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(419) Production(s) de l'année 2017
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Non invasive blood flow features estimation in cerebral arteries from uncertain medical data
Auteur(s): Lal Rajnesh, Nicoud Franck, Le Bars E., Deverdun J., Molino F., Costalat Vincent, Mohammadi Bijan
(Article) Publié:
Annals Of Biomedical Engineering, vol. 45 p.2574–2591 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01575417_v1
DOI: 10.1007/s10439-017-1904-7
WoS: 000414172300008
Exporter : BibTex | endNote
4 Citations
Résumé: A methodology for non-invasive estimation of the pressure in internal carotid arteries is proposed. It uses data assimilation and Ensemble Kalman filters in order to identify unknown parameters in a mathematical description of the cerebral network. The approach uses patient specific blood flow rates extracted from Magnetic Resonance Angiography and Magnetic Resonance Imaging. This construction is necessary as the simulation of blood flows in complex arterial networks, such as the circle of Willis, is not straightforward because hemodynamic parameters are unknown as well as the boundary conditions necessary to close this complex system with many outlets. For instance, in clinical cases, the values of Windkessel model parameters or the Young's modulus and the thickness of the arteries are not available on per-patient cases. To make the approach computational efficient, a reduced order zero-dimensional compartment model is used for blood flow dynamics. Using this simplified model, the proof-of-concept study demonstrates how to use the EnKF as an optimization tool to find parameters and how to make the inverse hemodynamic problem tractable. The predicted blood flow rates in the internal carotid arteries and the predicted systolic and diastolic brachial blood pressures are found to be in good agreement with the clinical measurements.
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Catching up with experiments: Equilibrium simulations of supercooled liquids beyond laboratory time scales
Auteur(s): Coslovich D., Berthier L., Ninarello A. S., Ozawa M.
Conference: 10th Liquid Matter Conference (Ljubljana, SI, 2017-07-17)
Ref HAL: hal-01576120_v1
Exporter : BibTex | endNote
Résumé: Computer simulations give precious insight into the microscopic behavior of disordered and amorphous materials, but their typical time scales are orders of magnitude shorter than the experimentally relevant ones. In particular, simulations of supercooled liquids cover at most 4-5 decades of viscous slowing down, which falls far short of the 13 decades commonly accessible in experimental studies. We close this enormous gap for a class of realistic models of liquids, which we successfully equilibrate beyond laboratory time scales by means of the swap Monte Carlo algorithm. We show that combined optimization of selected features of the interaction potential, such as particle softness, polydispersity and non-additivity, leads to computer models with excellent glass-forming ability. For such models, we achieve over 10 orders of magnitude speedup in equilibration time scale. This numerical advance allows us to address some outstanding questions concerning glass formation, such as the role of local structure and the relevance of an entropy crisis, in a dynamical range that remains inaccessible in experiments. Our results support the view that non-trivial static correlations continue to build up steadily in supercooled liquids even below the laboratory glass temperature.
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Polarization Properties of Laser Solitons
Auteur(s): Rodriguez Pedro, Jimenez Jesus, Guillet T., Ackemann Thorsten
(Article) Publié:
Applied Sciences, vol. 7 p.442 (2017)
Texte intégral en Openaccess :
Ref HAL: hal-01576088_v1
DOI: 10.3390/app7050442
WoS: WOS:000404449000010
Exporter : BibTex | endNote
1 Citation
Résumé: The objective of this paper is to summarize the results obtained for the state of polarization in the emission of a vertical-cavity surface-emitting laser with frequency-selective feedback added. We start our research with the single soliton, this situation presents two perpendicular main orientations, connected by a hysteresis loop. In addition, we also find the formation of a ring shaped intensity distribution, the vortex state, that shows two homogeneous states of polarization with very close values to those find in the soliton. For both cases above, the study shows the spatially resolved value of the orientation angle. It's important to remark too the appearance of a non negligible amount of circular light that gives vectorial character to all the different emissions investigated.
