Low degradation rate in strained InGaAs/AlGaAs single quantum welllasers

A 10000 h, 30°C constant-current lifetest performed on five strained In_0.2Ga_0.8As/AlGaAs single-quantum-well lasers, with λ~930 nm, is discussed. The devices are 90-μm×400-μm oxide-stripe lasers with facet coatings, grown by atmospheric pressure organometallic vapor-phase epitaxy. For each diode, the current was maintained at a constant value of ~300 mA, corresponding to approximately 100 mW of output power. After 10⁴ h, thresholds increased from an average of 84 mA to 108 mA, while quantum efficiencies were essentially unchanged. In relation to a typical 100-mW constant-power lifetest, this is equivalent to a degradation rate of less than 1%/kh     

New Class of Efficient Terahertz Generators: Effective Terahertz Spectral Filling by Complementary Tandem Configuration of Nonlinear Organic Crystals

Intense table‐top terahertz (THz) sources, which have progressed tremendously in the last decade, are becoming more important for advanced THz science to study light–matter interactions and subsequent applications. Nonlinear optical organic crystals exhibit great potential for intense broadband THz wave generation due to their large nonlinearities and advantageous phase‐matching characteristics. However, the phonon‐induced absorption of most organic crystals in the THz region leads to undesired modulation of the spectrum and limits the THz output efficiency. To overcome such drawbacks, phonon‐mode engineering by modification of molecular structures is suggested, but intrinsic limitations still remain. Here, an efficient alternative approach has been recently proposed for generating intense broadband THz waves based on a tandem configuration that combines two complementary nonlinear organic crystals. Such configuration compensates for the spectral gap of the generated THz waves mainly caused by phonon absorption and additionally enhances the optical‐to‐THz conversion efficiency. The proposed organic tandem generator indicates a substantial enhancement of the peak‐to‐peak THz electric field due to effective spectral filling at phonon absorption gaps. As a result, such tandem configuration provides a versatile platform to generate gapless broadband THz spectra with suppressed phonon absorption and contributes to advancing the development of intense broadband coherent THz sources.     

Recent Advances and Perspectives on Powder-Based Halide Perovskite Film Processing

Halide perovskites have undergone an impressive development and could be used in a wide range of optoelectronic devices, where some of them are already at the edge of commercialization, e.g., perovskite solar cells. Recently, interest in perovskites in powder form has increased, as for example, they are found to exhibit high stability and allow for easy production of large quantities. Accordingly, also the topic of processing thin and thick films on the basis of perovskite powders is currently gaining momentum. Here, perovskite powder can form the basis for both, typical wet and solvent-based processing approaches, as well as for dry processes. In this Progress Report, the recent developments of halide perovskites in powder form and of film processing approaches are summarized that are based on them. The advantages and opportunities of the different processing methods are highlighted, but their individual drawbacks and limitations are also discussed. Prospects are also pointed out and possible steps necessary to unlock the full potential of powder-based processing methods for producing high quality thick and thin perovskite layers in the future are discussed.     

Chemically Stable,Strongly Adhesive Sealant Patch for Intestinal Anastomotic Leakage Prevention

Intestinal anastomotic leaking, which involves the discharge of chemically aggressive, non-sterile fluids into the abdomen, remains one of the most dreaded postoperative complications of abdominal surgery. Depending on the site and the patient condition, incidence ranging between 4% and 21% and mortality rates up to 27% are reported. Currently available surgical sealants only poorly address the issue, especially since most commonly used fibrin glues fail due to insufficient adhesion and chemical instability. Here, a chemically highly resistive, leak-tight, and mucoadhesive hydrogel sealant, which is grafted on the surface of the intestinal wall using a mutually interpenetrating network that traverses hydrogel and tissue is presented. In contrast to clinically used fibrin-based sealants (including Tachosil), the developed adhesive poly(acrylamide-methyl acrylate-acrylic acid) patch does not degrade and exhibits strong tissue adhesion even when exposed to intestinal fluid. The biocompatible hydrogel patch effectively seals anastomotic leaks in ex vivo intestinal models, greatly surpassing commercial sealants (time to patch-failure >24 h compared to 5 min for commonly used Tachosil). Importantly, the developed adhesive patch paves the way for the application of both mechanically and chemically robust sealants suitable for the treatment and prevention of intestinal leaks.     

