SINGLE MATERIAL SOLAR CELLS: Single Material Solar Cells: the Next Frontier for Organic Photovoltaics? (Adv. Energy Mater. 2/2011)

An overview of various approaches for the realization of single‐material organic solar cells (SMOCs) is presented. Fullerene‐conjugated systems dyads, di‐block copolymers, and self‐organized donor‐acceptor molecules all represent different possible approaches towards SMOCs. Although each of them presents specific advantages and poses specific problems of design and synthesis, these different routes have witnessed significant progress in the past few years and SMOCs with efficiencies in the range of 1.50% have been realized. These performances are already higher than those of bi‐component bulk heterojunction solar cells some ten years ago, demonstrating that SMOCs can represent a credible approach towards efficient and simple organic solar cells. Possible directions for future research are discussed with the aim of stimulating further research on this exciting topic.     

Highly Efficient Nb2C MXene Cathode Catalyst with Uniform O-Terminated Surface for Lithium–Oxygen Batteries

Highly-efficient cathode catalysts are the key to improve high rate cycle stability, avoid side reactions, and lower the overpotential of lithium–oxygen batteries (LOBs). MXenes are predicted to be one of the most impressive materials for energy applications. In this work, the catalytic capability of Nb₂C MXene is demonstrated with a uniform O-terminated surface as a cathode material for LOBs. The easily fabricated uniform O-terminated surface, high catalytic activity of Nb₂CO₂ sites, and unique reaction kinetics contribute to the excellent electrocatalytic performance of Nb₂C MXene. The uniform O-terminated surface on Nb₂C MXene is obtained after heat treatment. Density functional theory calculations reveal the superior catalytic activity of Nb₂CO₂ compared to other anchor groups and bare surfaces. The calculations also reveal the multinucleation and growth/decomposition mechanism for discharge products on the Nb₂CO₂ surface. This mechanism is believed to account for the results characterized by ex situ and in situ measurements. The spatial-direction accumulated porous discharge products at high current density contribute to the excellent high-rate cycle stability. For example, the cathodes exhibit cycle stability for 130 cycles at an ultrahigh current density of 3 A g⁻¹. The present work provides insights into the modulation of catalytic capabilities, and the rational design of high-performance MXenes based electrocatalysts.     

A Low-Cost Al(OH)3-Modified Fire-Retardant and Shuttle-Limiting Separator for Safe and Stable Lithium–Sulfur Batteries

Lithium–sulfur battery (LSB) possesses high theoretical energy density, but its poor cycling stability and safety issues significantly restrict progress in practical applications. Herein, a low-cost and simple Al(OH)₃-based modification of commercial separator, which renders the battery outstanding fire-retardant and stable cycling, is reported. The modification is carried out by a simple blade coating of an ultrathin composite layer, mainly consisting of Al(OH)₃ nanoparticles and conductive carbon, on the cathode side of the separator. The Al(OH)₃ shows strong chemical absorption ability toward Lewis-based polysulfides and outstanding fire retardance through a self-decomposition mechanism under high heat, while the conductive carbon material acts as a top current collector to prevent dead polysulfide. LSB using the Al(OH)₃-modified separator shows an extremely low average capacity decade per cycle during 1000 cycles at 2 C (0.029%, 1 C = 1600 mA g⁻¹). The pouch cell exhibiting high energy density (426 Wh kg⁻¹) can also steadily cycle for more than 100 cycles with high capacity retention (70.2% at 0.1 C). The effectiveness and accessibility of this Al(OH)₃ modification strategy will hasten the practical application progress of LSBs.     

