A high temperature Seebeck coefficient and electrical resistivity measurement apparatus has been designed and built for measuring advanced thermoelectric materials. The apparatus covers the range of temperatures from 300 to 1300 K. Different sources of errors involved in the two measurements are discussed. The accuracy of the electrical resistivity measurement is estimated to be better than ±1% by measuring standard graphite sample from NIST.
Efficient metal-free electrocatalysts for oxygen reduction reaction (ORR) are highly expected in future low-cost energy systems. We have successfully prepared crumpled, sheet-like, sulfur-doped graphene by magnesiothermic reduction of easily available, low-cost, nontoxic CO2 (in the form of Na2CO3) and Na2SO4 as the carbon and sulfur sources, respectively. At high temperature, Mg can reduce not only carbon in the oxidation state of +4 in CO32− to form graphene, but also sulfur in SO42− from its highest (+6) to lowest valence which was hybridized into the carbon sp2 framework. Various characterization results show that sulfur-doped graphene with only few layers has an appropriate sulfur content, hierarchically robust porous structure, large surface area/pore volume, and highly graphitized textures. The S-doped graphene samples exhibit not only a high activity for ORR with a four-electron pathway, but also superior durability and tolerance to MeOH crossover to 40% Pt/C. This is mainly ascribed to the combination of sulfur-related active sites and hierarchical porous textures, facilitating fast diffusion of oxygen molecules and electrolyte to catalytic sites and release of products from the sites.
Design of endogenous stimuli-responsive
amino acids allows for
precisely modulating proteins or peptides under a biological microenvironment
and thereby regulating their performance. Herein we report a noncanonical
amino acid 2-nitroimidazol-1-yl alanine and explore its functions
in creation of the nitroreductase (NTR)-responsive peptide-based supramolecular
probes for efficient hypoxia imaging. On the basis of the reduction
potential of the nitroimidazole unit, the amino acid was synthesized
via the Mitsunobu reaction between 2-nitroimidazole and a serine derivate.
We elucidated the relationship between the NTR-responsiveness of the
amino acid and the structural feature of peptides involving a series
of peptides. This eventually facilitates development of aromatic peptides
undergoing NTR-responsive self-assembly by rationally optimizing the
sequences. Due to the intrinsic role of 2-nitroimidazole in the fluorescence
quench, we created a morphology-transformable supramolecular probe
for imaging hypoxic tumor cells based on NTR reduction. We found that
the resulting supramolecular probes penetrated into solid tumors,
thus allowing for efficient fluorescence imaging of tumor cells in
hypoxic regions. Our findings demonstrate development of a readily
synthesized and versatile amino acid with exemplified properties in
creating fluorescent peptide nanostructures responsive to a biological
microenvironment, thus providing a powerful toolkit for synthetic
biology and development of novel biomaterials.
The lack of efficient electrocatalysts for the oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) has been a fatal issue for the development of metal-air batteries in large-scale commercialization. In this paper, spinel CoFe 2 O 4 (CFO) nanoparticles were successfully in situ grown onto rod-like ordered mesoporous carbon (RC) by a facile, scalable hydrothermal method, followed by annealing at different temperatures. The as-acquired CFO/RC nanohybrid pyrolyzed at 400 C (CFO/RC-400) has a high specific surface area (150.3 m 2 g À1 ) and two sets of uniform mesopore systems (3.38 and 19.1 nm), all of which are favorable for the improvement of the electrocatalytic activity. The hybridization of CFO nanoparticles and the RC matrix results in increased ORR and OER electrocatalytic activity of the CFO/ RC nanohybrids, which is significantly superior to that of unsupported CFO nanoparticles and pure RC.CFO/RC-400 shows better catalytic activity for the ORR with a direct four-electron reaction pathway than those prepared at other temperatures in terms of the onset potential and limiting current density.Furthermore, the CFO/RC-400 nanohybrid exhibits outstanding durability for both the ORR and OER, and can outperform commercial Pt/C. The excellent bifunctional electrocatalytic activities of the CFO/ RC nanohybrids are mainly owing to the hierarchical mesoporous structures of the nanohybrids and strong coupling between the CFO nanoparticles and the RC matrix.
Thin-film ferromagnetic semiconductors Sb 2−x V x Te 3 with the Curie temperature as high as 177 K were prepared on sapphire ͑0001͒ substrates by molecular-beam epitaxy. Films of Sb 2−x V x Te 3 with x up to 0.35 display robust, out-of-plane ferromagnetic ordering that depends on the concentration of vanadium in the structure. The Curie temperature was determined from magnetization measurements and Arrott plots. Ferromagnetic order is manifested by hysteresis loops observed in magnetization, magnetoresistivity, and the anomalous Hall effect.
Tissue regeneration based on the utilization of artificial soft materials is considered a promising treatment for bone-related diseases. Here, we report cranial bone regeneration promoted by hydrogels that contain parathyroid hormone (PTH) peptide PTH(1–34) and nano-hydroxyapatite (nHAP). A combination of the positively charged natural polymer chitosan (CS) and negatively charged sodium alginate led to the formation of hydrogels with porous structures, as shown by scanning electron microscopy. Rheological characterizations revealed that the mechanical properties of the hydrogels were almost maintained upon the addition of nHAP and PTH(1–34). In vitro experiments showed that the hydrogel containing nHAP and PTH(1–34) exhibited strong biocompatibility and facilitated osteogenic differentiation of rat bone marrow mesenchymal stem cells (rBMSCs) via the Notch signaling pathway, as shown by the upregulated expression of osteogenic-related proteins. We found that increasing the content of PTH(1–34) in the hydrogels resulted in enhanced osteogenic differentiation of BMSCs. Implantation of the complex hydrogel into a rat cranial defect model led to efficient bone regeneration compared to the rats treated with the hydrogel alone or with nHAP, indicating the simultaneous therapeutic effect of nHAP and PTH during the treatment process. Both the in vitro and in vivo results demonstrated that simultaneously incorporating nHAP and PTH into hydrogels shows promise for bone regeneration, suggesting a new strategy for tissue engineering and regeneration in the future.
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