Transformation of CO2 into high-value, long-chain carbon compounds is a long-term goal for CO2 conversion and utilization. Electrocatalytic CO2 reduction can achieve C1/C2 products with a high formation rate, while biosynthesis can utilize these C1/C2 species as substrates for carbon chain elongation. Coupling these two processes offers a promising avenue for efficient CO2 fixation via synergizing the advantages of both sides. However, it is still challenging to realize its widespread application because of the poor compatibility between different modules. This review summarizes and discusses current developments in electrocatalytic-biosynthetic hybrid systems for CO2 upcycling. First, the recent advances of individual modules are introduced, including conversion pathways, representative electrocatalysts and typical reactors for electrocatalytic CO2 reduction process and microbial synthesis and in vitro multi-enzyme cascade catalysis for low-carbon bio-conversion process. Then, key factors that influence system coupling are discussed via analyzing the features of single modules and their cross-interference effects. Finally, several construction strategies are proposed based on different integration scenarios, offering guidance for the design and optimization of these hybrid systems.
CO2 and greenhouse gas emissions have become a major environmental issue worldwide, and emissions have spiked faster than most could ever imagine. The issues have made it crucial to find financially feasible and long-term, use-efficient solutions that fulfill industrial needs. As society so much depends on the current industry outputs, we need to reduce emissions coming from those industrial facilities and premises where people shop and buy services and assets on a daily basis. These emissions need to be reduced on a global scale, and here, concrete as a building material comes into play as one of the most used materials, especially on industrial floors. A typical solution is a sturdy base slab with a use case-specific coating on it. The base slab is expected to last the whole life of the building, whereas the coating might be considered consumable and refurbished/fixed as a maintenance job many times before the building itself is demolished. In heavy use cases, the maintenance cycle might be fast, which reduces the usable time of the building and generates downtimes for business. The coating decisions have a major impact on the building’s lifetime emissions, which is the key focus of this study, too. Bad decisions can introduce unnecessary microplastics and nano dust particles to work environments and also generate restructuring needs of the operational activities. In the worst case, operations have to be shut down. Luckily, there are options, and emissions can be reduced in many ways. By using long-term and durable cementitious mix-based dry shake coatings, one can reduce top coating-based emissions, and by decreasing the amount of used reinforcement components in the base slab, an extra positive impact can be achieved. With a base slab, also more environmentally friendly low-carbon cement formulations can be considered, like fly ash or GGBS (ground granulated blast furnace slag) based formulas, which we discuss in detail and analyses traditional options compared to modern CEM3a and CEM3b versions. For the top coating, emissions are generated in the construction and maintenance phases. To find different options with cross implications on lifetime emissions, our study analyzes CO2 emissions sources for several concrete mixes, which are then paired with floor-top coatings based on Cementous mix or epoxy coating. We have pinpointed the potential for reducing the building’s floor-based lifetime CO2 emissions. The analysis is based on the impacts of the base slab and floor coating selection combinations. As a de facto comparison element, we used a 100 percent virgin Portland cement-based mix. The Portland cement was compared to CEM3a and CEM3b mixes. On the top surface of the floor, traditional epoxy base floor coating was compared to a modern dry shake-based option. In the analysis, the dry-shake-based floor showed major benefits. Emissions were drastically reduced, fewer maintenance downtimes were needed, and the general life expectancy was a lot longer for the dry shake option.
Orthoptera are often surveyed in research on urban environments, but results are ambiguous in different regions and cities. We studied the insects in a city located in the centre of the East-European plain, at the junction of the Continental and Boreal biogeoregions. We distinguished suburbs and the urban landscape and meadows and lawns within the urban landscape. To find orthopterans in grassland habitats, we used sweepnet, acoustic and visual observations, and pitfall traps. Urban habitats are colonised by 20 species of Orthoptera from 29 species observed in the suburbs. Only five species are as frequent in urban habitats as in suburban ones. The urban environment negatively affects both forest species, all three species of dry meadows and only one of ten grassland generalists. On lawns, we found 11 species. Total abundance and species numbers were lower in lawns than in meadows. Only three late-emerging and high-dispersing species were quite frequent in lawns. The occurrence of Conocephalus fuscus in lawns was positively influenced by the presence of uncut patches, Chorthippus dorsatus—by the density of the herb layer. Ch. mollis, which is native to dry meadows, preferred unshaded lawns. Chorthippus biguttulus is a single species inhabiting lawns of almost every quality.
Exif metadata contained in digital photographs is an important forensic resource, offering authentic information like timestamps, geolocation, and device identifiers. The research assesses the integrity of Exif information on various methods of image transmission, such as USB, email, and messaging platforms like WhatsApp, Telegram, Signal, Instagram, Facebook Messenger, and Snapchat. With the controlled image dataset of Android, iOS phones, and the Flickr Creative Commons collection, we examined metadata preservation using forensic software (Magnet AXIOM, FTK, XRY, ExifTool). Document-based modes and direct transfers (USB, email) maintained all Exif fields and file hashes, providing forensic integrity. Chat/image-based transfers, fueled by compression, effectively remove metadata, changing the file integrity. These results emphasize the necessity of platform-aware evidence handling in order to preserve metadata integrity during digital forensic examinations.
Silicon carbide (SiC) ceramics have become critical materials for high-temperature engineering applications because of their exceptional mechanical strength, thermal conductivity, and chemical stability. In order to meet the diverse needs of industrial applications, various sintering methods have been developed. These include traditional methods such as pressureless sintering, reaction-bonded sintering, hot pressing, and recrystallization, as well as advanced technologies like spark plasma sintering, oscillatory pressure sintering, and flash sintering. This review provides a systematic analysis of both traditional and advanced sintering techniques for SiC ceramics. It highlights their mechanisms, critical process parameters, and impacts on the final material properties. Key challenges, including high sintering temperatures, additive selection, microstructural control, and scalability, are examined. Strategies for balancing cost-efficiency with performance are also discussed. In addition, recent advancements in SiC-based composite materials for applications ranging from aerospace components to catalytic filtration systems are presented. Finally, future research directions are proposed. These focus on precise additive engineering, microstructure tailoring, and innovative sintering methodologies to speed up the transition of high-performance SiC ceramics from laboratory prototypes to large-scale industrial implementation.
