A determinantal formula for the GOE Tracy-Widom distribution

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A determinantal formula for the GOE Tracy-Widom distribution Patrik L. Ferrari and Herbert Spohn Technische Universität München Zentrum Mathematik and Physik Department e-mails: ferrari@ma.tum.de, spohn@ma.tum.de 4th May 005 Abstract Investigating the long time asymptotics of the totally asymmetric simple exclusion process, Sasamoto obtains rather indirectly a formula for the GOE Tracy-Widom distribution. We establish that his novel formula indeed agrees with more standard expressions. 1 Introduction The Gaussian orthogonal ensemble (GOE) of random matrices is a probability distribution on the set of N N real symmetric matrices defined through Z 1 e Tr(H )/4N dh. (1) Z is the normalization constant and dh = 1 i j N dh i,j. The induced statistics of eigenvalues can be studied through the method of Pfaffians. Of particular interest for us is the statistics of the largest eigenvalue, E 1. As proved by Tracy and Widom [8], the limit lim È( E 1 N + sn 1/3) = F 1 (s) () N exists, È being our generic symbol for probability of the event in parenthesis. F 1 is called the GOE Tracy-Widom distribution function. Following [3] it can be expressed in terms of a Fredholm determinant in the Hilbert space L (Ê) as follows, F 1 (s) = det ( ½ P s (K + g f )P s ), (3) 1

where K is the Airy kernel defined through K(x, y) = dλ Ai(x + λ) Ai(y + λ), g(x) = Ai(x), (4) f(y) = 1 dλ Ai(y + λ), and P s is the projection onto the interval [s, ). The GOE Tracy-Widom distribution F 1 (s) turns up also in the theory of one-dimensional growth process in the KPZ universality class, KPZ standing for Kardar-Parisi-Zhang [4]. Let us denote the height profile of the growth process at time t by h(x, t), either x Ê or x. One then starts the growth process with flat initial conditions, meaning h(x, 0) = 0, and considers the height above the origin x = 0 at growth time t. For large t it is expected that h(0, t) = c 1 t + c t 1/3 ξ 1. (5) Here c 1 and c are constants depending on the details of the model and ξ 1 is a random amplitude with È(ξ 1 s) = F 1 (s). (6) For the polynuclear growth (PNG) model the height h(0, t) is related to the length of the longest increasing subsequence of symmetrized random permutations [5], for which Baik and Rains [1] indeed prove the asymptotics (5), (6), see [] for further developments along this line. Very recently Sasamoto [6] succeeds in proving the corresponding result for the totally asymmetric simple exclusion process (TASEP). If η j (t) denotes the occupation variable at j at time t, then the TASEP height is given by N t + j i=1 (1 η i(t)) for j 1, h(j, t) = N t for j = 0, N t (7) 0 i=j+1 (1 η i(t)) for j 1, with N t denoting the number of particles which passed through the bond (0, 1) up to time t. The flat initial condition for the TASEP is... 0 1 0 1 0 1.... For technical reasons Sasamoto takes instead...010100000... and studies the asymptotics of h( 3t/, t) for large t with the result h( 3t/, t) = 1t + 1 t1/3 ξ SA. (8)

The distribution function of the random amplitude ξ SA is with È(ξ SA s) = F SA (s) (9) F SA (s) = det(½ P s AP s ). (10) Here A has the kernel A(x, y) = 1 Ai((x+y)/) and, as before, the Fredholm determinant is in L (Ê). The universality hypothesis for one-dimensional growth processes claims that in the scaling limit, up to model-dependent coefficients, the asymptotic distributions are identical. In particular, since (5) is proved for PNG, the TASEP with flat initial conditions should have the same limit distribution function, to say F SA (s) = F 1 (s). (11) Our contribution provides a proof for (11). The identity As written above, the s-dependence sits in the projection P s. It will turn out to be more convenient to transfer the s-dependence into the integral kernel. From now on the determinants are understood as Fredholm determinants in L ( ) with scalar product,. Thus, whenever we write an integral kernel like A(x, y), the arguments are understood as x 0 and y 0. Let us define the operator B(s) with kernel B(s)(x, y) = Ai(x + y + s). (1) By [7] B(s) < 1 and clearly B(s) is symmetric. Thus also B(s) < 1 for all s. B(s) is trace class with both positive and negative eigenvalues. Shifting the arguments in (10) by s, one notes that Applying the same operation to (3) yields with F SA (s) = det(½ B(s)). (13) F 1 (s) = det ( ½ B(s) g f ) (14) g(x) = Ai(x + s) = (B(s)δ)(x), (15) f(y) = 1 dλ Ai(y + λ + s) = ((½ B(s))1)(y). 3

