Correction to: Chirality and Chiroptical Effects in Metal Nanostructures: Fundamentals and Current Trends (Advanced Optical Materials, (2017), 5, 16, (1700182), 10.1002/adom.201700182)

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1 Citation (Scopus)

Abstract

The statement “However, it is yet unclear the extent to which the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as CD, or plasmon resonance shifts. Indeed, a complete QED theory to study chiroptical radiation matter interactions in the near field has not been developed.” on page 29 of the originally published article is not correct, in the sense that a nearfield quantum electrodynamic (QED) theory has indeed been developed in earlier works.[1] The authors regret this mistake in the article and take the chance to add further references for the readers who might want to go deeper in the subject.[2,3] However, to the best of our knowledge, it is yet unclear to which extent the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as circular dichroism (CD), or plasmon resonance shifts in QED frameworks. This correction does not affect the conclusions of the original publication.

LanguageEnglish
Article number1701345
JournalAdvanced Optical Materials
Volume6
Issue number2
DOIs
StatusPublished - 18 Jan 2018

Fingerprint

Optical materials
Chirality
Electrodynamics
optical materials
quantum electrodynamics
chirality
Nanostructures
Metals
Dichroism
trends
dichroism
asymmetry
metals
shift
readers
near fields
Radiation
radiation
interactions

ASJC Scopus subject areas

  • Electronic, Optical and Magnetic Materials
  • Atomic and Molecular Physics, and Optics

Cite this

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title = "Correction to: Chirality and Chiroptical Effects in Metal Nanostructures: Fundamentals and Current Trends (Advanced Optical Materials, (2017), 5, 16, (1700182), 10.1002/adom.201700182)",
abstract = "The statement “However, it is yet unclear the extent to which the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as CD, or plasmon resonance shifts. Indeed, a complete QED theory to study chiroptical radiation matter interactions in the near field has not been developed.” on page 29 of the originally published article is not correct, in the sense that a nearfield quantum electrodynamic (QED) theory has indeed been developed in earlier works.[1] The authors regret this mistake in the article and take the chance to add further references for the readers who might want to go deeper in the subject.[2,3] However, to the best of our knowledge, it is yet unclear to which extent the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as circular dichroism (CD), or plasmon resonance shifts in QED frameworks. This correction does not affect the conclusions of the original publication.",
author = "Collins, {Joel T.} and Christian Kuppe and Hooper, {David C.} and Concita Sibilia and Marco Centini and Valev, {Ventsislav K.}",
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AU - Collins, Joel T.

AU - Kuppe, Christian

AU - Hooper, David C.

AU - Sibilia, Concita

AU - Centini, Marco

AU - Valev, Ventsislav K.

PY - 2018/1/18

Y1 - 2018/1/18

N2 - The statement “However, it is yet unclear the extent to which the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as CD, or plasmon resonance shifts. Indeed, a complete QED theory to study chiroptical radiation matter interactions in the near field has not been developed.” on page 29 of the originally published article is not correct, in the sense that a nearfield quantum electrodynamic (QED) theory has indeed been developed in earlier works.[1] The authors regret this mistake in the article and take the chance to add further references for the readers who might want to go deeper in the subject.[2,3] However, to the best of our knowledge, it is yet unclear to which extent the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as circular dichroism (CD), or plasmon resonance shifts in QED frameworks. This correction does not affect the conclusions of the original publication.

AB - The statement “However, it is yet unclear the extent to which the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as CD, or plasmon resonance shifts. Indeed, a complete QED theory to study chiroptical radiation matter interactions in the near field has not been developed.” on page 29 of the originally published article is not correct, in the sense that a nearfield quantum electrodynamic (QED) theory has indeed been developed in earlier works.[1] The authors regret this mistake in the article and take the chance to add further references for the readers who might want to go deeper in the subject.[2,3] However, to the best of our knowledge, it is yet unclear to which extent the optical chirality of a field influences the dissymmetry of a chiroptical system in a way that enhances measurable quantities such as circular dichroism (CD), or plasmon resonance shifts in QED frameworks. This correction does not affect the conclusions of the original publication.

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