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Complexation of short ds RNA/DNA oligonucleotides with Gemini micelles: a time resolved SAXS and computational study
Auteur(s): Falsini Sara, Di Cola Emanuela, In M., Giordani Maria, Borocci Stefano, Ristori Sandra
(Article) Publié:
Physical Chemistry Chemical Physics, vol. 19 p.3046-3055 (2017)
Ref HAL: hal-01574850_v1
DOI: 10.1039/c6cp06475b
WoS: WOS:000394940400044
Exporter : BibTex | endNote
2 Citations
Résumé: Gene therapy is based on nucleic acid delivery to pathogenic cells in order to modulate their gene expression. The most used non viral vectors are lipid-based nanoaggregates, which are safer than viral carriers and have been shown to assemble easily with both DNA and RNA. However, the transfection efficiency of non viral carriers still needs to be improved before intensive practise in clinical trials can be implemented. For this purpose the in depth characterization of the complexes formed by nucleic acids and their transporters is of great relevance. In particular, information on the structure and assembly mechanism can be useful to improve our general knowledge of the se artificial transfection agents. In this paper the complexation mechanism of short interfering RNA and DNA molecules (siRNA and siDNA, respectively) with cationic micelles are investigated by combining Small Angle X-Ray Scattering experiments and Molecular Dynamics simulations. Micelles were obtained by Gemini surfactants with different spacer length (12-3-12, 12-6-12). The siRNA and siDNA used were double strand molecules characterized by the same length and homologous sequence, in order to perform close comparison. We showed that complexes appear in solution immediately after mixing and, therefore, the investigation of complex formation requires fast experimental techniques, such as stopped-flow synchrotron SAXS. The obtained systems had internal arrangement constituted by layers of squeezed micelles alternating the nucleic acids. Both SAXS and MD analysis allowed to evaluate the mean size of complexes in the range of few nanometers, with looser and less ordered stacking for the DNA containing aggregates.
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Photo-induced droop in blue to red light emitting InGaN/GaN single quantum wells structures
Auteur(s): Ngo T. H., Gil B., Damilano Benjamin, Valvin P., Courville A, Demierry P
(Article) Publié:
Journal Of Applied Physics, vol. 122 p.063103 (2017)
Ref HAL: hal-01573934_v1
DOI: 10.1063/1.4997608
WoS: 000407742400003
Exporter : BibTex | endNote
9 Citations
Résumé: The variation of the internal quantum efficiency (IQE) of single InGaN quantum well structures emitting from blue to red is studied as a function of the excitation power density and the temperature. By changing the well width, the indium content, and adding a strain compensation AlGaN layer, we could tune the intrinsic radiative recombination rate by changing the quantum confined Stark effect, and we could modify the carrier localization. Strong quantum confined Stark effect and carrier localization induce an increase in the carrier density and then favor Auger non-radiative recombination in the high excitation range. In such high excitation conditions with efficient Auger recombination, the variation of the IQE with the photo-excitation density P is ruled by a universal power law independent of the design: IQE = IQEMAX – a log10P with a close to 1/3. The temperature dependences of the different recombination mechanisms are determined. At low temperature, both quantum confined Stark effect and carrier localization trigger electron-electron repulsions and therefore the onset of the Auger effect. The increase in the value of coefficient C with changing temperature reveals indirect Auger recombination that relates to the interactions of the carriers with other phonons than the longitudinal optical one.
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Radiative heat-transfer between metallic gratings using adaptive spatial resolution
Auteur(s): Messina R., Noto A., Guizal B., Antezza M.
Conférence invité: META'17 - Incheon – Korea (Incheon - Seoul, KR, 2017-07-25)
Ref HAL: hal-01570566_v1
Exporter : BibTex | endNote
Résumé: We calculate the radiative heat transfer between two metallic gratings by exploiting the Adaptive Spatial Resolution metod. This technique dramatically improves the rate of convergence allowing to explore smaller separations. The heat flux shows a remarkable amplification of the exchanged energy, due to spoof-plasmon modes. We find a consistent disagreement with some previously obtained results going up to 50% (this disagreement is explained in terms of an incorrect connection between the reflection operators of the two gratings).
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Graphene based 1D photonic crystals bands via the Fourier Modal Method
Auteur(s): Ben Rhouma Maha, Oueslati Meherzi, Guizal B.
Conférence invité: META'17 - Incheon – Korea (Incheon - Seoul, KR, 2017-07-25)
Ref HAL: hal-01570553_v1
Exporter : BibTex | endNote
Résumé: The Fourier Modal Method (FMM) is used to obtain the band structure of a 1D graphene based photonic crystal. The structure consists of graphene layers periodically inlayed in a homogeneous dielectric medium. In the model, the graphene sheet is considered as layer with atomic thickness. Under these conditions, we show that it is possible to use the FMM in order to obtain a polynomial eigenvalue problem allowing the computation of the band structure.
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