It is proposed that the statistics of the inertial range of fully developed turbulence can be described by a quantized random multiplicative process. We then show that (i) the cascade process must be a loginfinitely divisible stochastic process (i.e., stationary independent log-increments); (ii) the inertial-range statistics of turbulent fluctuations, such as the coarse-grained energy dissipation, are log-Poisson; and (iii) a recently proposed scaling model [Z.-S. She and E. Leveque 72, 336 (1994)] of fully developed turbulence can be derived. A general theory using the Levy-Khinchine representation for infinitely divisible cascade processes is presented, which allows for a classification of scaling behaviors of various strongly nonlinear dissipative systems. PACS numbers: 47.27.Gs, 47.27.TeThe statistics of fully developed turbulence exhibit certain universal features as a result of strong nonlinear interactions. One set of intriguing quantities characterizing universal behavior of turbulent flows is a set of scaling exponents for two-point correlation functions, e.g. , g"of the velocity structure functions defined by an expressionset of quantities is an exponent~p for pth-order moment of locally averaged energy dissipation e over a ball of size 4: (et") -8". The range of the length scale 8 for the above power-law behavior to be valid is called an inertial range. Kolmogorov's refined similarity hypothesis[1] provides a relation between these two sets of quantities: g"= p/3 + r"t3. This Letter addresses a predictive model [2] of g"and r". Note that g2 characterizes the scaling for the kinetic energy fluctuations and is directly related to the exponent for the kinetic energy spectrum E(k) -k:n =1+ j2.During the past half century since Kolmogorov's 1941 seminal work [3] that predicts r"= 0 and g"= p/3, there has been a continual effort to experimentally determine the values of g"or r". There is now strong evidence [4 -7] that g"W p/3, which is usually referred to as the intermittency effects or anomalous scaling exponents. Many theoretical models have been proposed to address this phenomenon. Some approaches start with an ansatz of probability density function (PDF) of et such as the log-normal model [2] or a log-stable model [8], for example. Others [9 -12] propose discrete random multiplicative processes (RMP) modeling the energy cascade. The stochastic process that generates the energy cascade is furnished by random multiplicative factors Wt, t, relating the fluctuations of e~at two different length scales 8]and Zz. et, = Wq, t, et, . By construction, the multiplicative factor is independent of ez, . The probability distribution of Wt, t, determines r", since it is required that log(Wt", t, )/ log(82/Zi) = r". Existing cascade models of random multiplicative processes [10 -12] are obtained by making an ad hoc ansatz for the PDF of lVt, t, being composed of a certain number of discrete atoms described by one or more adjustable parameters. The parameters in the models are difficult to determine by plausible phys...
