Terahertz photonics

Generation of high-power terahertz pulses in a prism

Optics Letters 27:21 (2002) 1935-1937

Authors:

MB Johnston, DM Whittaker, A Dowd, AG Davies, EH Linfield, X Li, DA Ritchie

Abstract:

A compact, high-power emitter of half-cycle terahertz (THz) radiation is demonstrated. The device consists of an epitaxial InAs emitter upon a GaAs prism and produces THz pulses that are 20 times more powerful than those from conventional planar InAs emitters. This improvement is a direct result of reorienting the transient THz dipole such that its axis is not perpendicular to the emitting surface. © 2002 Optical Society of America.

Simulation of terahertz generation at semiconductor surfaces

Physical Review B: Condensed Matter and Materials Physics 65 (2002) 165301 6pp

Authors:

MB Johnston, D. M. Whittaker, A. Corchia, A. G. Davies

Theory of magnetic-field enhancement of surface-field terahertz emission

Journal of Applied Physics 91:4 (2002) 2104-2106

Authors:

MB Johnston, DM Whittaker, A Corchia, A G. Davies, EH Linfield

Abstract:

We present a theoretical treatment of surface-field THz generation in semiconductors, which explains the power enhancement observed when a magnetic field is applied. Our model consists of two parts: a Monte Carlo simulation of the dynamics of carriers generated by a subpicosecond optical pulse, and a calculation of the resulting THz radiation emitted through the semiconductor surface. The magnetic field deflects the motion of the carriers, producing a component of the THz dipole parallel to the surface. This causes the power transmitted through the surface to be increased by more than one order of magnitude. © 2002 American Institute of Physics.

Theory of magnetic-field enhancement of surface-field terahertz emission

Journal of Applied Physics 91:3 (2002) 2104-2106

Authors:

MB Johnston, DM Whittaker, A Corchia, A G. Davies, EH Linfield

Abstract:

We present a theoretical treatment of surface-field THz generation in semiconductors, which explains the power enhancement observed when a magnetic field is applied. Our model consists of two parts: a Monte Carlo simulation of the dynamics of carriers generated by a subpicosecond optical pulse, and a calculation of the resulting THz radiation emitted through the semiconductor surface. The magnetic field deflects the motion of the carriers, producing a component of the THz dipole parallel to the surface. This causes the power transmitted through the surface to be increased by more than one order of magnitude. © 2002 American Institute of Physics.

Magnetic-field-induced enhancement of terahertz emission from III-V semiconductor surfaces

Physica E: Low-Dimensional Systems and Nanostructures 13:2-4 (2002) 896-899

Authors:

MB Johnston, A Corchia, A Dowd, EH Linfield, AG Davies, R McLaughlin, DD Arnone, M Pepper

Abstract:

We discuss the origins of the magnetic-field-induced enhancement of terahertz (THz) emission from bulk semiconductor surfaces. The principal effect of the magnetic field is to rotate the THz dipole and hence dramatically increase the THz power radiated through the semiconductor surface. It also significantly affects the ability of the photo-created carriers to screen surface electric fields. The sensitivity of THz emission to the motion of photo-created carriers makes this an ideal probe of hot carrier dynamics both in bulk semiconductors and sophisticated heterostructures. © 2002 Elsevier Science Ltd. All rights reserved.