Managing Water Sustainably

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Cold plasma technology, as a new and efficient nonthermal processing technology, has gained attention in the field of  water and inedible biomass revealed treatment and even food preservation. Cold plasma technology makes use of charged, highly reactive gas molecules at ambient temperatures to rapidly act on contaminated water by different microorganisms. It is also beneficial for the treatment of heat-sensitive products, sterilization of internally-packaged foods and beverages. Due to the high reactivity of active particles in plasma, they can interact with nearly all cellular components and play a significant role in water and food quality maintenance. 

The addition of atmospheric pressure nonequilibrium plasma to water is a multi-faced phenomena, related to the increased sterilization and improved washibility through removing pathogens from the cleaning surface. Cold plasma directly affect many water's physical and chemical properties, particularly the temperature dependent, including heat conductance, light absorption, and surface tension. These drastic changes associated with water gradually changing its mesoscopic structure: while at the higher temperatures water is a uniform media (amorphous state), at the temperatures below transition it consists of many nano-to-micro-scale clusters (crystalline state).  The water treatment with non-thermal plasma or adding plasma-created active compounds can significantly lower the temperature of the transition, causing a significant change in physical quantities as surface tension, viscosity, freezing rate, wettability, and washability. 

AviXéla embody and inspire change of nanoplasmonic technologies through developed cutting edge plasma jet devices, which can be implied in water analytical chemistry and sterilization, food preservation, and polymer solution treatment.  

AviXéla recognize the importance of sustainable water management to ensure our ongoing success and meet the needs of our customers. We are committed to responsible water use, focusing on conservation, efficient management, and minimizing our environmental impact. 

Our unique nanomaterials made over the HPLC ( High-Performance Liquid Chromatography) water due to the low conductivity, low total organic carbon, bacterial and particle contamination free to ensure the accuracy, reliability, and efficiency of their production processes.  Its purity and quality directly impact the accuracy and reliability of our products analytical and chemico-physical properties. 

Nanophotonics, the study of light-matter interactions at nanoscale, is emerging a powerful tool for optimising water quality and purification. By harnessing the unique properties of nanomaterials, we enable to develop innovative solutions to address growing pressing water quality challenges, as pollution and scarcity. AviXéla's unique nanoproducts can be used in plasmonic sensors due to their Surface Plasmon Resonance (SPR), Localized Surface Plasmon Resonance (LSPR),  Plasmonic Photocatalysis,  Solar-Driven Water Distillation, Antimicrobial coating, and other properties.   

These sensors leverage the unique optical properties of nanomaterials to detect minute changes in the surrounding environment. The key techniques in plasmonic sensing include SPR, LSPR, and surface-enhanced spectroscopy. Nanomaterials, including gold and silver nanoparticles, graphene, and quantum dots, play a crucial role in enhancing the performance of nanophotonic devices by modifying their optical properties, enhancing signal amplification; and providing functionalization sites.

Plasmonic sensing leverages the interaction of light with metallic nanostructures and enables to detect various label-free  biomolecules in a timely manner. This technology has revolutionized fields like biomedicine, environmental monitoring, and food safety. AviXéla plasmonic devices and unique inorganic nanomaterials can significantly enhance the water quality. By combining nanotechnology with advanced optic,technologies  our team is pushing the boundaries of sensitivity, selectivity, and real-time monitoring capabilities.