probing electric and magnetic vacuum fluctuations with quantum dots

Petru Tighineanu; Anders Søndberg Sørensen; Søren Stobbe; Peter Lodahl

probing electric and magnetic vacuum fluctuations with quantum dots

Petru Tighineanu, Anders Søndberg Sørensen, Søren Stobbe, Peter Lodahl

15 Citations (Scopus)

Abstract

The electromagnetic-vacuum-field fluctuations are intimately linked to the process of spontaneous emission of light. Atomic emitters cannot probe electric- and magnetic-field fluctuations simultaneously because electric and magnetic transitions correspond to different selection rules. In this Letter we show that semiconductor quantum dots are fundamentally different and are capable of mediating electric-dipole, magnetic-dipole, and electric-quadrupole transitions on a single electronic resonance. As a consequence, quantum dots can probe electric and magnetic fields simultaneously and can thus be applied for sensing the electromagnetic environment of complex photonic nanostructures. Our study opens the prospect of interfacing quantum dots with optical metamaterials for tailoring the electric and magnetic light-matter interaction at the single-emitter level.

Original language	English
Title of host publication	Nonlinear quantum optics : Workshop, Leiden, the Netherlands, 2014
Place of Publication	Leiden, Netherlands
Publication date	25 Jul 2014
Publication status	Published - 25 Jul 2014

Cite this

@inproceedings{6a9e555808334052b236c453f773ea31,

title = "probing electric and magnetic vacuum fluctuations with quantum dots",

abstract = "The electromagnetic-vacuum-field fluctuations are intimately linked to the process of spontaneous emission of light. Atomic emitters cannot probe electric- and magnetic-field fluctuations simultaneously because electric and magnetic transitions correspond to different selection rules. In this Letter we show that semiconductor quantum dots are fundamentally different and are capable of mediating electric-dipole, magnetic-dipole, and electric-quadrupole transitions on a single electronic resonance. As a consequence, quantum dots can probe electric and magnetic fields simultaneously and can thus be applied for sensing the electromagnetic environment of complex photonic nanostructures. Our study opens the prospect of interfacing quantum dots with optical metamaterials for tailoring the electric and magnetic light-matter interaction at the single-emitter level.",

author = "Petru Tighineanu and S{\o}rensen, {Anders S{\o}ndberg} and S{\o}ren Stobbe and Peter Lodahl",

year = "2014",

month = jul,

day = "25",

language = "English",

booktitle = "Nonlinear quantum optics",

}

TY - GEN

T1 - probing electric and magnetic vacuum fluctuations with quantum dots

AU - Tighineanu, Petru

AU - Sørensen, Anders Søndberg

AU - Stobbe, Søren

AU - Lodahl, Peter

PY - 2014/7/25

Y1 - 2014/7/25

N2 - The electromagnetic-vacuum-field fluctuations are intimately linked to the process of spontaneous emission of light. Atomic emitters cannot probe electric- and magnetic-field fluctuations simultaneously because electric and magnetic transitions correspond to different selection rules. In this Letter we show that semiconductor quantum dots are fundamentally different and are capable of mediating electric-dipole, magnetic-dipole, and electric-quadrupole transitions on a single electronic resonance. As a consequence, quantum dots can probe electric and magnetic fields simultaneously and can thus be applied for sensing the electromagnetic environment of complex photonic nanostructures. Our study opens the prospect of interfacing quantum dots with optical metamaterials for tailoring the electric and magnetic light-matter interaction at the single-emitter level.

AB - The electromagnetic-vacuum-field fluctuations are intimately linked to the process of spontaneous emission of light. Atomic emitters cannot probe electric- and magnetic-field fluctuations simultaneously because electric and magnetic transitions correspond to different selection rules. In this Letter we show that semiconductor quantum dots are fundamentally different and are capable of mediating electric-dipole, magnetic-dipole, and electric-quadrupole transitions on a single electronic resonance. As a consequence, quantum dots can probe electric and magnetic fields simultaneously and can thus be applied for sensing the electromagnetic environment of complex photonic nanostructures. Our study opens the prospect of interfacing quantum dots with optical metamaterials for tailoring the electric and magnetic light-matter interaction at the single-emitter level.

M3 - Article in proceedings

BT - Nonlinear quantum optics

CY - Leiden, Netherlands

ER -

probing electric and magnetic vacuum fluctuations with quantum dots

Abstract

Fingerprint

Cite this