Piezoelectric materials, which respond mechanically to applied electric field and vice versa, are essential for electromechanical transducers. Previous theoretical analyses have shown that high piezoelectricity in perovskite oxides is associated with a flat thermodynamic energy landscape connecting two or more ferroelectric phases. Here, guided by phenomenological theories and phase-field simulations, we propose an alternative design strategy to commonly used morphotropic phase boundaries to further flatten the energy landscape, by judiciously introducing local structural heterogeneity to manipulate interfacial energies (that is, extra interaction energies, such as electrostatic and elastic energies associated with the interfaces). To validate this, we synthesize rare-earth-doped Pb(MgNb)O-PbTiO (PMN-PT), as rare-earth dopants tend to change the local structure of Pb-based perovskite ferroelectrics. We achieve ultrahigh piezoelectric coefficients d of up to 1,500 pC N and dielectric permittivity ε/ε above 13,000 in a Sm-doped PMN-PT ceramic with a Curie temperature of 89 °C. Our research provides a new paradigm for designing material properties through engineering local structural heterogeneity, expected to benefit a wide range of functional materials.
The anatomical structure of central respiratory chemoreceptors in the superficial ventral medulla of rats was studied by using hypercapnia-induced c-fos labeling to identify cells directly stimulated by extracellular pH or PCO(2). The distribution of c-fos-positive cells was found to be predominantly perivascular to surface vessels. In the superficial ventral medullary midline, parapyramidal, and ventrolateral regions where c-fos-positive cells were concentrated, we found a common, characteristic, anatomical architecture. The medullary surface showed an indentation covered by a surface vessel, and the marginal glial layer was thickened. We classified c-fos-positive cells into two types. One (type I cell) was small, was located inside the marginal glial layer and close to the medullary surface, and surrounded fine vessels. The other (type II cell) was large and located dorsal to the marginal glial layer. c-fos Expression under synaptic blockade suggested that type I cells are intrinsically chemosensitive. The chemosensitivity of surface cells (possible type I cells) surrounding vessels was confirmed electrophysiologically in slice preparations. We suggest that this characteristic anatomical structure may be the central chemoreceptor.
Peroxisome proliferator-activated receptor-␥ (PPAR␥) agonists have been shown to have significant therapeutic benefits such as desirable glycemic control in type 2 diabetic patients; however, these agents may cause fluid retention in susceptible individuals. Since PPAR␥ is expressed selectively in distal nephron epithelium, we studied the mechanism of PPAR␥ agonist-induced fluid retention using male Sprague-Dawley rats treated with either vehicle or GI262570 (farglitazar), a potent PPAR␥ agonist. GI262570 (20 mg/kg/day) induced a plasma volume expansion. The plasma volume expansion was accompanied by a small but significant decrease in plasma potassium concentration. Small but significant increases in plasma sodium and chloride concentrations were also observed. These changes in serum electrolytes suggested an activation of the renal mineralocorticoid response system; however, GI262570-treated rats had lower plasma levels of aldosterone compared with vehicle-treated controls. mRNA levels for a group of genes involved in distal nephron sodium and water absorption are changed in the kidney medulla with GI262570 treatment. In addition, due to a possible rebound effect on epithelial sodium channel (ENaC) activity, a low dose of amiloride did not prevent GI262570-induced fluid retention. On the contrary, the rebound effect after amiloride treatment potentiated GI262570-induced plasma volume expansion. This is at least partially due to a synergistic effect of GI262570 and the rebound from amiloride treatment on ENaC␣ expression. In summary, our current data suggest that GI262570 can increase water and sodium reabsorption in distal nephron by stimulating the ENaC and Na,KATPase system. This may be an important mechanism for PPAR␥ agonist-induced fluid retention.
Abstract(K,Na)NbO3 based ceramics are considered to be one of the most promising lead-free ferroelectrics replacing Pb(Zr,Ti)O3. Despite extensive studies over the last two decades, the mechanism for the enhanced piezoelectricity in multi-elements doped (K,Na)NbO3 ceramics has not been fully understood. Here, we combine temperature-dependent synchrotron x-ray diffraction and property measurements, atomic-scale scanning transmission electron microscopy, and first-principle and phase-field calculations to establish the dopant–structure–property relationship for multi-elements doped (K,Na)NbO3 ceramics. Our results indicate that the dopants induced tetragonal phase and the accompanying high-density nanoscale heterostructures with low-angle polar vectors are responsible for the high dielectric and piezoelectric properties. This work explains the mechanism of the high piezoelectricity recently achieved in (K,Na)NbO3 ceramics and provides guidance for the design of high-performance ferroelectric ceramics, which is expected to benefit numerous functional materials.
SUMMARY1. We recorded phrenic nerve activities and single unit firing of mesencephalic neurones in unanaesthetized supracollicularly decerebrated, paralysed and ventilated cats, in which vagi and carotid sinus nerves had been ablated. We made these measurements first at low levels of respiratory drive associated with normal PC02 levels, then with increased respiratory drive and levels of phrenic activity produced by hypercapnia or by carotid sinus nerve stimulation.2. We found that at least a quarter of the neuronps i the central tegmental field of the mesencephalon, which were irregularly tonic or silent at low respiratory drives, developed a rhythmic increase of firing associated with each respiration. There appeared to be a threshold at about 50% of maximum respiratory activity, below which the respiratory-associated rhythm did not occur. Above this level, neuronal firing increased in graded fashion with increasing magnitude of respiratory activity. The latency from onset of phrenic activity to onset of increased neuronal firing was quite long (1X0 s) at drives just above the threshold but shortened to as little as 0 3 s as drive increased towards its maximum.3. Cutting the spinal cord at C1-02 had no effect on the ability of increased respiratory activity to generate a respiratory-associated rhythm in mesencephalic neurones.4. Short-lasting anaesthesia with the agent Saffan caused mesencephalic neurones to lose the respiratory-associated rhythm with little change in phrenic activity and no change in respiratory cycle timing.5. We also found a mesencephalic response to ventilator-induced chest expansion.The latency of the response from onset of expansion, indexed by fall of airway PC02, to onset of neurone firing was shorter (0-2 s) than that found with the respiratoryassociated rhythm. In seventeen neurones we found both the respiratory-associated rhythm and the independent ventilator-associated rhythm.
Dry reforming of methane (DRM) is a promising chemical approach to convert greenhouse gases CO2 and CH4 into valuable fuels. Previous experimental study has shown that the addition of alkaline earth can promote the activity and stability of the Ni-based catalyst. However, the physical structure of alkaline earth additives on supports and their interaction with Ni particles should have significant influence for the catalytic performance of catalysts. To clarify the synthesis–structure–activity relationship for further improving these catalysts, the underlying reaction mechanism for DRM over size-confined Ni–CaO catalysts on neutral supports and the structure/effect of CaO as promoter were investigated combining density functional theory (DFT) calculation and experimental studies. The favored active sites for all elementary reactions were identified, and the activation energies of the reactions were calculated for the determination of the primary reaction pathways. DFT results found a cooperation effect between Ni and CaO, where the interface dissociates CO2, Ni activates CH4 dehydrogenation, and CaO attracts CO2. The interface between Ni and CaO was found to provide another channel to activate CO2 and decrease the energy barrier of CHO formation, contributing to the high efficiency and long-term stability of the catalyst. On the basis of the DFT results, the optimum stacking order between Ni and CaO was proposed, in good agreement with the experimental studies that synthesized and compared four catalysts with different Ni–CaO structures. The proposed Ni–CaO composite catalyst should be a promising catalyst for potential application in industrial dry reforming processes.
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