Epitaxially overgrown, stable W–GaAs Schottky contacts with sizes down to 50 nm

Wernersson, Lars‐Erik; Georgsson, Kristina; Gustafsson, Anders; Löfgren, Anneli; Montelius, Lars; Nilsson, Nina Shariati; Pettersson, H.; Seifert, Werner; Samuelson, Lars; Malm, Jan‐Olle

doi:10.1116/1.1454128

Cited by 9 publications

(11 citation statements)

References 30 publications

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“…The patterning of the wafers was done by electron beam lithography and electron beam evaporation of 20-nm-thick W in a conventional lift-off process [4]. Prior to the overgrowth, oxygen plasma stripping and a short (60 s) etch in HCl:H 2 O (1:1), followed by rinsing in deionized water, were performed to remove traces of the photoresist and the native oxide.…”

Section: Experimental Techniquesmentioning

confidence: 99%

InAs epitaxial lateral overgrowth of W masks

Wernersson

Lind

Lembke

et al. 2005

Journal of Crystal Growth

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Section: Experimental Techniquesmentioning

confidence: 99%

InAs epitaxial lateral overgrowth of W masks

Wernersson

Lind

Lembke

et al. 2005

Journal of Crystal Growth

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“…Because the embedded gate consists of thin buried metal wires, the resistance may be high and limit the device performance. From electrical measurements of embedded individual wires, we deduced an experimental value of the metal resistivity to be about 100 cm [13]. In our device model (Figure 3), we used a structure consisting of 25 parallel connected wires 5 m long.…”

Section: The Resonant Tunnelling Permeable Base Transistormentioning

confidence: 99%

“…The growth is interrupted and the sample is patterned with 20-nm-thick W wires placed in a grating with 140 nm wide wires in a period of 350 nm. This covers a total area of 70 m × 100 m. To build the gate, a conventional lift-o process based on electron beam lithography and electron beam evaporation of the W [13] is used. The grating is oriented 60…”

Section: The Resonant Tunnelling Permeable Base Transistormentioning

confidence: 99%

Highly functional tunnelling devices integrated in 3D

Wernersson

Lind

Lindstrom

et al. 2003

Circuit Theory & Apps

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SUMMARYWe present a new technology for integrating tunnelling devices in three dimensions. These devices are fabricated by the combination of the growth of semiconductor heterostructures with the controlled introduction of metallic elements into an epitaxial layer by an overgrowth technique. First, we use a new type of tunnelling transistor, namely a resonant-tunnelling permeable base transistor. A simple model based on a piece-wise linear approximation is used in Cadence to describe the current-voltage characteristics of the transistor. This model is further introduced into a small signal equivalent circuit in order to optimize the performance of the device. In addition to the tunnelling structure below the grating, these transistors may be integrated in 3D by the introduction of another tunnelling structure directly over the metal grating. In the integrated device structure, the gate acts simultaneously on both tunnelling structures and the obtained characteristics are the result of the interplay between the two tunnelling structures and the gate. An equivalent circuit model is developed and we show how this interaction in uences the current-voltage characteristics. The gate may be used to adjust the peak voltage of certain peaks in a controlled fashion, which creates a highly functional tunnelling device. These results show the need for a strong interaction between the development of circuit models and processing technology to develop new nano-electronic devices and circuits.

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“…3 The patterns formed consist of lines ͑width of 90-100 nm and periods of 200-700 nm͒ and concentric rings ͑width of 100 nm and periods of 400 nm͒. Metal organic vapor phase epitaxy ͑MOVPE͒ was used to epitaxially overgrow the patterned substrates with InAs at a growth temperature of 500°C and a V/III ratio of 14.…”

Section: Methodsmentioning

confidence: 99%

“…The mesa geometry was used to deduce the conductivity of the devices from the measured data. Based on reported values for the resistivity for overgrown tungsten lines ͑120 ⍀ cm͒, 3 it was calculated that the contribution from the metal accounted only for about 15% ͑it varied with pattern density from 11% to 18%͒ of the total measured conductance in our devices. It may hence not be responsible for the observed reduction in the resistance as the metal density increased.…”

Section: Electrical Characterizationmentioning

confidence: 99%

Electrical characterization of thin InAs films grown on patterned W∕GaAs substrates

Astromskas

Wallenberg

Wernersson

2009

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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InAs has been grown on W-GaAs patterned substrates using metal organic vapor phase epitaxy. It is shown that the W pattern guides the nucleation of the InAs on the GaAs substrate and that the islands formed may be used to embed metal features in a hybrid InAs/ GaAs structure. A lower resistance ͑factor of 2͒ was measured for the hybrid structures as compared to reference structures. The reduction in the resistance is attributed to an increased carrier concentration as observed from Hall measurements on devices with different tungsten densities. Cross-sectional transmission electron microscopy investigations reveal a void-free overgrowth above the metal despite the large mismatch of the InAs/ GaAs system.

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Epitaxially overgrown, stable W–GaAs Schottky contacts with sizes down to 50 nm

Cited by 9 publications

References 30 publications

InAs epitaxial lateral overgrowth of W masks

InAs epitaxial lateral overgrowth of W masks

Highly functional tunnelling devices integrated in 3D

Electrical characterization of thin InAs films grown on patterned W∕GaAs substrates

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