Learn how corrosion works as an electrochemical cell with an anode, cathode, electrolyte, and metallic path. Discover how to prevent metal degradation.
Learn how an H-type electrolytic cell uses an ion-exchange membrane to separate anode and cathode reactions, enabling precise control and high-purity synthesis.
Learn the 4 critical factors for electrolyte selection: ionic conductivity, stability window, solubility, and chemical compatibility. Ensure accurate electrochemical data.
Discover why high borosilicate glass is the standard material for electrolysis cell bodies, offering chemical inertness, thermal stability, and full visibility.
Learn how regenerated carbon is professionally cleaned and restored for reuse, offering a sustainable and cost-effective alternative to virgin carbon for filtration.
Learn how the activated carbon method uses adsorption to remove contaminants from air and water. Understand its mechanisms, applications, and limitations.
Discover the key applications of gold electrodes, from high-performance biosensors to reliable electrochemistry research, enabled by their unique properties.
Explore the dual effects of carbon nanotubes on plants: boosting growth at low doses or causing toxicity at high concentrations. Learn the key factors.
Carbon nanotube inhalation is toxic when fibers are long, rigid, and durable, mimicking asbestos by causing lung inflammation and disease. Learn the key risk factors.
Discover how carbon nanotubes conduct electricity through their unique chirality and sp² hybridization. Learn why some are metallic while others are semiconducting.
Discover why carbon nanotubes are crucial for enhancing lithium-ion batteries, advanced composites, and next-gen electronics with superior conductivity and strength.
Discover how carbon nanotubes replace carbon black and other additives for better conductivity, strength, and sustainability in batteries and composites.
Explore carbon nanotube capacities: from 10⁹ A/cm² current density to 100 GPa tensile strength. Learn how to apply CNTs in energy storage, electronics, and composites.
Compare dual-chamber vs. single-chamber bio-electrochemical cells. Discover how isolation membranes improve electrode characterization and data purity.
Learn essential precautions for connecting a platinum disk electrode, including electrical safety, surface purity, and handling to protect your instrument and data.
Learn how to extend your platinum electrode's lifespan. Key factors include chemical contamination, physical wear, and a strict cleaning & storage protocol.
Learn essential precautions for metal disk electrodes: prevent physical damage, ensure chemical compatibility, and follow electrical safety protocols for reliable results.
Learn the critical steps for handling a metal disk electrode, from secure installation and immersion control to managing environmental conditions for reliable data.
Explore the key specs of Ir-Ta-Ti OER electrodes: precious metal loading, current density, oxygen potential, and their impact on efficiency and durability.
Learn the critical precaution for using gold or platinum electrodes: selecting a non-reactive electrolyte to prevent corrosion and ensure experimental accuracy.
Learn the standard pre-use cleaning protocol for platinum electrodes to remove oxides and contaminants for accurate, reproducible electrochemical measurements.
Explore the key performance traits of platinum electrodes: chemical inertness, high conductivity, and catalytic activity for reliable electrochemical results.
Learn the standard sizes for Pt wire (0.5x37mm, 1x37mm) and rod (1x5mm, 1x10mm) electrodes, plus how to choose based on surface area, current density, and application.
Learn the critical steps for operating a platinum mesh electrode, from correct immersion and connection to managing current density for reliable results.
Learn key precautions for thin-layer spectroelectrochemical cells, including polarity checks, contamination prevention, and safe handling to ensure reliable data.