Mechanical Flip-Chip for Ultra-High Electron Mobility Devices

Keyan Bennaceur; Benjamin A. Schmidt; Samuel Gaucher; Dominique Laroche; Michael P. Lilly; John L. Reno; Ken W. West; Loren N. Pfeiffer; Guillaume Gervais

doi:10.1038/srep13494

Mechanical Flip-Chip for Ultra-High Electron Mobility Devices

Keyan Bennaceur, Benjamin A. Schmidt, Samuel Gaucher, Dominique Laroche, Michael P. Lilly, John L. Reno, Ken W. West, Loren N. Pfeiffer, Guillaume Gervais

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Electrostatic gates are of paramount importance for the physics of devices based on high-mobility two-dimensional electron gas (2DEG) since they allow depletion of electrons in selected areas. This field-effect gating enables the fabrication of a wide range of devices such as, for example, quantum point contacts (QPC), electron interferometers and quantum dots. To fabricate these gates, processing is usually performed on the 2DEG material, which is in many cases detrimental to its electron mobility. Here we propose an alternative process which does not require any processing of the 2DEG material other than for the ohmic contacts. This approach relies on processing a separate wafer that is then mechanically mounted on the 2DEG material in a flip-chip fashion. This technique proved successful to fabricate quantum point contacts on both GaAs/AlGaAs materials with both moderate and ultra-high electron mobility.

Original language	English (US)
Article number	13494
Journal	Scientific reports
Volume	5
DOIs	https://doi.org/10.1038/srep13494
State	Published - Sep 22 2015
Externally published	Yes

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title = "Mechanical Flip-Chip for Ultra-High Electron Mobility Devices",

abstract = "Electrostatic gates are of paramount importance for the physics of devices based on high-mobility two-dimensional electron gas (2DEG) since they allow depletion of electrons in selected areas. This field-effect gating enables the fabrication of a wide range of devices such as, for example, quantum point contacts (QPC), electron interferometers and quantum dots. To fabricate these gates, processing is usually performed on the 2DEG material, which is in many cases detrimental to its electron mobility. Here we propose an alternative process which does not require any processing of the 2DEG material other than for the ohmic contacts. This approach relies on processing a separate wafer that is then mechanically mounted on the 2DEG material in a flip-chip fashion. This technique proved successful to fabricate quantum point contacts on both GaAs/AlGaAs materials with both moderate and ultra-high electron mobility.",

author = "Keyan Bennaceur and Schmidt, {Benjamin A.} and Samuel Gaucher and Dominique Laroche and Lilly, {Michael P.} and Reno, {John L.} and West, {Ken W.} and Pfeiffer, {Loren N.} and Guillaume Gervais",

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doi = "10.1038/srep13494",

language = "English (US)",

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AU - Bennaceur, Keyan

AU - Schmidt, Benjamin A.

AU - Gaucher, Samuel

AU - Laroche, Dominique

AU - Lilly, Michael P.

AU - Reno, John L.

AU - West, Ken W.

AU - Pfeiffer, Loren N.

AU - Gervais, Guillaume

PY - 2015/9/22

Y1 - 2015/9/22

N2 - Electrostatic gates are of paramount importance for the physics of devices based on high-mobility two-dimensional electron gas (2DEG) since they allow depletion of electrons in selected areas. This field-effect gating enables the fabrication of a wide range of devices such as, for example, quantum point contacts (QPC), electron interferometers and quantum dots. To fabricate these gates, processing is usually performed on the 2DEG material, which is in many cases detrimental to its electron mobility. Here we propose an alternative process which does not require any processing of the 2DEG material other than for the ohmic contacts. This approach relies on processing a separate wafer that is then mechanically mounted on the 2DEG material in a flip-chip fashion. This technique proved successful to fabricate quantum point contacts on both GaAs/AlGaAs materials with both moderate and ultra-high electron mobility.

AB - Electrostatic gates are of paramount importance for the physics of devices based on high-mobility two-dimensional electron gas (2DEG) since they allow depletion of electrons in selected areas. This field-effect gating enables the fabrication of a wide range of devices such as, for example, quantum point contacts (QPC), electron interferometers and quantum dots. To fabricate these gates, processing is usually performed on the 2DEG material, which is in many cases detrimental to its electron mobility. Here we propose an alternative process which does not require any processing of the 2DEG material other than for the ohmic contacts. This approach relies on processing a separate wafer that is then mechanically mounted on the 2DEG material in a flip-chip fashion. This technique proved successful to fabricate quantum point contacts on both GaAs/AlGaAs materials with both moderate and ultra-high electron mobility.

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Mechanical Flip-Chip for Ultra-High Electron Mobility Devices

Abstract

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