A modulation-doped heterostructure-based terahertz photoconductive antenna emitter with recessed metal contacts

We report on the continuing efforts of the National Institute of Physics, University of the Philippines, in the design, growth, and fabrication of novel structures for THz photoconductive antennas (PCA’s) [1-3]. In particular, the talk presents recent works on the molecular beam epitaxial growth of gallium arsenide-based semiconductor trilayer films and modulation-doped heterostructures (MDH) as substrates for THz PCA emitter’s [1,2]. The improvement of these novel substrates on the performance of the emitters are primarily attributed to the surface/interface electric field modification for the trilayer design; as well as an increase in the carrier mobility for the MDH design. Additionally, work is also being undertaken on the surface modification of the PCA’s [3]. Initial results on the adsorption of Si nanowires on the PCA gap to improve THz generation will also be presented; as well recent work on the incorporation of micron-size metal line arrays on the emission side of the PCA. Being relatively large, these metal line arrays do not require electron beam lithography that are commonly employed in metamaterial enhanced PCA’s. These research activities are carried out in collaboration with the FIR Center, University of Fukui, Japan.

show abstract

A modulation-doped heterostructure-based terahertz photoconductive antenna emitter with recessed metal contacts

Cited by 3 publications

References 41 publications

Design and performance enhancement of terahertz photoconductive antenna based on nano-crossline contacts

Design and performance enhancement of terahertz photoconductive antenna based on nano-crossline contacts

Full-wave multiphysics model for simulation and investigation of terahertz photoconductive antenna using LUMERICAL and CST softwares

Novel GaAs-Based, MBE-Grown Materials for THz Photoconductive Antenna Emitter Research at the University of the Philippines

Contact Info

Product

Resources

About