Abstract: The invention relates to control of THz radiation in parallel plate waveguides (PPWG) by forming components in the waveguide by use of optical radiation pulses. Patterns of excited regions induced in the PPWG by an optical excitation pulses changes the electromagnetic properties of the waveguide medium in the THz regime, thereby forming transient passive and active components for controlling THz radiation signals. The excitation can be generation of free charge carriers in a semiconductor material in the PPWG, to create metallic regions that form mirrors, lenses or photonic crystal structures in the PPWG. The photo-induced pattern can be modulated in time in response to an incoming signal, to frequency-, phase- or amplitude-modulate the THz signal. The systems can be integrated on chip-scale components and can be applied in e.g. THz communication, digital computing, sensors, and lab-on-a-chip applications. The optical and THz radiation can be ultrashort pulses with picosecond or femtosecond pulse durations.

Abstract: The invention relates to control of THz radiation in parallel plate waveguides (PPWG) by forming components in the waveguide by use of optical radiation pulses. Patterns of excited regions induced in the PPWG by an optical excitation pulses changes the electromagnetic properties of the waveguide medium in the THz regime, thereby forming transient passive and active components for controlling THz radiation signals. The excitation can be generation of free charge carriers in a semiconductor material in the PPWG, to create metallic regions that form mirrors, lenses or photonic crystal structures in the PPWG. The photo-induced pattern can be modulated in time in response to an incoming signal, to frequency-, phase- or amplitude-modulate the THz signal. The systems can be integrated on chip-scale components and can be applied in e.g. THz communication, digital computing, sensors, and lab-on-a-chip applications. The optical and THz radiation can be ultrashort pulses with picosecond or femtosecond pulse durations.