The chemistry industry is working on new uses for polymers as well. In development are conductive polymers for printable electronics. Polymer Electrolyte Membrane, PEM, (or Proton Exchange Membrane) fuel cells are already in use in hydrogen fuel cell vehicles. The industry is also working on materials for advanced fuel cells including a polymer electrolyte fuel cell (PFC).
Yes, there are fluids known as electroactive polymers (EAPs) that can expand or contract when an electric current is applied. These polymers change shape in response to stimulation, making them useful in applications such as artificial muscles and sensors. They are being researched for applications in robotics, medical devices, and other fields.
Yes, polymers can be broadly categorized into natural and synthetic polymers. Synthetic polymers can further be classified based on their chemical structure and properties, such as thermoplastics, thermosets, elastomers, and fibers. These classifications help in understanding the different characteristics and applications of polymers.
Polymers have compounds that have repeating subunits. Polymers consist of long chains of monomers, which are repeated units that are linked together. This repeating structure gives polymers unique properties and versatility in various applications.
Nature polymers and synthetic polymers are both large molecules made up of repeating units called monomers. They both have high molecular weights and exhibit similar properties like flexibility, strength, and durability. Additionally, both nature and synthetic polymers can be engineered to have specific properties for various applications.
Polymers that are water-soluble, which means they dissolve in water. These polymers are often used to wrap products such as dishwasher tablets and pouches containing detergent for washing machines.
Charles G. Gebelein has written: 'Biotechnological Polymers: Medical Pharmaceutical and Industrial Applications' 'Biomedical Applications of Polymers (Review Reports)'
Applications of polymers include medicine, agribusiness, and agriculture. Consumer science, sports, and industry are other applications of polymers. Polymers applications range from electronic devices to optical devices.
Yes, there are fluids known as electroactive polymers (EAPs) that can expand or contract when an electric current is applied. These polymers change shape in response to stimulation, making them useful in applications such as artificial muscles and sensors. They are being researched for applications in robotics, medical devices, and other fields.
Polymers are important in everyday life because they are versatile and can be tailored to have specific properties like strength, flexibility, and durability. They are used in a wide range of applications such as packaging, clothing, electronics, and medical devices. Polymers also contribute to sustainability efforts by enabling lightweight materials that reduce energy consumption and emissions.
Different polymers have different physical and chemical properties. This makes some polymers more suitable for particular applications than others. As a result, no one polymer is suitable for all applications.
6-oxoheptanal has potential applications in organic chemistry as a building block for synthesizing various compounds, such as pharmaceuticals, fragrances, and polymers. It can be used in the development of new materials and in the study of chemical reactions.
Yes, polymers can be broadly categorized into natural and synthetic polymers. Synthetic polymers can further be classified based on their chemical structure and properties, such as thermoplastics, thermosets, elastomers, and fibers. These classifications help in understanding the different characteristics and applications of polymers.
Designer polymers are created through precise control of the chemical architecture of the polymer chain, allowing for specific properties such as mechanical strength, thermal stability, or flexibility. By manipulating the monomer structure, molecular weight, and branching, designers can tailor the polymer's properties to meet desired specifications. These polymers find applications in industries such as electronics, medical devices, and environmental engineering.
Thermosoftening polymers are used in a wide range of applications such as packaging materials, textiles, toys, and medical devices. They can be easily molded into different shapes when heated and can be recycled by melting and reshaping, making them versatile materials for various industries.
alkenes can be polymerized into polymers (plastics), or used as fuels.
One use - is in the medical field. Ultrasonic 'baths' are used to deep-clean medical devices, optics and dental products during manufacture.
With polymers you can do all kinds of things like they use polymers to make nylon and acrylic fabric they also use it for paint and bikes and car tires, some types of plastics, pipe restorations, DNA blueprints in our bodies, and protein and starches in the foods we eat.