Transmission Electron Microscopy Liquid Electrochemical In Situ SystemBeing able to observe in real-time the electrochemical reactions, structural changes, and dynamic processes of materials in liquid environments at the atomic scale.

Transmission Electron Microscopy Liquid Electrochemical In Situ SystemApplication areas:

Research on Energy Materials:

Lithium ion batteries: Observing the deposition/dissolution process of lithium metal, revealing the mechanism of dendrite growth, and guiding the design of solid-state electrolytes.

Lithium sulfur batteries: Study the conversion pathway of lithium polysulfides, discover new mechanisms of charge storage aggregation reactions, and provide theoretical basis for the design of next-generation batteries.

Fuel cell: Analyze the surface reaction process of the catalyst, optimize the catalyst structure to improve catalytic efficiency.

Electrochemical catalysis:

Study the intermediates and reaction pathways of electrocatalytic reactions such as CO ₂ reduction, hydrogen evolution reaction (HER), and oxygen evolution reaction (OER).

Reveal the dynamic evolution process of active sites on the surface of catalysts and guide the rational design of efficient catalysts.

Corrosion and Protection:

Observe the corrosion behavior of metals in corrosive media and analyze the mechanism of corrosion product formation.

Study the mechanism of action of corrosion inhibitors and provide experimental basis for the development of anti-corrosion coatings.

Bioelectrochemistry:

Study the structural changes and functional regulation of biomolecules (such as proteins and DNA) under the action of electric fields.