Subcritical Gaussian Multiplicative Chaos in the Wiener Space: Construction, Moments and Volume Decay

Abstract

We construct and study properties of an infinite dimensional analog of Kahane's theory of Gaussian multiplicative chaos K85. Namely, if HT(ω) is a random field defined w.r.t. space-time white noise B and integrated w.r.t. Brownian paths in d≥ 3, we consider the renormalized exponential, weighted w.r.t. the Wiener measure P0. We construct the almost sure limit μγ in the entire weak disorder (subcritical) regime and call it subcritical GMC on the Wiener space. We show that μγ\ω: T∞ HT(ω)T(φφ)(0) γ\=0 almost surely, meaning, μγ is supported only on γ- thick paths, and consequently, the normalized version is singular w.r.t. the Wiener measure. We characterize uniquely the limit μγ w.r.t. the mollification scheme φ in the sense of Shamov S14 and the random rooted measure Qμγ(d B dω)= μγ(dω, B)P(d B). We then determine the fractal properties of the measure around γ-thick paths: -C2 ≤ r 0 r2 μγ(\|ω\| < r) ≤ r 0η r2 μγ(\|ω-η \| < r) ≤ -C1 w.r.t a weighted norm \|·\|. Here C1>0 and C2<∞ are the uniform upper (resp. pointwise lower) H\"older exponents which are explicit in the entire weak disorder regime. Moreover, they converge to the scaling exponent of the Wiener measure as the disorder approaches zero. Finally, we establish negative and Lp (p>1) moments for the total mass of μγ in the weak disorder regime.

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