Your search keyword '"Karin A. Dahmen"' showing total 2 results

1. The duration-energy-size enigma for acoustic emission

Author

Ekhard K. H. Salje, Karin A. Dahmen, Boyuan Gou, Blai Casals, Spencer Rooke, Salje, Ekhard [0000-0002-8781-6154], and Apollo - University of Cambridge Repository

Subjects

639/301/119/996, Ferroelectrics and multiferroics, Science, 02 engineering and technology, 01 natural sciences, Article, symbols.namesake, Computer Science::Hardware Architecture, 0103 physical sciences, Pareto distribution, 010306 general physics, Condensed-matter physics, 40 Engineering, Computer Science::Cryptography and Security, Physics, 639/301/119/2795, Multidisciplinary, 639/301, AMAX, Acoustic wave, 021001 nanoscience & nanotechnology, Materials science, Computational physics, Amplitude, Phase transitions and critical phenomena, Mean field theory, Acoustic emission, Rise time, 4015 Maritime Engineering, symbols, 639/301/119, Medicine, 0210 nano-technology, 51 Physical Sciences, Energy (signal processing)

Abstract

Acoustic emission (AE) measurements of avalanches in different systems, such as domain movements in ferroics or the collapse of voids in porous materials, cannot be compared with model predictions without a detailed analysis of the AE process. In particular, most AE experiments scale the avalanche energy E, maximum amplitude Amax and duration D as E ~ Amaxx and Amax ~ Dχ with x = 2 and a poorly defined power law distribution for the duration. In contrast, simple mean field theory (MFT) predicts that x = 3 and χ = 2. The disagreement is due to details of the AE measurements: the initial acoustic strain signal of an avalanche is modified by the propagation of the acoustic wave, which is then measured by the detector. We demonstrate, by simple model simulations, that typical avalanches follow the observed AE results with x = 2 and ‘half-moon’ shapes for the cross-correlation. Furthermore, the size S of an avalanche does not always scale as the square of the maximum AE avalanche amplitude Amax as predicted by MFT but scales linearly S ~ Amax. We propose that the AE rise time reflects the atomistic avalanche time profile better than the duration of the AE signal.

Published

2021

2. Period multiplication cascade at the order-by-disorder transition in uniaxial random field XY magnets

Author

Sayan Basak, Erica Carlson, and Karin A. Dahmen

Subjects

Physics, Multidisciplinary, Random field, Condensed matter physics, Field (physics), Science, General Physics and Astronomy, General Chemistry, Nonlinear phenomena, Classical XY model, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, 010305 fluids & plasmas, Magnetic field, Phase transitions and critical phenomena, Cascade, Critical point (thermodynamics), Magnet, Limit cycle, 0103 physical sciences, lcsh:Q, lcsh:Science, 010306 general physics

Abstract

Uniaxial random field disorder induces a spontaneous transverse magnetization in the XY model. Adding a rotating driving field, we find a critical point attached to the number of driving cycles needed to complete a limit cycle, the first discovery of this phenomenon in a magnetic system. Near the critical drive, time crystal behavior emerges, in which the period of the limit cycles becomes an integer n > 1 multiple of the driving period. The period n can be engineered via specific disorder patterns. Because n generically increases with system size, the resulting period multiplication cascade is reminiscent of that occurring in amorphous solids subject to oscillatory shear near the onset of plastic deformation, and of the period bifurcation cascade near the onset of chaos in nonlinear systems, suggesting it is part of a larger class of phenomena in transitions of dynamical systems. Applications include magnets, electron nematics, and quantum gases., In the XY model, the application of a disordered uniaxial magnetic field leads to a long range magnetic order. Here, using a numerical approach, the authors find that at a critical rotating driving field, the number of driving cycles needed to complete a limit cycle diverges.

Published

2020