Quality Control of Advanced Materials with Thermal Analysis
As the market for advanced materials continues to grow, thermal analysis becomes increasingly critical for efficient, reliable quality assurance of innovative materials.
4 Characteristics of Real High-Force DMA and Why They Matter
While many instruments can measure DMA type properties (phase, tan delta, etc), many are not performing ‘real’ DMA experiments. On the surface, Dynamic Mechanical Analysis seems straightforward: apply periodic stress/strain and measure the sample’s mechanical response including the phase relationship, revealing characteristics like stiffness (storage modulus) and damping (loss modulus).
Streamline Battery Slurry Quality Control with Rheology
In battery manufacturing, quality starts with the slurry. For QA/QC professionals, ensuring the consistency and performance of electrode slurries is not just a checkpoint — it’s a quality control imperative. Slurry quality directly impacts electrode uniformity, adhesion, and ultimately, battery performance and lifespan.
How to Accelerate Product Development with Easy, Reliable Advanced Mechanical Testing
Mechanical 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.
The Importance of Fatigue Testing: Prevent Product Failures Early
From 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.
Linear Viscoelastic Region: Why It’s Crucial in Materials Testing
Our world is brimming with viscoelastic materials: The dough you knead before baking a fresh loaf, the Silly Putty your toddler slaps against the wall, the rubber gaskets that create an airtight seal on an airplane door. Testing those materials by applying controlled deformations (strains) or forces (stresses) at various timescales, temperatures, and/or humidities allows for the optimization of properties and ensures durability and safety.
Optimization of Catalytic Reactions by High-Pressure TGA
Catalytic reactions are everywhere: from plastics and bread to over 90% of all chemicals worldwide, countless goods and materials are manufactured with the aid of catalysts.1 Catalysts are substances that speed up sluggish chemical reactions. Faster reactions are more technologically and economically competitive. Furthermore, optimized catalysts offer a huge potential to reduce energy and resource consumption and lower carbon dioxide emissions.