Embracing Traditional Methods in Modern Research In the realm of scientific innovation, particularly in studies related to zeta potential in high salt/high conductivity environments, there’s a unique blend of old and new methodologies. This fusion is brilliantly showcased in a recent study conducted in collaboration with the University of Sheffield, set to be published in

Key Role of Electrode Materials in Zeta Potential Measurement Zeta potential is a crucial parameter in understanding the stability of colloidal systems, and its accurate measurement is especially challenging in high salt/high conductivity conditions where the choice of electrode material is often overlooked. This study focuses on how different materials – palladium (Pd), platinum (Pt),

In my comprehensive study on the electrokinetic properties of bovine serum albumin (BSA) in potassium chloride solutions, I focused on the intricate effects of high salt concentrations and pH levels, aiming to deepen the understanding of protein behavior in aqueous environments, with a particular emphasis on zeta potential, which is vital in the realms of

Introduction: In the realm of colloidal science, accurately determining the zeta potential of particles in various environments is essential. However, when these environments feature high conductivity, standard measurement techniques face significant challenges. This article delves into these challenges and explores the advanced methodologies developed to overcome them, focusing on sterically-stabilized particles in high ionic strength

There’s a plethora of misconceptions about measuring zeta potential in high conductivity/high salt concentration media. Some even doubt the existence of zeta potentials under these conditions. Let’s set the record straight with some facts: Zeta Potentials in High Salt Concentrations: A Reality Contrary to popular belief, significant zeta potentials can indeed exist at high salt

This video showcases the prototype of a Next Generation Electrophoretic Light Scattering instrument, proven to be capable of handling high conductivity samples with ionic strengths up to 6 molar, a range unachievable by commercial zeta potential instruments. I demonstrate its unique ability to perform electrophoretic light scattering using both a laser Doppler method and phase

As an innovator in the field of zeta potential measurement, I am proud to introduce my latest development, a method specifically designed to excel in high salt concentration/high conductivity environments. My invention seamlessly integrates laser Doppler electrophoresis with phase analysis light scattering, enabling me to analyze scattered light signals with unprecedented accuracy. Addressing the Challenges

Hello, I’m John Miller, owner of Enlighten Scientific, and I’m delighted to welcome you to our webinar focused on confidently measuring zeta potential. You might initially think about the technical steps like maintaining clean equipment and using filtered diluents. However, my approach today is broader, encompassing how these measurements impact business decisions. Our journey starts