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Plenary
Speech:
Design ab-initio of Coherent
Thermal Sources
Professor Philippe Ben-Abdallah
French National Center for Scientific Research
Laboratoire de Thermocinetique UMR CNRS 6607
Ecole Polytechnique de l'Universite de Nantes
44306 Nantes, France
Abstract: Controlling the spatial or temporal
coherence of thermal light a hot body emits when it relaxes to lower states
is undoubtedly one of major objectives for improving the efficiency of
numerous actual technologies such as thermophotovoltaic conversion devices,
radiative cooling systems, infrared gas sensors and highly
directional/narrow band thermal radiators. Until recently thermal sources
were considered as objects that were able to emit light only over a broad
band of the infrared spectrum. Today we know this paradigm is wrong and
several partially coherent thermal sources have been already fabricated. The
physical origin of these unusual behaviors comes from the structures at the
wavelength scale of materials used to fabricate these sources and from the
presence of surface waves. Roughly speaking, in the first generation of
partially coherent thermal sources, polar materials surmounted by an
appropriate surface grating were used to diffract the surface phonon-polaritons
into the far field. This principle has opened new prospects for engineering
the radiative properties of these media. One of the best achievements in the
design of coherent thermal sources has been obtained later with photonic
crystals. These periodic dielectric structures-also known as photonic band
gap (PBG) materials have, for almost two decades, attracted much attention
because of their high potentiality in numerous applied and theoretical
fields. At sufficient refractive index contrast, PBG forbid photons to
propagate through them at certain frequencies, irrespective of propagation
direction in space and polarization. Coupled with frequency selective
surfaces photonic crystals have recently allowed the construction of narrow
bands IR emitters. These last years promising results have opened prospects
for the fabrication of temporally coherent IR sources when a defect is
introduced into a photonic crystal. Such defects act like waveguides with a
confinement achieved by means of the photonic band gap and not by total
internal reflection as in traditional wave guides. The latest generation of
partially coherent thermal sources, has been engineered by coupling polar
layers with photonic crystals. These structures exhibit highly directional
and narrow bands emission patterns for both p- and s-polarization states of
the thermal light. Similar antenna-like emission patterns also have been
achieved with completely different physical mechanisms using simple thin
fims and more recently resonant cavities coupled with metallic layers.
Another direction of research has been recently explored for designing
thermal antennae with left-handed material (LHM) which are engineered from
one-dimensional periodic metallic structures. Near the plasmon resonance of
these structures, the effective optical index is close to zero. Therefore,
in accordance with the Snell-Descartes laws, the radiation emitted by a
source embedded in this medium is expected to be refracted around the normal
to the surface. However, no LHM material have been built so far to operate
in the infrared range. Moreover, although these structures make it possible
to consider many applications at localized frequencies they seem, because of
the dispersion, much more difficult to exploit for designing spatially
coherent thermal sources over a broad spectral band. All distinct approaches
mentioned above have led to highly directional, narrow band partially
coherent thermal sources. However it is not known whether the corresponding
structures truly achieve the maximum permissible coherence degree. This is
due on the fact that only heuristic strategies based on trial-and-error have
been followed for engineering such sources. In this lecture we present a
general method for the ab initio design of coherent thermal sources by using
only the first principles of optics. The ability to artificially grow, from
modern deposition techniques, complex structural configurations of planar
heterogeneous metallic/dielectric materials raises the issue of the best
achievable thermal emitter that is with the highest directivity and/or with
the narrowest band of emission in a given spectral range. This engineering
design problem is formally a type of mathematical inverse problem. After an
overview on the actual coherent thermal sources, I will present a new
strategy to solve this problem. From our current research I will present two
examples of multilayered thermal sources. These planar structures involves
dielectric and metallic films only without gratings and can be used to
realize coherent emission for either polarization both in the far field and
in the near-field. The first example I will present is a quasi-isotropic
source that has been imagined to radiate in the far field in a narrow
spectral band for both polarization states at ambient temperature. It was
found that the designed structure can be interpreted as a phonon-polariton
resonant guide which converts any photon into atomic vibration at a
localized frequency for both polarization states. The second example is a
multilayered metallic source which strongly enhance the near-field thermal
emission. I will conclude by raising some significant questions.
Brief Biography of the Speaker:
Formation et postes précédents / Background :
-Thèse de doctorat au Laboratoire d'Etudes Thermiques (CNRS-ENSMA)
-Postdoctorat at Québec University (Canda)
-Chargé de Recherche à l'Ecole Nationale Supérieure de Mécanique et
d'Aérotechnique (CNRS)
-Chargé de Recherche à l'Ecole Poytechnique (CNRS)
Quelques pubications récentes/ A few recent publications :
- P. BEN ABDALLAH and B. NI
"Single-defect Bragg stacks for high-power narrow-band thermal emission
Journal of Applied Physics. 97, 104910, 2005"
- P. BEN ABDALLAH, B. NI, A. OULD EL MOCTAR , N. AUBRYand P. SINGH
"Optical manipulation of neutral nanoparticles suspended in a
microfluidic channel, Journal of Applied Physics, 99, 094303, 2006."
- P. BEN-ABDALLAH,
"Heat transfer through near-field interactions in
nanofluids, Applied Physics Letters, 89, 113117, 2006"
- P. BEN-ABDALLAH,
"Dynamic structure and cluster formation in confined
nanofluids under the action of an external force field, Physical Review E,
74, 041407 (2006)"
- J. Drevillon (PhD) and P. Ben-Abdallah,
"Ab initio design of coherent
thermal sources, J. Appl. Phys., 102, 114305, 2007."
- P. Ben-Abdallah*, K. Joulain, J. Drevillon and C. Le Goff,
"Heat transport
through plasmonic interactions in closely spaced metallic nanoparticles
chains, Phys. Rev. B, to appear 2007"
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