Developing high-performance materials for demanding applications requires predicting their behavior over a wide range of time scales. Rheology and DMA are powerful tools to understand and predict viscoelastic behavior, including how materials will respond to sudden forces or years of continuous use.
DetailsHeat shrink tubing appears simple at first glance: wrap it around your wires, apply a heat gun, and voila – perfectly insulated wires every time. But these tubes are more complex than they seem.
DetailsAs electronic devices grow more powerful and compact, thermal management has become a critical design challenge. Central to this challenge are Thermal Interface Materials (TIMs)—specialized materials engineered to enhance heat transfer between high-power electronic components and heat-dissipating surfaces.
DetailsPolymer rheology plays a critical role in understanding the flow behavior and viscoelastic properties of polymers across the supply chain. Whether in polymer manufacturing, compounding, conversion, or recycling, precise rheological measurements are essential for optimizing processing conditions, ensuring product quality, and preventing defects.
DetailsWill your paint stick to the wall or drip off? Does your low-fat cream cheese have the same texture as a full-fat version? How will new ingredients affect your formulation’s texture and application, especially as environmental conditions change? Rheology offers invaluable insights that help researchers, developers, and engineers across numerous industries optimize their products for performance and customer satisfaction.
DetailsMechanical testing supports material and product innovation across a variety of industries and applications, from testing the long-term durability of dental implants during chewing to predicting how a car part will bend during an accident. Learn how the latest technology advances mechanical testing to better support cutting-edge product development.
DetailsFrom faster prototyping to ensuring long-term performance, fatigue testing is a critical step in product development across a variety of industries that rely on high-performance materials, like polymers, rubber compounds, and composites. When done properly, fatigue testing accelerates development by helping engineers make informed decisions about prototypes and designs.
DetailsPolymers are everywhere, from components making up the electronic device you’re reading this on to life-saving medical devices, energy efficient solar panels, and lightweight aero or auto components. Material scientists and engineers continue to improve high-performance polymers for strength, durability, and stability under demanding applications.
DetailsIn the world of material science, understanding the viscoelastic properties of materials is crucial for developing and optimizing products. Two key parameters in this context are storage modulus (E’ or G’) and loss modulus (E” or G”). These parameters provide insights into a material’s stiffness and damping characteristics, respectively, which are essential for applications ranging from polymers and pharmaceuticals to batteries and composites.
DetailsDifferential Scanning Calorimetry is a thermal analysis technique commonly used to characterize materials across a broad array of applications including chemistry, biochemistry, pharmaceuticals, polymers, and more. Differential Scanning Calorimetry (DSC) measures the heat flow in a material as it is heated or cooled over a specified temperature range.
DetailsA testament to the march of scientific inquiry, thermogravimetry emerged through the integration of three individual inventions in the 19th and 20th centuries: the electric furnace, the thermocouple, and the microbalance. As a cornerstone of material science, chemistry, and various other industries, thermogravimetric analysis (TGA) has since developed in leaps and bounds. Today, TA Instruments are leading the way in TGA, and we welcome you to join us as we explore the workings and applications of this groundbreaking technique.
DetailsIf you’re working with materials that can be flowed, for example within pharmaceutical, food, cosmetics, or petrochemical industries, it’s likely that there is a viscometer in the laboratory that is the go-to instrument for formulation testing or QA purposes. However, does this viscometer give you the whole picture and fully meet all your needs?
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