Hasil untuk "Chemical technology"

Robin J. White, R. Luque, V. Budarin et al.

K. Jensen

L. Mai, Xiaocong Tian, Xu Xu et al.

S. Pankaj, Zifan Wan, K. Keener

Cold plasma (CP) technology has proven very effective as an alternative tool for food decontamination and shelf-life extension. The impact of CP on food quality is very crucial for its acceptance as an alternative food processing technology. Due to the non-thermal nature, CP treatments have shown no or minimal impacts on the physical, chemical, nutritional and sensory attributes of various products. This review also discusses the negative impacts and limitations posed by CP technology for food products. The limited studies on interactions of CP species with food components at the molecular level offers future research opportunities. It also highlights the need for optimization studies to mitigate the negative impacts on visual, chemical, nutritional and functional properties of food products. The design versatility, non-thermal, economical and environmentally friendly nature of CP offers unique advantages over traditional processing technologies. However, CP processing is still in its nascent form and needs further research to reach its potential.

Suqing Wang, Lu Xia, Le Yu et al.

M. Nisoli, P. Decleva, F. Calegari et al.

Yuan-Jie Wang, Li Zhao, Alexander Otto et al.

Abstract Reducing CO 2 emissions has become a worldwide research topic. Of all the sources of CO 2 emissions, power plants burning fossil fuels, especially coals, account for a very large portion. For CO 2 capture from existing coal-fired power plants, post-combustion technology is thus far considered the most viable method due to its “end-of-pipe” characteristic. Chemical absorption or scrubbing process is currently the technology most likely to be implemented in the near future but rather energy-intensive. Membrane-based CO 2 separation process in recent years appears to be a competitive substitution for conventional chemical absorption technology. This paper reviews the basic process designs of chemical absorption and membrane-based separation processes for CO 2 capture, as well as corresponding optimization methods including optimizing operational parameters, process modifications, membrane module types and so forth. In addition, some energetic and economic estimates from other researchers for these two CO 2 capture technologies are summarized. It is found that membrane-based separation process does not possess obvious advantage over MEA-based chemical absorption process at the typical 90% CO 2 capture degree in terms of both energy consumption and cost. Therefore, various optimization methods have not changed the fact that CCS technology will lay more burdens on power plants unless they can get enough allowances from government. In recent years, hybrid system with the target of utilizing more than one single capture technology seems to be new direction from the perspective of capture process design. However, it still needs to be further investigated.

Sean Overa, B. Ko, Yaran Zhao et al.

ConspectusCarbon capture, utilization, and sequestration play an essential role to address CO2 emissions. Among all carbon utilization technologies, CO2 electroreduction has gained immense interest due to its potential for directly converting CO2 to a variety of valuable commodity chemicals using clean, renewable electricity as the sole energy source. The research community has witnessed rapid advances in CO2 electrolysis technology in recent years, including highly selective catalysts, larger-scale reactors, specific process modeling, as well as a mechanistic understanding of the CO2 reduction reaction. The rapid advances in the field brings promise to the commercial application of the technology and the rapid rollout of the CO2 electroreduction for chemical manufacturing.This Account focuses on our contributions in both fundamental and applied research in the field of electrocatalytic CO2 and CO reduction reactions. We first discuss (1) the development of novel electrocatalysts for CO2/CO electroreduction to enhance the product selectivity and lower the energy consumption. Specifically, we synthesized nanoporous Ag and homogeneously mixed Cu-based bimetallic catalysts for the enhanced production of CO from CO2 and multicarbon products from CO, respectively. Then, we review our efforts in (2) the field of reactor engineering, including a dissolved CO2 H-type cell, vapor-fed CO2 three-compartment flow cell, and vapor-fed CO2 membrane electrode assembly, for enhancing reaction rates and scalability. Next, we describe (3) the investigation of reaction mechanisms using in situ and operando techniques, such as surface-enhanced vibrational spectroscopies and electrochemical mass spectroscopy. We revealed the participation of bicarbonate in CO2 electroreduction on Au using attenuated total-reflectance surface-enhanced infrared absorption spectroscopy, the presence of an "oxygenated" surface of Cu under CO electroreduction conditions using surface-enhanced Raman spectroscopy, and the origin of oxygen in acetaldehyde and other CO electroreduction products on Cu using flow electrolyzer mass spectrometry. Lastly, we examine (4) the commercial potential of the CO2 electrolysis technology, such as understanding pollutant effects in CO2 electroreduction and developing techno-economic analysis. Specifically, we discuss the effects of SO2 and NOx in CO2 electroreduction using Cu, Ag, and Sn catalysts. We also identify technical barriers that need to be overcome and offer our perspective on accelerating the commercial deployment of the CO2 electrolysis technology.

Young Chan Kim, N. Jeon, J. Noh et al.

B. Niemira

M. Flickinger, S. Drew

Bozell, L. Moens, D. et al.