Here δ is the δ-function at x = 0 and 1 denotes the function 1(x) = 1 for all x 0. δ and 1 are not in L ( ). Since the kernel of B(s) is continuous and has super-exponential decay, the action of B(s) is unambiguous. Proposition 1. With the above definitions we have det(½ B(s)) = F 1 (s). (16) Proof. For simplicity we suppress the explicit s-dependence of B. We rewrite F 1 (s) = det ( (½ B)(½ + B Bδ 1 ) ) = det(½ B) det(½ + B) ( 1 δ, B(½ + B) 1 1 ) = det(½ B) det(½ + B) δ, (½ + B) 1 1 (17) since 1 = δ, 1. Thus we have to prove that det(½ B) = det(½ + B) δ, (½ + B) 1 1. (18) Taking the logarithm on both sides, ln det(½ B) = ln det(½ + B) + ln δ, (½ + B) 1 1, (19) and differentiating it with respect to s results in Tr ( (½ B) 1 s B)) = Tr ( (½ + B) 1 s B)) + s δ, (½ + B) 1 1 δ, (½ + B) 1 1 (0) where we used d ds ln(det(t)) = Tr ( T 1 s T). (1) Since B(s) 0 as s, the integration constant for (0) vanishes and we have to establish that Tr ( (½ B ) 1 s B)) = δ, s (½ + B) 1 1 δ, (½ + B) 1 1. () Define the operator D = d. Then using the cyclicity of the trace and dx Lemma, Tr ( (½ B ) 1 s B)) = Tr ( (½ B ) 1 DB) ) Using Lemma 3 and D1 = 0, one obtains = δ, (½ B ) 1 Bδ. (3) δ, s (½ + B) 1 1 = δ, (½ B ) 1 Bδ δ, (½ + B) 1 1. (4) Thus () follows from (3) and (4). 4

Lemma. Let A be a symmetric, trace class operator with smooth kernel and let D = d dx. Then Tr(DA) = δ, Aδ (5) where DA is the operator with kernel A(x, y). x Proof. The claim follows from spectral representation of A and the identity dxf (x)f(x) = f(0)f(0) dxf(x)f (x). (6) Lemma 3. It holds s (½ + B) 1 = (½ B ) 1 BD + (½ B ) 1 Bδ δ(½ + B) 1. (7) Proof. First notice that B Ḃ = DB. For any test function f, s Ê (Ḃf)(x) = dy y Ai(x + y + s)f(y) + = Ai(x + s)f(0) dy Ai(x + y + s)f (y). (8) Thus, using the notation P = Bδ δ, one has DB = BD P. (9) Since B < 1, we can expand s (½ + B) 1 in a power series and get s (½ + B) 1 = ( 1) n s Bn = n 1 n 1 Using recursively (9) we obtain n 1 B k DB n k k=0 = 1 ( 1)n n 1 B n D + ( 1) n n 1 j=0 k=j = 1 ( 1)n n 1 B n D + k=0 B k DB n k. (30) k=0 Inserting (31) into (30) and exchanging the sums results in (½ + B) 1 = s n 1 B n+1 D + k 0 n k+1 n 1 ( 1) j+1 B k PB n k 1 1 + ( 1) k B k PB n k 1. (31) 1 + ( 1) k B k P( B) n (k+1) = (½ B ) 1 BD + (½ B ) 1 P(½ + B) 1. (3) 5

3 Outlook The asymptotic distribution of the largest eigenvalue is also known for Gaussian unitary ensemble of Hermitian matrices (β = ) and Gaussian symplectic ensemble of quaternionic symmetric matrices (β = 4). As just established, for β = 1, F 1 (s) = det(½ B(s)), (33) and, for β =, F (s) = det(½ B(s) ), (34) which might indicate that F 4 (s) equals det(½ B(s) 4 ). This is however incorrect, since the decay of det(½ B(s) 4 ) for large s is too rapid. Rather one has F 4 (s/ ) = 1 ) det(½ B(s)) + det(½ + B(s)). (35) ( This last identity is obtained as follows. Let U(s) = 1 q(x)ds with q the s unique solution of the Painlevé II equation q = sq + q 3 with q(s) Ai(s) as s. Then the Tracy-Widom distributions for β = 1 and β = 4 are given by F 1 (s) = exp( U(s))F (s) 1/, F 4 (s/ ) = cosh(u(s))f (s) 1/, (36) see [8]. Thus F 4 (s/ ) = 1 (F 1(s)+F (s)/f 1 (s)), from which (35) is deduced. References [1] J. Baik and E.M. Rains, Symmetrized random permuations, Random Matrix Models and Their Applications, vol. 40, Cambridge University Press, 001, pp. 1 19. [] P.L. Ferrari, Polynuclear growth on a flat substrate and edge scaling of GOE eigenvalues, Comm. Math. Phys. 5 (004), 77 109. [3] P.J. Forrester, Painlevé trascendent evaluation of the scaled distribution of the smallest eigenvalue in the Laguerre orthogonal and symplectic ensembles, arxiv:nlin.si/0005064 (000). [4] K. Kardar, G. Parisi, and Y.Z. Zhang, Dynamic scaling of growing interfaces, Phys. Rev. Lett. 56 (1986), 889 89. [5] M. Prähofer and H. Spohn, Universal distributions for growth processes in 1 + 1 dimensions and random matrices, Phys. Rev. Lett. 84 (000), 488 4885. 6

[6] T. Sasamoto, Spatial correlations of the 1D KPZ surface on a flat substrate, arxiv:cond-mat/0504417 (005). [7] C.A. Tracy and H. Widom, Level-spacing distributions and the Airy kernel, Comm. Math. Phys. 159 (1994), 151 174. [8] C.A. Tracy and H. Widom, On orthogonal and symplectic matrix ensembles, Comm. Math. Phys. 177 (1996), 77 754. 7

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