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NCN Nanophotonics: Simulation Tools for Education and Research

PhotonicsDB: Optical Constants

This resource has a 9.3 Ranking

Ranking is calculated from a formula comprised of user reviews and usage statistics. Learn more ›

Usage Stats
Overall Period: Updated 21 Nov, 2008
Users: 111
Jobs: 1346
Avg. exec. time: 2 secs
Reviews & Citations
Google/IEEE
Avg. Review: 5.0 out of 5 stars
Citations: 0

111 users, detailed statistics

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Available Versions

  • 1.0 (published)

Supporting Documents

Version 1.0 - published on 28 Feb, 2008
Contributor(s) Xingjie Ni
Purdue University, West Lafayette

Liu, Zhengtong

Alexander V. Kildishev
Purdue University, West Lafayette
At a glance Experimental data is used to interpolate the dielectric function or the index of refraction of bulk materials used in optics and photonics
Description

PhotonicsDB: Optical Constants uses the initial experimental data to interpolate the dielectric function or the index of refraction of bulk materials. Interpolations are possible only within a certain range of wavelengths taken from the initial experimental data sets.

The tool also gives the approximate data and the approximation coefficients obtained from best-fit Drude-Lorentz models for gold and silver. Depending on the number of Lorentz kernels (from 1 to 5) the Drude-Lorentz models support different accuracy of the best-fit approximation.

The imaginary part (and sometimes, the real part) of their dielectric functions can be very different depending on the source of published data. Therefore, in addition to the cubic spline interpolation of the raw experimental data, gold and silver can be interpolated using the corresponding Drude-Lorentz best-fit models. The constants of each model and the initial data set are shown in the reference window of the user interface (UI).

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PhotonicsDB: Optical Constants is built on an earlier project (Data Interpolation Tool, DITTO) developed in collaboration by Alex Kildishev & Alex Moskalenko (2004).
An initial prototype version written using the Scientific Python with a limited set of materials can be found at DITTO Home.

Credits

PhotonicsDB: Optical Constants is built on the experimental data taken from published databases. Custom approximation tools are used for the Drude-Lorentz models of the noble metals.

Development

  • X. Ni, Z. Liu and A. Kildishev ... Developed the core interpolation engine and UI
  • Z. Liu, X. Ni and A. Kildishev ... Provided the Drude-Lorentz approximation data and the overall testing
  • A. Kildishev ... Led the development effort

Support

  • X. Wang and G. Klimeck ... Provided Rappture and nanoHUB.org support
  • A. Moskalenko ... Performed the initial prototyping

References

Handbook of Optical Constants of Solids, Edward D. Palik (Ed.), Academic Press (1997).
Optical Constants of the Noble Metals, P. B. Johnson and R. W. Christy, Physical Review B Vol.6 n.12 (1972).

Cite this work

If you reference this work in a publication, please cite as follows:

  • Ni, Xingjie; Zhengtong, Liu,; Kildishev, Alexander V. (2008), "PhotonicsDB: Optical Constants," doi: 10254/nanohub-r3692.1.

    BibTex | EndNote

In addition, we would appreciate it if you would add the following acknowledgment to your publication:

  • Simulation services for results presented here were provided by the Network for Computational Nanotechnology (NCN) at nanoHUB.org
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  1. 5.0 out of 5 stars 

    Posted on 30 May, 2008 by Ahmad Reza Hajiaboli

  2. 5.0 out of 5 stars 

    Posted on 18 March, 2008 by Anonymous

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