A Tale of Two Sites: On Defining the Carrier Concentration in Garnet‐Based Ionic Conductors for Advanced Li Batteries

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/111906/1/aenm201500096.pdfhttp://deepblue.lib.umich.edu/bitstream/2027.42/111906/2/aenm201500096-sup-0001-S1.pd

Low-temperature densification of Al-doped Li7La3Zr2O12 : a reliable and controllable synthesis of fast-ion conducting garnets

The application of Li7La3Zr2O12as a Li+solid electrolyte is hampered by the lack of a reliable procedure to obtain and densify the fast-ion conducting cubic garnet polymorph. Dense cubic Li7La3Zr2O12-type phases are typically formed as a result of Al-incorporation in an unreliable reaction with the alumina crucible at elevated temperatures of up to 1230 °C. High Al3+-incorporation levels are also believed to hinder the three-dimensional movement of Li+in these materials. Here, a new, facile hybrid sol-gel solid-state approach has been developed in order to accomplish reliable and controllable synthesis of these phases with low Al-incorporation levels. In this procedure, sol-gel processed solid precursors of Li7La3Zr2O12and Al2O3nanosheets are simply mixed using a pestle and mortar and allowed to react at 1100 °C for 3 h to produce dense cubic phases. Fast-ion conducting Al-doped Li7La3Zr2O12phases with the lowest reported Al3+-content (∼0.12 mol per formula unit), total conductivities of ∼3 × 104S cm1, bulk conductivities up to 0.6 mS and ion conduction activation energies as low as 0.27 eV, have been successfully achieved. The ease of lithium diffusion in these materials is attributed to the formation of dense cubic phases with low Al3+dopant ratios. This approach is applicable to Li7xLa3Zr2xTaxO12phases and opens up a new synthetic avenue to Li7La3Zr2O12-type materials with greater control over resulting characteristics for energy storage applications

Turn it down a notch

In the developing vertebrate embryo, segmentation initiates through the formation of repeated segments, or somites, on either side of the posterior neural tube along the anterior to posterior axis. The periodicity of somitogenesis is regulated by a molecular oscillator, the segmentation clock, driving cyclic gene expression in the unsegmented paraxial mesoderm, from which somites derive. Three signaling pathways underlie the molecular mechanism of the oscillator: Wnt, FGF, and Notch. In particular, Notch has been demonstrated to be an essential piece in the intricate somitogenesis regulation puzzle. Notch is required to synchronize oscillations between neighboring cells, and is moreover necessary for somite formation and clock gene oscillations. Following ligand activation, the Notch receptor is cleaved to liberate the active intracellular domain (NICD) and during somitogenesis NICD itself is produced and degraded in a cyclical manner, requiring tightly regulated, and coordinated turnover. It was recently shown that the pace of the segmentation clock is exquisitely sensitive to levels/stability of NICD. In this review, we focus on what is known about the mechanisms regulating NICD turnover, crucial to the activity of the pathway in all developmental contexts. To date, the regulation of NICD stability has been attributed to phosphorylation of the PEST domain which serves to recruit the SCF/Sel10/FBXW7 E3 ubiquitin ligase complex involved in NICD turnover. We will describe the pathophysiological relevance of NICD-FBXW7 interaction, whose defects have been linked to leukemia and a variety of solid cancers

Dynamique de la signalisation cellulaire au cours de la segmentation des Vertébrés

The segmentation of the anteroposterior axis in somites is a major feature of Vertebrates. This process relies on an oscillator, the “segmentation clock”. The present thesis addresses the signaling dynamics regulating this process. We studied the transcriptional regulation of Mesp2 and showed that Tbx6 controls its expression in chicken. We established an ex vivo experimental system with stable oscillations of the cyclic gene Lfng. We demonstrated the existence of a population behavior that controls the generation of oscillations and involves the Notch pathway and mechanical factors. We interpreted these observations in the framework of an excitable oscillator. Moreover, we evidenced a dose-dependent effect of Fgf signaling on cell determination that challenges current models of segmentation. Furthermore, this experimental system has enabled us to identify a role of the translation rate on the clock period. Last, we showed ongoing work aiming to recapitulate the segmentation in vitro using differentiated mouse embryonic stem cells.La segmentation de l’axe antéro-postérieur en somites est une caractéristique majeure des Vertébrés. Ce processus est basé sur un oscillateur, l’« horloge de segmentation ». Cette thèse cherche à comprendre la dynamique de signalisation régulant ce processus. Nous avons étudié la régulation transcriptionnelle de Mesp2 et nous avons montré que Tbx6 contrôle son expression chez le poulet. Nous présentons également un système d’étude ex vivo présentant des oscillations stables du gène cyclique Lfng. Nous avons mis en évidence un effet de population régulant la génération de ces oscillations et reposant sur la voie Notch et des facteurs mécaniques que nous interprétons avec un modèle d’oscillateur excitable. De plus, nous avons démontré un effet dose-dépendant de la voie Fgf sur la différenciation cellulaire, remettant ainsi en question le modèle actuel de segmentation. Par ailleurs, ce système d’étude nous a permis d’identifier un rôle du taux de traduction dans le contrôle de la période de l’horloge. Enfin, nous présentons des travaux, où nous cherchons à reconstituer l’horloge de segmentation in vitro à partir de cellules souches murines différenciées

Signaling dynamics during Vertebrate segmentation

La segmentation de l’axe antéro-postérieur en somites est une caractéristique majeure des Vertébrés. Ce processus est basé sur un oscillateur, l’« horloge de segmentation ». Cette thèse cherche à comprendre la dynamique de signalisation régulant ce processus. Nous avons étudié la régulation transcriptionnelle de Mesp2 et nous avons montré que Tbx6 contrôle son expression chez le poulet. Nous présentons également un système d’étude ex vivo présentant des oscillations stables du gène cyclique Lfng. Nous avons mis en évidence un effet de population régulant la génération de ces oscillations et reposant sur la voie Notch et des facteurs mécaniques que nous interprétons avec un modèle d’oscillateur excitable. De plus, nous avons démontré un effet dose-dépendant de la voie Fgf sur la différenciation cellulaire, remettant ainsi en question le modèle actuel de segmentation. Par ailleurs, ce système d’étude nous a permis d’identifier un rôle du taux de traduction dans le contrôle de la période de l’horloge. Enfin, nous présentons des travaux, où nous cherchons à reconstituer l’horloge de segmentation in vitro à partir de cellules souches murines différenciées.The segmentation of the anteroposterior axis in somites is a major feature of Vertebrates. This process relies on an oscillator, the “segmentation clock”. The present thesis addresses the signaling dynamics regulating this process. We studied the transcriptional regulation of Mesp2 and showed that Tbx6 controls its expression in chicken. We established an ex vivo experimental system with stable oscillations of the cyclic gene Lfng. We demonstrated the existence of a population behavior that controls the generation of oscillations and involves the Notch pathway and mechanical factors. We interpreted these observations in the framework of an excitable oscillator. Moreover, we evidenced a dose-dependent effect of Fgf signaling on cell determination that challenges current models of segmentation. Furthermore, this experimental system has enabled us to identify a role of the translation rate on the clock period. Last, we showed ongoing work aiming to recapitulate the segmentation in vitro using differentiated mouse embryonic stem cells