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Literature DB >> 28137872

Mermin-Wagner fluctuations in 2D amorphous solids.

Bernd Illing¹, Sebastian Fritschi¹, Herbert Kaiser¹, Christian L Klix¹, Georg Maret¹, Peter Keim².

Abstract

In a recent commentary, J. M. Kosterlitz described how D. Thouless and he got motivated to investigate melting and suprafluidity in two dimensions [Kosterlitz JM (2016) J Phys Condens Matter 28:481001]. It was due to the lack of broken translational symmetry in two dimensions-doubting the existence of 2D crystals-and the first computer simulations foretelling 2D crystals (at least in tiny systems). The lack of broken symmetries proposed by D. Mermin and H. Wagner is caused by long wavelength density fluctuations. Those fluctuations do not only have structural impact, but additionally a dynamical one: They cause the Lindemann criterion to fail in 2D in the sense that the mean squared displacement of atoms is not limited. Comparing experimental data from 3D and 2D amorphous solids with 2D crystals, we disentangle Mermin-Wagner fluctuations from glassy structural relaxations. Furthermore, we demonstrate with computer simulations the logarithmic increase of displacements with system size: Periodicity is not a requirement for Mermin-Wagner fluctuations, which conserve the homogeneity of space on long scales.

Keywords: 2D ensembles; Mermin–Wagner fluctuations; confined geometry; glass transition; phase transition

Year: 2017 PMID： 28137872 PMCID： PMC5338416 DOI： 10.1073/pnas.1612964114

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

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