Nonlocal Hot-Electron Transport and Capture Model for Multiple Quantum Well Structures Excited by Infrared Radiation

Semicond. Sci. Technol.

Suris

et al. 2001

We investigate the spatio-temporal electric-field distributions in multiple quantum well infrared photodetectors (QWIPs) excited by infrared radiation using ensemble Monte Carlo particle modelling. It is shown that self-organized stable periodic electric-field structures can occur in QWIPs excited by infrared radiation. These electric-field distributions have a period equal to twice the period of the QWIP structure. The periodic distributions are superimposed by relatively weak spatio-temporal oscillations. The transition between two stable periodic structures in response to step-like variation of the applied voltage is demonstrated. The periodicity of the electric-field structures is conserved after the cessation of illumination for a long time. This time is determined by relatively slow thermoexcitation processes. The occurrence of the electric-field distributions can pronouncedly affect the QWIP steady-state and noise characteristics.

Section: Analysis Of the Resultsmentioning

confidence: 99%

Self-organization in multiple quantum well infrared photodetectors

Semicond. Sci. Technol.

Suris

et al. 2001

“…Since the photoexcited and injected electrons acquire kinetic energy propagating across the device under the electric field, they can be hot. If the electron energy relaxation length L ε = v d τ ε , where v d and τ ε are the electron drift velocity and the energy relaxation time, respectively, exceeds the heterostructure period d, the electron effective temperature T ef f is mainly determined by the applied bias voltage V [38]. An increase in V leads to a rise of T ef f and to a drop of the capture efficiency p [26] (see also references therein).…”

Section: Discussionmentioning

confidence: 99%

Effect of doping on the characteristics of infrared photodetectors based on van der Waals heterostructures with multiple graphene layers

Journal of Applied Physics

Leiman

et al. 2017

Keywords: graphene, van der Waals heterostructure, infrared photodetector. We study the operation of infrared photodetectors based on van der Waals heterostructures with the multiple graphene layers (GLs) and n-type emitter and collector contacts. The operation of such GL infrared photodetectors (GLIPs) is associated with the photoassisted escape of electrons from the GLs into the continuum states in the conduction band of the barrier layers due to the interband photon absorption, the propagation of these electrons and the electrons injected from the emitter across the heterostructure and their collection by the collector contact. The space charge of the holes trapped in the GLs provides a relatively strong injection and large photoelectric gain. We calculate the GLIP responsivity and dark current detectivity as functions of the energy of incident infrared photons and the structural parameters. It is shown that both the periodic selective doping of the inter-GL barrier layers and the GL doping lead to a pronounced variation of the GLIP spectral characteristics, particularly near the interband absorption threshold, while the doping of GLs solely results in a substantial increase in the GLIP detectivity. The doping "engineering" opens wide opportunities for the optimization of GLIPs for operation in different parts of radiation spectrum from near infrared to terahertz.

“…It is worth mention that if the capture efficiency p n is a sufficiently strong function of E n−1 , the monotonic electric-field spatial distributions can become unstable against the perturbation with the length 2d [36][37][38]. Such an instability can lead to quasi-chaotic spatio-temporal electric field variations, which eventually result in the formation of stable quasi-periodic electric-field distributions [48].…”

Section: A2 Field-dependence Of the Capture Efficiencymentioning

confidence: 99%

“…In the framework of this concept, the electric-field distributions are assumed to be uniform. A more accurate consideration of the transport phenomena in such structures (including GLIPs) in the dark conditions and under irradiation accounts for the self-consistent electric field distributions and the nonideality of the emitter [32][33][34][35][36][37][38]. This paper uses this more accurate approach.…”

Section: Introductionmentioning

confidence: 99%

Infrared photodetectors based on graphene van der Waals heterostructures

Infrared Physics & Technology

Svintsov

et al. 2017

We propose and evaluate the graphene layer (GL) infrared photodetectors (GLIPs) based on the van der Waals (vdW) heterostructures with the radiation absorbing GLs. The operation of the GLIPs is associated with the electron photoexcitation from the GL valence band to the continuum states above the inter-GL barriers (either via tunneling or direct transitions to the continuum states). Using the developed device model, we calculate the photodetector characteristics as functions of the GL-vdW heterostructure parameters. We show that due to a relatively large efficiency of the electron photoexcitation and low capture efficiency of the electrons propagating over the barriers in the inter-GL layers, GLIPs should exhibit the elevated photoelectric gain and detector responsivity as well as relatively high detectivity. The possibility of high-speed operation, high conductivity, transparency of the GLIP contact layers, and the sensitivity to normally incident IR radiation provides additional potential advantages in comparison with other IR photodetectors. In particular, the proposed GLIPs can compete with unitravelling-carrier photodetectors.Comment: 14 pages, 7 figure