k h t P 6 S F p f G E 1 N j U U j i 6 E H f R i k u Y x j C n P I I E s d 9 3 G K S 1

Figure 5 .
Figure 5. Plot of ∆V N, T / for N = 1050, 2735, 4000 with fixed T = 0.01.share the same N 2 dependence, as a check of our numerical calculations.

Figure 6 .
Figure 6.The behavior of the functions in the metric components.H(x) is the classical geometry without the quantum correction, and H 1 (x), H 2 (x) and H 3 (x) are with the corrections.Left: The case with N = 456 and T = 0.02.Right: The case with N = 20000 and T = 0.002.