Negative differential mobility in GaAs at ultrahigh fields: Comparison between an experiment and simulations

“…For decades the lock-on effect was a puzzle. The key finding that has helped to explain such anomalous dynamics is the discovery of collapsing high-field domains that spontaneously appear in electronhole plasma due to negative differential electron mobility in GaAs [19]- [21]. These domains were originally predicted as a mechanism that explains picosecond-range switching and terahertz emission in GaAs avalanche transistors [19], [20].…”

Section: Resultsmentioning

confidence: 97%

“…These domains were originally predicted as a mechanism that explains picosecond-range switching and terahertz emission in GaAs avalanche transistors [19], [20]. The mechanism that initiates the instability of the spatially uniform current flow is essentially the same as that for the well-known Gunn effect and is related to negative differential conductivity [19]- [21]. However, the shape and spatiotemporal dynamics of collapsing domains turn out to be very different from the conventional monopolar Gunn effect [22] as well as from the early analytical description of bipolar Gunn domains [23].…”

Section: Resultsmentioning

confidence: 97%

Picosecond-Range Avalanche Switching of High-Voltage Diodes: Si Versus GaAs Structures

Brylevskiy

Smirnova

Rozhkov

et al. 2016

IEEE Trans. Plasma Sci.

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We present a comparative study of Si and GaAs high-voltage diodes operated in the delayed impact ionization breakdown mode. We use an experimental setup that allows measuring current and voltage on the diode simultaneously and independently during a 100-ps high-voltage switching transient. Si and GaAs structures with identical geometries and a stationary breakdown voltage of ∼1 kV were investigated. All devices trigger at close to 2 kV and are capable of forming a voltage ramp with a kilovolt amplitude and a 100-ps rise time. We found that Si p + nn + and p + pnn + structures differ in residual voltage: a relatively low residual voltage V res of 100-200 V was observed only for p + nn + structures, whereas for p + pnn + structures V res is about 1 kV. We report observing the lock-on effect in GaAs structures: after 100-ps avalanche switching GaAs diodes remain in a high conducting state as long as the applied voltage pulse lasts, whereas within the same time of 2 ns reference Si diodes fully recover the blocking capability.

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“…Namely, NDM must take place well above the ionization threshold . We have proved this condition so far [ 31 ] only for GaAs, in which NDM takes place up to at least 600 kV/cm, while for other III-V materials the question is still open.…”

Section: Introductionmentioning

confidence: 85%

“…In contrary, in our case multiple fi eld domains are generated, which number varies from a few to ~20 during the transient; the ionization threshold is exceeded several times and causes extremely powerful impact ionization; both electrons and holes are presented forming plasma between the domains; drastic domain shrinkage causes very fast voltage reduction across the structure and even complete domain disappearance [ 27 ]. As for the fundamental physical reason, the collapsing domain effect requires not simply presence of NDM [ 30 ] (as Gunn effect), but much more hard condition must be satisfi ed [ 31 ]. Namely, NDM must take place well above the ionization threshold .…”

Section: Introductionmentioning

confidence: 97%

Transmission Subterahertz Imaging Utilizing Milliwatt-Range Nanosecond Pulses from Miniature, Collapsing-Domain-Based Avalanche Source

Vainshtein

Kostamovaara

2014

NATO Science for Peace and Security Series B: Physics and Biophysics

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Pulsed radars widely used in microwave and optical frequencies are not available in very interesting for applications millimeter-wave (3-0.3 mm/0.1-1 THz) spectral range due to lacking of a miniature, simple, high-power all -solid-state pulsed emitter. We suggest utilization of a phenomenon which we recently found in powerfully avalanching GaAs-based bipolar transistor structure and termed " collapsing fi eld domains". Here we explain the operating principle of the emitter and show an example of transmission sub-terahertz imaging. The pulsed imaging system uses a prototype of our new source operating in sub-nanosecond time domain in milliwatt range, and a commercial Schottky detector. The imaging traditionally utilizing pulse attenuation in the objects is compared with suggested here timedomain imaging that uses the propagation delay of the transmitted pulse. Advantages of each of those two operating modes are discussed. Presented here pulsed imaging radar is a prospective candidate for Detection of Explosives and CBRN in places of people crowding when utilization of x-ray is problematic. It can also be used in non-destructive tests when x-ray does not show suffi cient contrast, or a portable, not dangerous for humans and cost-effective system is required. Very interesting is a prospective of skin and breast cancer detection. Realization of the refl ection imaging regime using the same source is pending.

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Negative differential mobility in GaAs at ultrahigh fields: Comparison between an experiment and simulations

Cited by 32 publications

References 18 publications

Investigation on properties of ultrafast switching in a bulk gallium arsenide avalanche semiconductor switch

Investigation on properties of ultrafast switching in a bulk gallium arsenide avalanche semiconductor switch

Picosecond-Range Avalanche Switching of High-Voltage Diodes: Si Versus GaAs Structures

Transmission Subterahertz Imaging Utilizing Milliwatt-Range Nanosecond Pulses from Miniature, Collapsing-Domain-Based Avalanche Source

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