Mafic Microgranular Enclaves (MME) are commonly observed in mixed/mingled rocks in intrusive calc-alkaline suites. Analysis of MME from the Sithonia Plutonic Complex (Northern Greece) was carried out using a new method, based on the acquisition of X-ray maps of chemical elements within enclave thin sections, and by calculating the degree of compositional disorder (S) attained by enclaves during magma interactions. Results show that the compositional disorder of MME is linearly correlated with the geochemical evidence of magma mixing (e.g. the variation of CaO in MME) during the first stages of the magma interaction process. As the intensity of magma interaction increases, S stabilises toward an asymptotic constant value. In addition, the degree of compositional disorder for the different chemical elements increases at different rates for the same degree of magma mixing.

We suggest that S depends on the different paths of geochemical evolution of MME, and that it is related to the infiltration of portions of felsic magma, within MME, that provoke increasing degrees of dilution of the enclave mafic magma. This process is simulated using a chaotic dynamical system in which the dispersal of felsic magma occurs within the enclave mafic magna. As observed in natural rocks, the degree of compositional disorder of the simulated systems increases linearly during the first steps of the process and, as the mixing intensity increases, stabilises towards an asymptotic constant value. The greater the contrast in content of chemical elements between the felsic and the mafic magma the faster S changes. This result can explain the different rates of increase of the parameter S for the different chemical elements observed in natural MME.

The method utilised to estimate S for MME is a useful technique that provides information on the degree of mixing exhibited by mafic microgranular enclaves. Such information, integrated with more conventional petrological techniques, can lead to a better understanding of mixing processes between felsic and mafic magmas.

The method has many potential applications in petrology since it is robust and can be used for accurate and reliable investigations of the degree of homogeneity of rock samples and permits fast detailed analyses of sample areas, taking into account the spatial relationships among the phases constituting the sample.

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