• Physique/Matière Condensée/Matière Molle
  
• Sciences de l'ingénieur/Matériaux
  

In the design of medium and low voltage equipment such as cable accessories, generator, motor end windings or bushings, issues with electrical field enhancement occur at interfaces between insulators and conductors, resulting in accelerated material ageing. The purpose of this paper is to present a novel dielectric composite material which has the properties to mitigate this local amplification. It is a functional dielectric which resistivity decreases by several orders with electric field from 10(14) to 10(9) ohm m up to 1 kV mm(-1) while the dielectric constant decreases from 15 to 12 in the 10(-2)-10(6) Hz range. This novel material is made with graphite nanoplatelets. It may be used as a resistive or capacitive field grading material in electrical applications.

The development of smart nanomaterials has attracted great attention in several fields like nanoscience and nanotechnology due to their unique response to external stimuli. Many of them are based on polymers that can exhibit a shape-changes when submitted to environmental modifications. Poly(N-isopropylacrylamide), PNIPAM, is a thermo-responsive polymer. Linear chains are water soluble at room temperature but undergo a reversible coil-to-globule transition at a lower critical solution temperature (LCST) close to 32°C due to the dehydration and subsequent collapse of its chains into compact globules. [1] This phenomenon results in a volume phase transition (VPT) in PNIPAM based crosslinked microgels and can be used to promote original thermal effects.Hybrid nanocomposite microgels associating PNIPAM and gold nanoparticles (GNP) have thus been designed in order to take advantage of the outstanding plasmonic and photo-thermal properties of GNP to promote the VPT of the microgels through an efficient photo-thermal conversion. [2] With their strong diameter-dependent optical absorption in the near infrared (NIR) and their large surface area favoring photo-thermal transfer, semiconducting single-walled carbon nanotubes (s-SWNT) are also good candidates for photo-thermal conversion in the NIR (Figure 1a). However, to the best of our knowledge, no thorough studies of nanomaterials based on both SWNT and PNIPAM have been reported so far.Here we describe the preparation of SWNT/PNIPAM hybrid microgels through a non-covalent functionalization technique. These nanoparticles are stable in water and show a VPT, which can be promoted either by direct heating or by excitation of the resonant absorption of s-SWNT in the NIR (Figure 1b-c). The photoluminescence (PL) signal can be used to monitor the VPT by a redshift observed when crossing the LCST, while the Raman signatures remain essentially the same.

Avec la plupart des couches d’alignement classiques des cellules commerciales, il est difficile d’obtenir une texture uniforme des phases nématiques twist bend (NTB) en géométrie planaire, y compris dans des cellules très fines (~1 μm). Même lorsqu’un composé présente une phase nématique N bien alignée, on observe en effet la formation spontanée de bandes lorsque l’on passe en phase NTB [1,2,3] (voir Fig.1-a). Cette texture en rayures est caractérisée par un pas égal à deux fois l’épaisseur de la cellule [1]. Son origine est attribuée à l’amincissement rapide des pseudo-couches NTB en dessous de la température de transition N-NTB qui conduit à une instabilité d’ondulation.Nous avons étudié en détail le rôle de la force d’ancrage des couches d’alignement sur les textures NTB d’un dimère cyanophyphényle, le CB7CB (1,7-bis-4-(4-cyanobiphenyl) heptane). Pour cela nous avons utilisé un polymère dont la force d’ancrage sur les nématiques cyanobiphényles (monomères) était connue pour varier fortement selon les conditions de préparation. Une étude systématique de l’ancrage de ce polymère sur le CB7CB a été faite en phase nématique et nous avons étudié l’influence des énergies d’ancrages zénithale et azimutale sur les textures obtenues en phase NTB. Dans des cellules symétriques, nous avons ainsi montré que la périodicité des instabilités dépendait fortement de l’ancrage et notamment de sa composante azimutale.Par ailleurs, ce travail a permis de montrer qu’avec des conditions d’ancrage adéquates, il était possible d’obtenir un alignement spontané uniforme de la phase NTB (voir Fig.1-b-c). Cet alignement est conservé même en s’éloignant de la température de transition, ouvrant la possibilité future d’utiliser les phases NTB dans des dispositifs électro-optiques.

The development of smart nanomaterials has attracted great attention in several fields like nanoscience, materials science,engineering and nanotechnology due to their unique response to external stimuli. Many of them are based on polymers thatcan exhibit great shape-changes when submitted to environmental modifications. Poly(N-isopropylacrylamide), PNIPAM, is sucha thermo-responsive polymer. It is water soluble at room temperature, forming gels by cross-linking but undergoes a reversiblecoil-to-globule volume phase transition (VPT) at a lower critical solution temperature (LCST) close to 32 °C due to thedehydration and subsequent collapse of its chains into compact globules.
Hybrid nanocomposite microgels associating PNIPAM and gold nanoparticles (GNP) have been designed in order to takeadvantage of the outstanding plasmonic and photo-thermal properties of GNP to promote the volume phase transition of themicrogels through an efficient photo-thermal conversion. With their strong diameter-dependent optical absorption in the nearinfrared (NIR) and their large surface area favoring photo-thermal transfer, semiconducting SWNT (s-SWNT) are goodcandidates for photo-thermal conversion in the NIR and may therefore be used to prepare multi-responsive hybrid microgels(Figure 1). However, to the best of our knowledge, no thorough studies of such nanomaterials have been reported so far.
Here we report the preparation of smart SWNT/PNIPAM nanocomposites through non-covalent functionalization techniques.These SWNT/PNIPAM hybrid microgels are stable in water and show a VPT, which can be promoted either by direct heating orby excitation of the resonant absorption of s-SWNT in the near infrared. Furthermore, the photoluminescence (PL) signal of s-SWNT is modulated at the phase transition and therefore, the PL signal can be used to monitor the VPT. This is illustrated inFigure 2, showing coupled Raman/PL measurements below and above the LCST, where a redshift of the PL bands is observedwhen crossing the LCST while the Raman signatures remain essentially the same.

Temperature is one of the basic parameters often required to characterize a system. A great demand has arisen for localmeasurements, especially in liquids or complex biological environments. Various approaches have been proposed to study thetemperature at the nano-scale level. Some of them are based on the spectroscopic properties of carbon nanotubes (CNT) usedas sensors.
Raman spectroscopy is indeed a powerful technique to identify single-walled carbon nanotubes (SWNT) and to study theirstructure, defects and electronic properties through the measurement of specific Raman signatures (RBM, D, G and 2D bands).On the other hand, individual SWNT or small bundles emit light in the near infrared and the photoluminescence (PL) spectra isvery sensitive to the quality of the dispersion and the dielectric environment of the nanotubes. In particular, when SWNT aredispersed in aqueous solutions, the PL energies are sensitive to the nature of the surfactants or polymers, to theirconcentration, and to the way they adsorb on/wrap around the nanotubes.
In this work we show that the PL/Raman spectra of SWNT dispersed with sodium dodecyl sulfate (SDS) is very sensitive to thetemperature (figure 1) in a large range of SDS concentrations. We discuss the influence of the chiral angle of the SWNT onthese PL changes, and the origin of the changes in terms of SDS reorganization at the surface of the nanotubes. Similarchanges are obtained with increasing laser power (figure 2), showing the local heating of the nanotubes. These results pavethe way for the development of SWNT-based nano-thermometers.