Coherent control approaches to light guidance in the nanoscale

Maxim Sukharev; Tamar Seideman

doi:10.1063/1.2177651

Coherent control approaches to light guidance in the nanoscale

Maxim Sukharev, Tamar Seideman

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

25 Scopus citations

Abstract

Concepts of coherent control are extended to manipulate light in subdiffraction length scales via nanoparticle arrays. Phase and polarization control are first introduced and applied to control the pathway of electromagnetic energy through multiple branching nanoarray intersections, leading to an ultrafast optical nanoswitch below the diffraction limit. The genetic algorithm is next generalized to provide a systematic design tool, wherein both the properties of the excitation field and the structural parameters of the material system are optimized so as to make nanodevices with desired functionality. The scheme is used to gain insight into the interplay between the interactions that underlies the coherent propagation of electromagnetic energy via nanoparticle arrays. Implications to several research fields, including single molecule spectroscopy, spatially confined chemistry, optical logic, and nanoscale sensing, are envisioned.

Original language	English (US)
Article number	144707
Journal	Journal of Chemical Physics
Volume	124
Issue number	14
DOIs	https://doi.org/10.1063/1.2177651
State	Published - Apr 14 2006
Externally published	Yes

ASJC Scopus subject areas

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1063/1.2177651

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title = "Coherent control approaches to light guidance in the nanoscale",

abstract = "Concepts of coherent control are extended to manipulate light in subdiffraction length scales via nanoparticle arrays. Phase and polarization control are first introduced and applied to control the pathway of electromagnetic energy through multiple branching nanoarray intersections, leading to an ultrafast optical nanoswitch below the diffraction limit. The genetic algorithm is next generalized to provide a systematic design tool, wherein both the properties of the excitation field and the structural parameters of the material system are optimized so as to make nanodevices with desired functionality. The scheme is used to gain insight into the interplay between the interactions that underlies the coherent propagation of electromagnetic energy via nanoparticle arrays. Implications to several research fields, including single molecule spectroscopy, spatially confined chemistry, optical logic, and nanoscale sensing, are envisioned.",

author = "Maxim Sukharev and Tamar Seideman",

note = "Funding Information: We thank Dr. G. Cheng, Dr. S. Gray, Dr. A. Pinchuk, Professor G. Schatz, and Professor R. Van Duyne for interesting conversations, and the National Energy Research Scientific Computing Center, supported by the Office of Science of the U.S. Department of Energy under Contract No. DE-AC03-76SF00098, and the San Diego Supercomputer Center under Grant No. PHY050006N for computational resources.",

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N1 - Funding Information: We thank Dr. G. Cheng, Dr. S. Gray, Dr. A. Pinchuk, Professor G. Schatz, and Professor R. Van Duyne for interesting conversations, and the National Energy Research Scientific Computing Center, supported by the Office of Science of the U.S. Department of Energy under Contract No. DE-AC03-76SF00098, and the San Diego Supercomputer Center under Grant No. PHY050006N for computational resources.

PY - 2006/4/14

Y1 - 2006/4/14

N2 - Concepts of coherent control are extended to manipulate light in subdiffraction length scales via nanoparticle arrays. Phase and polarization control are first introduced and applied to control the pathway of electromagnetic energy through multiple branching nanoarray intersections, leading to an ultrafast optical nanoswitch below the diffraction limit. The genetic algorithm is next generalized to provide a systematic design tool, wherein both the properties of the excitation field and the structural parameters of the material system are optimized so as to make nanodevices with desired functionality. The scheme is used to gain insight into the interplay between the interactions that underlies the coherent propagation of electromagnetic energy via nanoparticle arrays. Implications to several research fields, including single molecule spectroscopy, spatially confined chemistry, optical logic, and nanoscale sensing, are envisioned.

AB - Concepts of coherent control are extended to manipulate light in subdiffraction length scales via nanoparticle arrays. Phase and polarization control are first introduced and applied to control the pathway of electromagnetic energy through multiple branching nanoarray intersections, leading to an ultrafast optical nanoswitch below the diffraction limit. The genetic algorithm is next generalized to provide a systematic design tool, wherein both the properties of the excitation field and the structural parameters of the material system are optimized so as to make nanodevices with desired functionality. The scheme is used to gain insight into the interplay between the interactions that underlies the coherent propagation of electromagnetic energy via nanoparticle arrays. Implications to several research fields, including single molecule spectroscopy, spatially confined chemistry, optical logic, and nanoscale sensing, are envisioned.

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Coherent control approaches to light guidance in the nanoscale

Abstract

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