APS March Meeting 2010
Volume 55, Number 2
Monday–Friday, March 15–19, 2010;
Portland, Oregon
Session T9: Focus Session: Optics of Nanostructures - Near Field, Single Molecule, and Plasmonics
2:30 PM–5:42 PM,
Wednesday, March 17, 2010
Room: A105
Sponsoring
Unit:
DMP
Chair: Rudolf Bratschitsch, University of Konstanz
Abstract ID: BAPS.2010.MAR.T9.4
Abstract: T9.00004 : Novel concepts in infrared imaging at nanoscale resolution
3:06 PM–3:42 PM
Preview Abstract
Abstract
Author:
Thomas Taubner
(RWTH Aachen)
Within the recent years, various novel optical concepts have been
invented
to improve the diffraction-limited resolution of optical
microscopy. The
first approach of scanning near-field optical microscopy (SNOM)
employed a
small, subwavelength-sized aperture that is scanned close to the
object of
interest, capable of a resolution of about 50 nm. More advanced
concepts
rely on the light scattering of a sharp tip probing the sample,
allowing for
higher resolution (10-30 nm) and the use of longer wavelengths.
Another
exciting new imaging device, a planar slab of a material with
negative
permittivity called a superlens, allows for subwavelength
resolved imaging
over large areas. I will focus on the latter two systems that
operate with
\textit{infrared light} and offer the capability of chemical
sensing by directly probing molecular
vibrations.
Particularly, I will present the latest results on superlensing
that became
accessible by \textit{phase-sensitive} infrared near-field
microscopy and thus provide new insight
into the imaging process of a such a device [1]. I will also
explain the basics
of scattering-type near-field optical microscopy (s-SNOM) and
present
various examples of unambiguous nanoscale material
characterization from
various areas such as semiconductor analysis, materials science,
chemistry,
and biology [2-4]. In these examples, the use of infrared
spectroscopy allows
to sense molecular vibrations as well as collective excitation of
lattice
vibrations (``phonons'') in polar crystals [5]. Currently, the
main limitation
of this technique comprises of the low signals that demand
tunable laser
sources and restrict the spectral range of operation.
Consequently, I will introduce new concepts for increasing the
sensitivity
of infrared near-field spectroscopy to ultimately allow for a
broadband
operation.
\\[4pt]
[1] T. Taubner, D. Korobkin, Y. Urzhumov, G. Shvets, R. Hillenbrand,
\textit{Science} \textbf{313}, 1595 (2006).
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[2] T. Taubner, R. Hillenbrand, F. Keilmann, \textit{Applied
Physics Letters} \textbf{85}, 5064 (2004).
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[3] A. Huber, D. Kazantsev, F. Keilmann, J. Wittborn, R.
Hillenbrand,
\textit{Advanced Materials} \textbf{19}, 2209 (2007).
\\[0pt]
[4] M. Brehm, T. Taubner, R. Hillenbrand, F. Keilmann,
\textit{Nano Letters} \textbf{6}, 1307
(2006).
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[5] R. Hillenbrand, T. Taubner, F. Keilmann, \textit{Nature}
\textbf{418}, 159 (2002).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.MAR.T9.4