J. Yun, J. Seidel, Jincheol Kim et al.

W. Bond, A. Grundy

J. Larminie, J. Lowry

Ncamisile Nondumiso Maseko, Dirk Enke, Pius Adewale Owolawi et al.

Viktoria Falkowski, Wilhelm Pfleging

Changing the topography of electrodes by ultrafast laser ablation has shown great potential in enhancing electrochemical performance in lithium-ion batteries. The generation of microstructured channels within the electrodes creates shorter pathways for lithium-ion diffusion and mitigates strain from volume expansion during electrochemical cycling. The topography modification enables faster charging, improved rate capability, and the potential to combine high-power and high-energy properties. In this study, we present a preliminary exploration of this approach for sodium-ion battery technology, focusing on the impact of laser-generated channels on hard carbon electrodes in sodium-metal half-cells. The performance was analyzed by employing different conditions, including different electrolytes, separators, and electrodes with varying compaction degrees. To identify key factors contributing to rate capability improvements, we conducted a comparative analysis of laser-structured and unstructured electrodes using methods including scanning electron microscopy, laser-induced breakdown spectroscopy, and electrochemical cycling. Despite being based on a limited sample size, the data reveal promising trends and serve as a basis for further optimization. Our findings suggest that laser structuring can enhance rate capability, particularly under conditions of limited electrolyte wetting or increased electrode density. This highlights the potential of laser structuring to optimize electrode design for next-generation sodium-ion batteries and other post-lithium technologies.

Diana Santacruz, Francis O Enane, Katrin Fundel-Clemens et al.

Jeong Han Lee, Min Ju O, Yong-Mook Kang et al.

Petroleum pitch (PP) is a by-product generated during the petroleum refining process, characterized by its high carbon content, tunable structure, and cost-effectiveness. These attributes have spurred extensive research into its potential as a carbon material. In this study, we prepared both untreated PP and oxidative stabilized PP (sPP) to explore the influence of pitch structural modifications on physical and electrochemical properties following carbonization and activation. Stabilizing the pitch above its softening point introduced oxygen functional groups on the surface, reaching levels of up to 19.6 at.%. These structural changes concurrently reduced aromaticity while increasing the coking value. Two types of activated carbons suitable for supercapacitors were derived from these distinct pitches, and their energy storage capacities were correlated with precursor pitch structural properties. The sPP-derived activated carbon exhibited a remarkable gravimetric specific capacitance of 39.6 F g−1, owing to its high specific surface area of 2508 m2 g−1. Conversely, PP-derived activated carbon exhibited a relatively lower specific surface area of 1122 m2 g−1. However, it demonstrated an increased electrode density and shallow ion intercalation within its graphitic structure, resulting in a notable volumetric capacitance of 26.0 F cc−1. This research not only sheds light on the electrochemical effects of pitch stabilization but also provides a foundation for the development of high-performance activated carbon materials through tailored modifications to the PP structure.

Rini Varghese, Anuradha Majumdar

Massive proteinuria, oedema, hypoalbuminemia, and hyperlipidemia are the hallmarks of nephrotic syndrome (NS). Recently, epigenetic pathways in renal diseases have been identified. The present work hypothesizes using the combination of two epigenetic drugs all-trans retinoic acid (ATRA) and valproic acid (VPA) as a prospective treatment method to lessen NS-related glomerulosclerosis, fibrosis, and increased renal function parameters along with attenuating inflammation and improving overall mitochondrial health. To induce NS, doxorubicin (8.5 mg/kg, n = 6) was injected intravenously into female Sprague Dawley rats. After 28 days, ATRA and VPA were orally administered to the rats, alone and in combination at a dose of 5 mg/kg (n = 6) and 200 mg/kg (n = 6) in sesame oil and saline, respectively. Prednisolone (3 mg/kg in saline; n = 6) was used as standard. Following 21-day treatment period, the rats were sacrificed prior to which 24 hrs urine samples were obtained. Blood samples were collected and kidneys were extracted for further analyses. Renal function parameters (proteinuria, BUN, albumin, creatinine), levels of tissue reengineering and fibrosis markers (TGF-β, MMP2 activity), cholesterol and triglyceride levels were significantly improved in the ATRA and VPA combination group as compared to positive control group. Histopathological analyses revealed a reduction in inflammation, glomerulosclerosis and fibrosis. The inflammatory markers, namely TNF-α, IL-1β, IL-6, NF-κB, determined by ELISA were downregulated. Mitochondrial biogenesis markers viz. PGC-1α, TFAM, NRF1, Nrf2, PPAR-γ, KEAP-1, analysed by RT-qPCR were upregulated thereby showing a significant improvement in the combination group as compared to positive control and standard group. The study overall contributes to a novel approach to treating NS and our findings will surely drive additional exploratory preclinical and clinical studies.