Hetero‐shaped thermoelectric (TE) generators (TEGs) can power the sensors used in safety monitoring systems of undersea oil pipelines, but their development is greatly limited by the lack of materials with both good shape‐conformable ability and high TE performance. In this work, a new ductile inorganic TE material, Ag20S7Te3, with high TE performance is reported. At 300–600 K, Ag20S7Te3 crystallizes in a body‐centered cubic structure, in which S and Te atoms randomly occupy the (0, 0, 1) site. Due to the smaller generalized stacking fault energy in the (101¯)[010] slip system, Ag20S7Te3 shows better ductility than Ag2S, yielding excellent shape‐conformability. The high carrier mobility and low lattice thermal conductivity observed in Ag20S7Te3 result in a maximum dimensionless figure of merit (zT) of 0.80 at 600 K, which is comparable with the best commercial Bi2Te3‐based alloys. The prototype TEG consisting of 10 Ag20S7Te3 strips displays an open‐circuit voltage of 69.2 mV and a maximum power output of 17.1 µW under the temperature difference of 70 K. This study creates a new route toward hetero‐shaped TEG.
Following pioneering work, solution-processable Mn-activated fluoride pigments, such as ABF (A = Na, K, Rb, Cs; A = Ba, Zn; B = Si, Ge, Ti, Zr, Sn), have attracted considerable attention as highly promising red phosphors for warm white light-emitting diodes (W-LEDs). To date, these fluoride pigments have been synthesized via traditional chemical routes with HF solution. However, in addition to the possible dangers of hypertoxic HF, the uncontrolled precipitation of fluorides and the extensive processing steps produce large morphological variations, resulting in a wide variation in the LED performance of the resulting devices, which hampers their prospects for practical applications. Here, we demonstrate a prototype W-LED with KAlF:Mn as the red light component via an efficient and water-processable cation-exchange green route. The prototype already shows an efficient luminous efficacy (LE) beyond 190 lm/W, along with an excellent color rendering index (Ra = 84) and a lower correlated color temperature (CCT = 3665 K). We find that the Mn ions at the distorted octahedral sites in KAlF:Mn can produce a high photoluminescence thermal and color stability, and higher quantum efficiency (QE) (internal QE (IQE) of 88% and external QE (EQE) of 50.6%.) that are in turn responsible for the realization of a high LE by the warm W-LEDs. Our findings indicate that the water-processed KAlF may be a highly suitable candidate for fabricating high-performance warm W-LEDs.
Several Toll-like receptors (TLRs) are expressed in Sertoli cells and can trigger testicular innate responses after activation by ligands. TLR signaling pathway must be tightly controlled because unrestrained TLR activation generates a chronic inflammatory milieu that often leads to pathogenesis of the host. However, the regulation of TLR signaling in Sertoli cells remains to be clarified. Here we demonstrate that Tyro3 subfamily of receptor tyrosine kinases, Tyro3, Axl, and Mer (TAM), negatively regulate TLR3 signaling in Sertoli cells. Sertoli cells from TAM triple mutant (TAM(-/-)) mice exhibit an excessive activation of TLR3 in response to its ligand polyinosinic-polycytidylic acid, resulting in the up-regulation of inflammatory cytokines including IL-1beta, IL-6, TNFalpha, and type I interferons (alpha and beta). Growth arrest-specific gene 6 (Gas6), a common ligand of TAM receptors, inhibits the TLR3-driven expression of cytokines in Sertoli cells. This TAM-mediated inhibition of TLR3 signaling in Sertoli cells is transduced through the up-regulation of TLR signaling suppressors suppressor of cytokine signaling-1/3 by Gas6. Moreover, we provide evidence that TAM inhibition of inflammatory cytokine production by Sertoli cells may have physiological significance in vivo. These results illuminate a negative regulatory mechanism of TLR3 signaling in Sertoli cells, which may participate in controlling the testicular innate immune responses to pathogens.
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