BeNano 180 Zeta Max

In this application note, Bettersize Instruments evaluated various micron-sized samples using the sedimentation method of the BeNano 180 Zeta Max. The results were then compared to size measurements conducted using the laser diffraction (LD) method of the Bettersizer 2600.

In this application note, Bettersize Instruments presents the characterization of silica polishing slurry in terms of particle size and concentration using the BeNano 180 Zeta Max.

In this application note collection, Bettersize Instruments focuses on key production processes of powder coating and explore how these processes affect the size and shape of powder particles and eventually the final product performance.

This guide from Bettersize Instruments highlights practical considerations for carrying out measurements, while briefly introducing the theory behind the measurements and illustrating typical applications with specific examples. The purpose of this guide is to equip readers, even those who are new to light scattering measurements, with the necessary understanding to meet measurement requirements, and to develop measurement solutions to reach the best practice in the characterization of nanoparticles.

In this application note from Bettersize Instruments, explore different light scattering techniques for biomaterials such as dynamic light scattering, electrophoretic light scattering, and static light scattering.

Dynamic light scattering microrheology (DLS microrheology) is a technique that uses dynamic light scattering to measure the mean square displacements (MSD) of added inert tracer particles in a solution environment and further obtain the rheological information of solutions. In this application note from Bettersize Instruments, explore how the DLS microrheology can be used to characterize weakly structured polymer and protein solutions, and also gel systems, in which tracer particles can diffuse over significant distances.

In this application note from Bettersize Instruments, explore how in recent years, the rapid development of the new energy industry has highlighted the significant role of lithium batteries as reusable and rechargeable batteries in various industrial applications. During the production process of lithium batteries, electrode slurry is formulated using n-methylpyrrolidone (NMP) as a dispersant. NMP serves as a solvent for polyvinylidene fluoride (PVDF) during the slurry batching stage, aiding in the dispersion of the slurry to create a more uniform system. In addition, NMP acts as the primary carrier of the slurry during the coating stage, ensuring even coating on the substrate. Furthermore, during the coating and baking stages, NMP volatilizes and creates pores in the coating, resulting in a uniformly distributed porous microelectrode structure.

In this application note from Bettersize Instruments, discover how a challenge was undertaken using the BeNano nanoparticle size analyzer from Bettersize to measure glucose, a sample with even lower molecular weight. Glucose has a smaller molecular size compared to sucrose and vitamin B1, with a molecular weight of only 180.16 Da, and its scattering ability is lower compared to sucrose samples, making the measurement even more demanding.

Alumina (Al2O3) can be widely used as wear-resistant material, refractory material, polishing material, thermally conductive material, and other materials due to its excellent mechanical strength, hardness, thermal conductivity, high resistivity, and high melting point. In this application note from Bettersize Instruments, explore how the zeta potentials of Al 2O3 at different pH were characterized by the BAT-1 autotitrator and BeNano analyzer.

The zeta potential of materials depends strongly on the dispersion medium, especially the solution pH, which not only affects the magnitude of zeta potential, but also the symbol of charged particle systems. In this application note from Bettersize Instruments, explore how the BAT-1 Autotitrator is equipped with three high-precision titration pumps (with precision of 0.28 μL), and a magnetic stirrer, and is in combination with the BeNano series nanoparticle size and zeta potential analyzer for automatic acid-base titration and determination of isoelectric point (IEP). The pinch valve can close the circuit of the sample during the measurement, leading to high efficiency, accurate titration, good repeatability and the results being independent of operators. The disposable sample container can avoid the sample cross-contamination.

Explore BetterSize Instruments' new nanoparticle analyzer, the BeNano 180 Zeta Max. Discover how it enhances measurement capabilities with advanced techniques for particle size, refractive index, and concentration. It can effectively measure various sample sizes using sedimentation technology, overcoming challenges posed by aggregates.

Learn how to use BeNano 180 Zeta max, a nanoparticle analyzer from BetterSize Instruments that combines light scattering and transmission techniques. Including sample preparation, concentration measurement and refractive index measurement, this video tutorial gives you the practical knowledge needed to ensure reliable, high-quality nanoparticle analysis.

Accurate particle size measurements depend on the refractive index of the dispersion medium, zeta potential, and molecular weight. Discover how BeNano 180 Zeta Max's patented technology uses a wedge-shaped sample cell for precise refractive index detection with minimal error. It analyzes particle size, distribution, and concentration through advanced techniques, providing high-resolution results.