Field patterns without blow up

• Published in: New journal of physics Vol. 19; no. 9; pp. 93022 - 93037
• Main Authors: Mattei, Ornella, Milton, Graeme W
• Format: Journal Article
• Language: English
• Published: Bristol IOP Publishing 28.09.2017
• Subjects: Coupled modes; Eigenvalues; Eigenvectors; field patterns; Inclusions; Mathematical analysis; Matrix methods; Periodic variations; Physics; Propagation modes; space-time microstructures; Spacetime; symmetry; Transfer matrices; wave equations; Wave fronts; Wave propagation
• ISSN: 1367-2630; 1367-2630
• DOI: 10.1088/1367-2630/aa847d

Field patterns, first proposed by the authors in Milton and Mattei (2017 Proc. R. Soc. A 473 20160819), are a new type of wave propagating along orderly patterns of characteristic lines which arise in specific space-time microstructures whose geometry in one spatial dimension plus time is somehow commensurate with the slope of the characteristic lines. In particular, in Milton and Mattei (2017 Proc. R. Soc. A 473 20160819) the authors propose two examples of space-time geometries in which field patterns occur: they are two-phase microstructures in which rectangular space-time inclusions of one material are embedded in another material. After a sufficiently long interval of time, field patterns have local periodicity both in time and space. This allows one to focus only on solving the problem on the discrete network on which a field pattern lives and to define a suitable transfer matrix that, given the solution at a certain time, provides the solution after one time period. For the aforementioned microstructures, many of the eigenvalues of this   -symmetric transfer matrix have unit norm and hence the corresponding eigenvectors correspond to propagating modes. However, there are also modes that blow up exponentially with time coupled with modes that decrease exponentially with time. The question arises as to whether there are space-time microstructures such that the transfer matrix only has eigenvalues on the unit circle, so that there are no growing modes (modes that blow-up)? The answer is found here, where we see that certain space-time checkerboards have the property that all the modes are propagating modes, within a certain range of the material parameters. Interestingly, when there is no blow-up, the waves generated by an instantaneous disturbance at a point look like shocks with a wake of oscillatory waves, whose amplitude, very remarkably, does not tend to zero away from the wave front.