The present disclosure concerns a means to use at least a form of electromagnetic excitation or light-matter interaction, including solar or
laser energy to generate localized conditions that enable
initiation and spatial and temporal control of
catalysis, chemical reactions, deposition, synthesis,
photocatalysis, electrocatalysis and catalytic processes.
Initiation and spatial and temporal control may be obtained by restricting and directing the electromagnetic excitation or light-matter interactions to specific objects or features embedded or located in or on a host matrix material or substrate. In some implementations this provides a means to use electromagnetic excitation to initiate and control
chemical synthesis or reactions without entirely or partially heating any of or all of the
reaction chamber, reactor
mass, reaction precursors and products, or reactor substrate. It may further provide for the use of
temperature sensitive elements or substrates. The method of use could include
initiation and control of light-matter interactions addressed at optical and other frequencies to generate controlled localized thermal conditions. A further implementation concerns a means to employ electromagnetic excitation or light-matter interactions to generate localized thermal conditions to initiate or control or cause the combination, separation, reformation or reclamation of a gas, a combination of gasses, a material or a combination of materials in the form of a gas,
plasma,
solid or liquid. The method of use disclosed could provide a means to initiate and control chemical reactions for the generation, use, transfer and output of controlled localized thermal heat or energy. The method of use disclosed could provide a means to realize and control local thermal conditions down to or below the
length scale of a single nanometer and down to or below the timescale of a single
picosecond. In some implementations
surface plasmon excitations may be used to realize and control local thermal conditions down to or below the
length scale of a single nanometer and down to or below the timescale of a single
picosecond.