![]() The method is tailored specifically to the rectangular-groove profile and is one of the few modal expansion techniques appropriate to non-perfectly conducting gratings. The assumption of perfect conductivity is relaxed in a formalism which is described for dielectric and lossy metallic surfaces. Their regions of accuracy and validity are determined. ![]() These approximations aid in the examination of resonances and other spectral phenomena. Single and bi-modal expansions are shown to provide useful field approximations for not only the conventional rectangular-groove grating, but also for two of the three related structures. The third structure is a stepped reflection grating which proves capable of accurately mode l1 i ng the performance of general profile gratings including those with sinusoidal and triangular profi 1 es. Tuning of the various grating parameters governs the behaviour of the resonances and indicates the potential use of these devices as a type of reflecting Fabry-Perot interferometer. Two of these structures consist of a transmission grating on a reflecting element, and are shown to exhibit a pronounced resonance action. The theoretical treatment for the rectangular-groove grating is adapted to account for the diffraction properties of three unusual profiles which also possess a rectangular geometry. These ideas are usefully extended throughout the thesis to encompass the behaviour of all gratings. They also provide new insight into the understanding of this grating 1s overall behaviour, including its blazing and passing-off properties in the first-order Littrow mounting. Intensive studies reveal an alternative approach to the concept of diffraction resonance anomalies. Initial theoretical investigations concern the rectangular-groove grating. ![]() The advantages that modal treatments have over these methods are explained, and previous applications of the former are summarised. Several of the established formalisms, based on a variety of nonmodal techniques, are reviewed, and the essence of their method described. However, in two cases one or other of these constraints is removed. Most of the formalisms pertain to gratings having specific groove geometries and infinitely-conducting surfaces. Both reflection and transmission gratings are considered, and although emphasis is given to a theoretical study of the formalisms, many numerical results obtained with the latter are also presented. This thesis reports on the analysis and development of rigorous modal expansion techniques for determining the scattering properties of singly-periodic diffraction gratings. ![]()
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