Mapping of strain and electric fields in (formula presented) quantum-well samples by laser-assisted NMR

Marcus Eickhoff; Björn Lenzmann; Dieter Suter; Sophia E. Hayes; Andreas D. Wieck

doi:10.1103/PhysRevB.67.085308

Mapping of strain and electric fields in (formula presented) quantum-well samples by laser-assisted NMR

Marcus Eickhoff
, Björn Lenzmann
, Dieter Suter
, Sophia E. Hayes
, Andreas D. Wieck

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

3 Scopus citations

Abstract

The usefulness of semiconductor heterostructures derives from the possibility to engineer their electronic and optical properties to match the requirements of many different applications. Optically detected nuclear magnetic resonance provides the possibility to map microscopic properties of such samples with a high spatial resolution through the splitting of resonance lines. In a multiple quantum-well sample, we measure the distortion of the crystal lattice and find variations of the order of (formula presented) over distances of a few mm. Internal electric fields also cause resonance line splittings. Comparing the electric field-induced resonance line splittings in different quantum wells, we mapped the vertical variation of the electric field from a Schottky contact with a spatial resolution of some 40 nm.

Original language	English
Journal	Physical Review B - Condensed Matter and Materials Physics
Volume	67
Issue number	8
DOIs	https://doi.org/10.1103/PhysRevB.67.085308
State	Published - Feb 6 2003

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10.1103/PhysRevB.67.085308

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abstract = "The usefulness of semiconductor heterostructures derives from the possibility to engineer their electronic and optical properties to match the requirements of many different applications. Optically detected nuclear magnetic resonance provides the possibility to map microscopic properties of such samples with a high spatial resolution through the splitting of resonance lines. In a multiple quantum-well sample, we measure the distortion of the crystal lattice and find variations of the order of (formula presented) over distances of a few mm. Internal electric fields also cause resonance line splittings. Comparing the electric field-induced resonance line splittings in different quantum wells, we mapped the vertical variation of the electric field from a Schottky contact with a spatial resolution of some 40 nm.",

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AU - Eickhoff, Marcus

AU - Lenzmann, Björn

AU - Suter, Dieter

AU - Hayes, Sophia E.

AU - Wieck, Andreas D.

PY - 2003/2/6

Y1 - 2003/2/6

N2 - The usefulness of semiconductor heterostructures derives from the possibility to engineer their electronic and optical properties to match the requirements of many different applications. Optically detected nuclear magnetic resonance provides the possibility to map microscopic properties of such samples with a high spatial resolution through the splitting of resonance lines. In a multiple quantum-well sample, we measure the distortion of the crystal lattice and find variations of the order of (formula presented) over distances of a few mm. Internal electric fields also cause resonance line splittings. Comparing the electric field-induced resonance line splittings in different quantum wells, we mapped the vertical variation of the electric field from a Schottky contact with a spatial resolution of some 40 nm.

AB - The usefulness of semiconductor heterostructures derives from the possibility to engineer their electronic and optical properties to match the requirements of many different applications. Optically detected nuclear magnetic resonance provides the possibility to map microscopic properties of such samples with a high spatial resolution through the splitting of resonance lines. In a multiple quantum-well sample, we measure the distortion of the crystal lattice and find variations of the order of (formula presented) over distances of a few mm. Internal electric fields also cause resonance line splittings. Comparing the electric field-induced resonance line splittings in different quantum wells, we mapped the vertical variation of the electric field from a Schottky contact with a spatial resolution of some 40 nm.

UR - https://www.scopus.com/pages/publications/85038893967

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SN - 1098-0121

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JO - Physical Review B - Condensed Matter and Materials Physics

JF - Physical Review B - Condensed Matter and Materials Physics

IS - 8

ER -

Mapping of strain and electric fields in (formula presented) quantum-well samples by laser-assisted NMR

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