Terahertz Phonon Mode Engineering of Highly Efficient Organic Terahertz Generators

For terahertz (THz) wave generators based on organic electrooptic crystals, their intrinsic phonon modes are playing an essential role in THz generation characteristics. Here, this study proposes an effective design strategy for THz phonon mode engineering of organic electrooptic salt crystals for efficient optical‐to‐THz frequency conversion. To reduce phonon‐mode intensity, strongly electronegative trifluoromethyl group acting as strong hydrogen‐bond acceptor is incorporated into molecular anions. New 2‐(4‐hydroxy‐3‐methoxystyryl)‐1‐methylquinolinium 4‐(trifluoromethyl)benzenesulfonate (HMQ‐4TFS) crystals exhibit a relatively small absorption coefficient in the THz spectral range between 0.5 and 4 THz, which is attributed to suppressed molecular vibrations due to strong hydrogen bonds involving the 4TFS anion. In addition, HMQ‐4TFS crystals possess a very large macroscopic optical nonlinearity, comparable (or even higher) to benchmark stilbazolium crystals. Based on the low‐intensity THz phonon modes and the large optical nonlinearity, a 0.37 mm thick HMQ‐4TFS crystal pumped with 150 fs infrared laser pulses facilitates very efficient THz wave generation by optical rectification, delivering 23 times higher peak‐to‐peak THz electric field than the widely used standard inorganic ZnTe crystal (1.0 mm thick) and a broader spectral bandwidth. Therefore, strongly electronegative groups introduced into molecular salt electrooptic crystals provide a very promising design strategy of THz phonon mode engineering for developing intense broadband THz sources.     

Link state opportunistic routing for multihop wireless networks

Wireless Networks - Enhancing the quality of service is the crucial issue of future wireless networks. In this paper, we propose a new multihop wireless routing protocol inspired by opportunistic...     

Increase in external quantum efficiency of encapsulated silicon solar cells from a luminescent down‐shifting layer

This paper reports the external quantum efficiency (EQE) of encapsulated screen‐printed crystalline silicon solar cells, where the encapsulation includes a layer of luminescent down‐shifting (LDS) molecules. At wavelengths less than 400 nm, the inclusion of the LDS molecules increases the EQE from near zero to, at most, 40%. The increase in EQE corresponds to a rise in short‐circuit current density of 0·37 ± 0·13 mA/cm² under the AM1‐5g spectrum. Copyright © 2008 John Wiley & Sons, Ltd.     

Organic Junction Field‐Effect Transistor

The realization and performance of a novel organic field‐effect transistor—the organic junction field‐effect transistor (JFET)—is discussed. The transistors are based on the modulation of the thickness of a depletion layer in an organic pin junction with varying gate potential. Based on numerical modeling, suitable layer thicknesses and doping concentrations are identified. Experimentally, organic JFETs are realized and it is shown that the devices clearly exhibit amplification. Changes in the electrical characteristics due to a variation of the intrinsic and the p‐doped layer thickness are rationalized by the numerical model, giving further proof to the proposed operational mechanism.     

Hybrid Cache Analysis in Running Time Verification of Embedded Software

Verification of software running time is essential in embedded systemdesign with real-time constraints. Simulation with incomplete test patternsis unsafe for complex architectures when software running times are inputdata dependent. Formal analysis of such dependencies leads to software runningtime intervals rather than single values. These intervals depend on programproperties, execution paths and states of processes, as well as on the targetarchitecture. In the target architecture, caches have a major influence onsoftware running time. Current cache analysis techniques as a part of runningtime analysis approaches combine basic block level cache modeling with explicitor implicit program path analysis. We present an approach that extends instructionand data cache modeling from basic blocks to program segments thereby increasingthe overall running time analysis precision. We combine it with data flowanalysis based prediction of cache line contents. This novel cache analysisapproach shows high precision in the presented experiments.