ACE2/Ang-(1–7) signaling and vascular remodeling

The renin-angiotensin system (RAS) regulates vascular tone and plays a critical role in vascular remodeling, which is the result of a complex interplay of alterations in vascular tone and structure. Inhibition of the RAS has led to important pharmacological tools to prevent and treat vascular diseases such as hypertension, diabetic vasculopathy and atherosclerosis. Angiotensin converting enzyme 2 (ACE2) was recently identified as a multifunctional monocarboxypeptidase responsible for the conversion of angiotensin (Ang) II to Ang-(1–7). The ACE2/Ang-(1–7) signaling has been shown to prevent cellular proliferation, pathological hypertrophy, oxidative stress and vascular fibrosis. Thus, the ACE2/Ang-(1–7) signaling is deemed to be beneficial to the cardiovascular system as a negative regulator of the RAS. The addition of the ACE2/Ang-(1–7) signaling to the complexities of the RAS may lead to the development of novel therapeutics for the treatment of hypertension and other vascular diseases. The present review considers recent findings regarding the ACE2/Ang-(1–7) signaling and focuses on its regulatory roles in processes related to proliferation, inflammation, vascular fibrosis and remodeling, providing proof of principle for the potential use of ACE2 as a novel therapy for vascular disorders related to vascular remodeling.     

Mono(p-tolyl)platinum(II) and bis(p-tolyl)platinum(II) complexes of diethylsulfide as reagents for organoplatinum synthesis. Structures of [Pt(p-Tol)2(μ-SEt2)]2 and PtCl(p-Tol)(bpy) (bpy=2,2′-bipyridine)

The complex trans-PtCl(p-Tol)(SEt₂)₂ is obtained from the reaction of [Pt(p-Tol)₂(SEt₂)]₂ with PtCl₂(SEt₂)₂ and SEt₂ in mole ratio 1:2:2. The mono(p-tolyl)platinum(II) and bis(p-tolyl)platinum(II) complexes of diethylsulfide react with 2,2′-bipyridine to form the complexes PtX(p-Tol)(bpy) (X=p-Tol, Cl) and are useful reagents for organoplatinum chemistry. X-ray crystal structures are presented for square planar PtCl(p-Tol)(bpy) and the centrosymmetric dimer [Pt(p-Tol)₂(μ-SEt₂)]₂.     

Hydraulic Conductivity (Lp) and Its Activation Energy (Ea), Cryoprotectant Agent Permeability (Ps) and ItsEa, and Reflection Coefficients (?) for Golden Hamster Individual Pancreatic Islet Cell Membranes

Long-term cryopreservation of islets of Langerhans would be advantageous to a clinical islet transplantation program. Fundamental cryobiology utilizes knowledge of basic biophysical characteristics to increase the understanding of the preservation process and possibly increase survival rate. In this study several of these previously unreported characteristics have been determined for individual islet cells isolated from Golden hamster islets. Using an electronic particle counting device and a temperature control apparatus, dynamic volumetric response of individual islet cells to anisosmotic challenges of 1.5 M dimethyl sulfoxide (DMSO) and 1.5 M ethylene glycol (EG) were recorded at four temperatures (8, 22, 28, and 37°C). The resulting curves were fitted using Kedem and Katchalsky equations which describe water flux and cryoprotectant agent (CPA) flux based on hydraulic conductivity (L_p), CPA permeability (P_s), and reflection coefficient (?) for the membrane. For Golden hamster islet cells,L_p,P_s, and ? for DMSO at 22°C were found to be 0.23 ± 0.06 μm/min/atm, 0.79 ± 0.32 × 10⁻³cm/min, and 0.55 ± 0.37 (n= 11) (mean ± SD), respectively. For EG at 22°C,L_pequaled 0.23 ± 0.06 μm/min/atm,P_sequaled 0.63 ± 0.20 × 10⁻³cm/min, and ? was 0.75 ± 0.17 (n= 9). Arrhenius plots (lnL_por lnP_sversus 1/temperature (K)) were created by adding the data from the other three temperatures and the resulting linear regression yielded correlation coefficients (r) of 0.99 for all four plots (L_pandP_sfor both CPAs). Activation energies (E_a) ofL_pandP_swere calculated from the slopes of the regressions. The values for DMSO were found to be 12.43 and 18.34 kcal/mol forL_pandP_s(four temperatures, totaln= 52), respectively. For EG,E_aofL_pwas 11.69 kcal/mol andE_aofP_swas 20.35 kcal/mol (four temperatures, totaln= 58).