From Gaussian to Gumbel: extreme eigenvalues of complex Ginibre products with exact rates

Abstract

We consider the product of \(kn\) independent \(n× n\) complex Ginibre matrices and denote its eigenvalues by \(Z1,… ,Zn\). Let \(α = n∞ n / kn\). Using the determinantal point process method, we reduce the study of extremal eigenvalues to the evaluation of determinants of certain \(n× n\) matrices. In the modulus case, rotational invariance makes the relevant matrix diagonal, which yields a product representation in terms of Gamma tail probabilities. In the real-part case, the matrix is no longer diagonal; we handle this by a polar-coordinate reduction that introduces an independent uniform angle and leads to explicit formulas involving Gamma variables and trigonometric integrals. After appropriate rescaling, the spectral radius \(1≤ j≤ n|Zj|\) converges weakly to a nontrivial distribution \(α\) when \(α ∈ (0, +∞)\), to the Gumbel distribution when \(α = +∞\), and to the standard normal distribution when \(α = 0\). The family \(\α\α >0\) extends continuously to the boundary regimes: \(α\) converges weakly to the standard normal law as \(α 0+\) and to the Gumbel law as \(α +∞\). Thus the three limiting regimes are connected by the single parameter \(α\), yielding a continuous transition from Gaussian to Gumbel distribution. For the spectral radius, we obtain the exact rates of convergence both in the fixed-\(α\) regime and at the boundaries \(α = 0\) and \(α = +∞\). For the rightmost eigenvalue \(1≤ j≤ n Zj\), we establish the convergence rates in the boundary regimes, while for \(α ∈ (0, +∞)\) we show that the limiting distribution, though not available in closed form, still interpolates continuously between the normal and Gumbel laws.