Spatial dispersion in incommensurately modulated insulators

Abstract: Peculiarities of the non-local responses of spatially inhomogeneous insulating media to electromagnetic waves are considered within a phenomenological approach. In the case of a weak spatial dispersion (SD), a ‘quasi-local’ constitutive equation is derived, which allows one to isolate the effects of SD in relation to non-uniformities of the wavefield and the material properties of the medium. The symmetry of the material tensors is clarified. The material contribution to the SD suggests a novel mechanism for o… Show more

“…For example, from the perspective of general thermodynamics, see [29], [30]. Some of the topics reexamined within the framework of a general nonlocal fieldmatter interaction theory include the applicability of optical reciprocity theorems [31]- [34], energy/power balance [35], quantization [36]- [38], operator methods [39], extension of spatial dispersion to include inhomogeneous media [12], and alternative formulations of spatial dispersion in terms of the Jones calculus [40].…”

“…Quasi-inhomogeneous or smoothly-inhomogeneous nonlocal media are some of the simplest possible prototypes of general (inhomogeneous) nonlocal materials where the spatial dispersion model ε(k) with only a dependence on one variable k is not adequate to the description of the physics of the problem [12], [39]. In general, there has been quite few investigations aimed at going beyond spatial dispersion in homogeneous media.…”

A Superspace Formalism for the Electromagnetism of Generic Nonlocal Continuous Metamaterials: Principal Structures and Applications

“…For example, from the perspective of general thermodynamics, see [29], [30]. Some of the topics reexamined within the framework of a general nonlocal fieldmatter interaction theory include the applicability of optical reciprocity theorems [31]- [34], energy/power balance [35], quantization [36]- [38], operator methods [39], extension of spatial dispersion to include inhomogeneous media [12], and alternative formulations of spatial dispersion in terms of the Jones calculus [40].…”

“…Quasi-inhomogeneous or smoothly-inhomogeneous nonlocal media are some of the simplest possible prototypes of general (inhomogeneous) nonlocal materials where the spatial dispersion model ε(k) with only a dependence on one variable k is not adequate to the description of the physics of the problem [12], [39]. In general, there has been quite few investigations aimed at going beyond spatial dispersion in homogeneous media.…”

A Superspace Formalism for the Electromagnetism of Generic Nonlocal Continuous Metamaterials: Principal Structures and Applications

“…which is the standard constitutive relation of linear electromagnetic materials. Clearly, (12) says that only the exciting field F(r) data at r is needed to induce a response at the same location. In a nutshell, locality implies that the natural configuration space of the electromagnetic problem is just the point-like spacetime manifold D ⊂ R 3 or the entire Euclidean space R 3 .…”

“…In general, dealing with topics such as supergravity, supersymmetry, superfields, superstrings, and noncommutative geometry often requires the use of one superspace formalism or another [8]. More related to the subject of nonlocal MTMs is the original superspace concept introduced earlier for the analysis of deformed crystal [11] and subsequently utilized for fundamental investigations of EM nonlocality in incommensurate (IC) superstructures in insulators [12]. Such modulatedstructure materials possess spaces with dimensions greater than spacetime [13].…”

A Superspace Formalism for the Electromagnetism of Generic Nonlocal Continuous Metamaterials: Principal Structures and Applications

“…The relation between the competing periods d, (d′) and δ plays an important role in the response of the structure to an incoming electromagnetic wave. Previous evidence shows that the modulation has a profound impact on the unmodulated EBGs [10,11]. One of the effects is the splitting in a (large) number of new EBGs [7].…”

Band pattern of commensurate modulated periodic structures