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Photoluminescent Nanofibers for Solid-State Lighting Applications

Published online by Cambridge University Press:  31 January 2011

Lynn Davis ,
Li Han ,
Paul Hoertz ,
Kim Guzan ,
Karmann C. Mills ,
Howard J. Walls ,
Teri A. Walker  and
Damaris Magnus-Aryitey
Lynn Davis
Affiliation:
ldavis@rti.org, RTI International, RTP, North Carolina, United States
Li Han
Affiliation:
lhan@rti.org
Paul Hoertz
Affiliation:
phoertz@rti.org, RTI International, RTP, North Carolina, United States
Kim Guzan
Affiliation:
kguzan@rti.org, RTI International, Research Triangle Park, North Carolina, United States
Karmann C. Mills
Affiliation:
kmills@rti.org, RTI International, RTP, North Carolina, United States
Howard J. Walls
Affiliation:
hjwalls@rti.org, RTI International, RTP, North Carolina, United States
Teri A. Walker
Affiliation:
twalker@rti.org, RTI International, RTP, North Carolina, United States
Damaris Magnus-Aryitey
Affiliation:
dmagnus@rti.org, RTI International, RTP, North Carolina, United States
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Abstract

Photoluminescent nanofibers (PLN) can be formed by combining electrospun polymeric nanofibers and luminescent particles such as quantum dots (QD). The physical properties of PLNs are dependent upon many different nanoscale parameters associated with the nanofiber, the luminescent particles, and their interactions. By understanding and manipulating these properties, the performance of the resulting optical structure can be tailored for desired end-use applications. For example, the quantum efficiency of quantum dots in the PLN structure depends upon multiple parameters including quantum dot chemistry, the method of forming the PLN nanocomposites, and preventing agglomeration of the quantum dot particles. This is especially important in solution-based electrospinning environments where some common solvents may have a detrimental effect on the performance of the PLN. With the proper control of these parameters, high quantum efficiencies can be readily obtained for PLNs. Achieving high quantum efficiencies is critical in applications such as solid-state lighting where PLNs can be an effective secondary conversion material for producing white light. Methods of optimizing the performance of PLNs through nanoscale manipulation of the nanofiber are discussed along with guidelines for tailoring the performance of nanofibers and quantum dots for application-specific requirements.

Keywords

fiberoptical propertiesnanostructure
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 1240: Symposium WW – Polymer Nanofibers–Fundamental Studies and Emerging Applications , 2009 , 1240-WW09-07
Copyright
Copyright © Materials Research Society 2010

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References

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