Fabrication and Evaluation of Bimetallic Materials for Removal of Cr6+

Adsorption technology is an effective way for removal of heavy metals ions and other organic pollutants in water treatment. In recent years, bimetallic adsorbents with high performance and low cost have attracted more and more attention. In this study, nano zero valent iron was prepared. On this basis, Fe/Cu Bimetallic materials were prepared. The effects of Cu conversion, initial concentration, time, and pH value on Cr6+ removal rate and amount were systematically tested. The results show that under the conditions of initial concentration (50mg/L), time (60min) and pH (3), the Fe/Cu material with copper conversion of 3% has the best effect on the removal of Cr6+ in wastewater. Thus, this study is expected to provide important reference data for the effective removal of Cr6+ in water.

Gas desulfurization adsorption technology

Adsorption technologies used for gas desulfurization are a widespread technique which, due to its relative simplicity, are widely used to the purification smaller volumes of gas. However, for their trouble-free and economical use, it is necessary to respect several basic requirements for the selection of suitable types of adsorbents with respect to the specific composition of the purified gas. The article provides a brief overview of the history of the development of adsorption technologies and also provides several different examples of the operational use of this technology for the purification of gases containing high concentrations of sulfur substances. Furthermore, the principles of correct selection of a suitable adsorbent for specific application cases are also specified here. Iron oxide adsorbents were used in the early times of the operation of the technology, which were inexpensive but had a relatively low sorption capacity for sulfur compounds. Therefore, sorbents based on iron oxides have been gradually replaced by more powerful, but also more expensive sorbents based on activated carbon. Initially, activated carbon without impregnation was used, the production of which took place in the Czech Republic on an industrial scale. By the further development of impregnated types of activated carbon and their introduction into industrial production, these adsorbents have been also used in adsorption technologies intended for gas desulfurization. Their sorption capacity is much higher in comparison with non-impregnated types of activated carbon, because the impregnants used convert sulfur compounds from gas into non-volatile substances (elemental sulfur, sulfides, polysulfides). This ensures a long service life of the adsorbent and high efficiency of gas purification from sul-fur substances.

Design Optimization and Simulation of an Ice Plant Working by Solar Adsorption Technology

This research presents a design optimization of a solar adsorption ice plant using activated carbon and methanol as working pairs in the climate of Makkah to produce a ton of ice per day. The plant consists of six adsorption refrigeration units. Each unit has 72 separate cylindrical adsorbent beds connected with its own condenser, valve, and evaporator. The unit is heated by seven evacuated-tube collectors connected in parallel. Then the total number of collectors are 42 collectors. The beds are filled by estimated amount of 540 kg of activated carbon with 178 kg of methanol. Selection and dimensioning of each component were carried out based on previous recommended values. A mathematical model and simulation were developed to validate the system performance along the year. The results showed that plant could produce up to ton of ice daily along the year. The coefficient of performance can reach 0.9 with condenser and evaporator temperatures of 35°C and -5°C respectively. The performance of the system is greatly affected by ambient temperature than solar radiation. Therefore, the best performance and largest amount of ice was found in the winter season.

Applications of aluminum oxide and nano aluminum oxide as adsorbents: review

Metal oxides are widely used in adsorption technology as adsorbent surfaces because of their efficiency, low cost and unique physical properties. The aim of this review to clarify the role of aluminium oxide and Nano aluminium oxide in removing some chemicals contain that influence on human health such as dyes, antibiotics, and heavy metals. This paper also includes the affective of some adsorption parameters like pH, contact time, removal percentageand temperature. The Adsorption nature, kinetic adsorption models and isotherm models are also reported here.

Enhanced Adsorption of Cooking Fume Pollutants By Loofah Carbon Modified By Fenton Reagents

In this study, natural loofah was used as a raw material to adsorb cooking fume pollutants after grinding into a powder (TGS), activation by phosphoric acid to generate activated loofah carbon (TGSC-0), and further modification by Fenton’s reagent (TGSC-1). SEM, GC-MS, FT-IR, and X-ray diffraction analyses, in addition to surface area and pore measurements, were used to characterize the adsorption performance of TGS, TGSC-0, and TGSC-1 toward cooking fume pollutants including oils, particulate matter, and non-methane hydrocarbon). TGSC-1 was the best adsorbent when compared against TGS and TGSC-0, and exhibited saturated adsorption capacities for oil, non-methane hydrocarbon (NMHC), PM2.5, and PM10 of 10.367 mg/g, 4.132 mg/g, 5.613 μg/g, and 16.486 μg/g, respectively. Microscopy indicated that the TGSC-1 surface was rougher than that of TGSC-0. In addition, the adsorption properties of TGSC-1 were enhanced due to abundant hydroxyl, carbonyl, and carboxyl groups on the material surfaces, while iron was also present in the amorphous form that was generated on TGSC-1 surfaces from Fenton’s reagent. As TGSC-1 mass increased, the adsorption breakthrough time and adsorption capacity for simulated cooking fumes (SCFs) gradually increased. Further, Langmuir models better fit the adsorption process based on the highest R2 values being observed for Langmuir model fitting curves of TGSC-1 adsorption of pollutants (i.e., oils, NMHC, PM2.5, and PM10) from SCF, suggesting that adsorption was primarily due to monolayer adsorption and that chemical adsorption plays a major role in this process. This study provides a theoretical basis for the application of TGSC adsorption technology in the treatment of cooking fumes.

Targeting Cytokines, Pathogen-Associated Molecular Patterns, and Damage-Associated Molecular Patterns in Sepsis via Blood Purification

Sepsis is characterized by a dysregulated immune response to infections that causes life-threatening organ dysfunction and even death. When infections occur, bacterial cell wall components (endotoxin or lipopolysaccharide), known as pathogen-associated molecular patterns, bind to pattern recognition receptors, such as toll-like receptors, to initiate an inflammatory response for pathogen elimination. However, strong activation of the immune system leads to cellular dysfunction and ultimately organ failure. Damage-associated molecular patterns (DAMPs), which are released by injured host cells, are well-recognized triggers that result in the elevation of inflammatory cytokine levels. A cytokine storm is thus amplified and sustained in this vicious cycle. Interestingly, during sepsis, neutrophils transition from powerful antimicrobial protectors into dangerous mediators of tissue injury and organ dysfunction. Thus, the concept of blood purification has evolved to include inflammatory cells and mediators. In this review, we summarize recent advances in knowledge regarding the role of lipopolysaccharides, cytokines, DAMPs, and neutrophils in the pathogenesis of sepsis. Additionally, we discuss the potential of blood purification, especially the adsorption technology, for removing immune cells and molecular mediators, thereby serving as a therapeutic strategy against sepsis. Finally, we describe the concept of our immune-modulating blood purification system.