Multi-purpose Spectro-efc 1.75 Ml - Spectro-electrochemical Flow Cell Economy Pack [9FJUzovT]

Multi-purpose Spectro-efc 1.75 Ml - Spectro-electrochemical Flow Cell Economy Pack [9FJUzovT]

The Spectro-EFC 1.75 mL is a versatile and robust spectroelectrochemical cell designed for precise analysis in various scientific research applications. This horizontally mounted cell is compatible with standard UV-Vis or IR spectrometers, allowing for comprehensive electrochemical and spectroscopic data acquisition from liquid samples or thin films. Its multi-purpose design makes it an essential tool for researchers seeking to understand the complex interplay between electrochemical potential and observed spectra.

Key Features and Specifications

The Spectro-EFC 1.75 mL is constructed with a durable polyether ether ketone (PEEK) flow chamber, ensuring long-lasting performance and ease of use. It comes equipped with a magnetic or screw mount sample holder, a screw mount quartz window holder, and two mini tripods for flexibility in setup. The cell is well-suited for both aqueous and organic solvent-based electrolytes, thanks to its compatibility with FKM and FFKM O-Rings. Key specifications include a nominal exposure area of 1 cm², an optical path length of 12 mm, and a flow chamber volume of 1.75 mL. The maximum substrate thickness it can accommodate is 4 mm, making it suitable for a wide range of materials and applications.

Applications and Benefits

The Spectro-EFC 1.75 mL is an invaluable tool for studying the relationship between absorbance/transmittance and electrochemical potential. Its real-time monitoring capabilities make it ideal for investigating electrochromic materials and capturing the optical changes that occur during electrochemical reactions. Additionally, the cell's in-situ spectral acquisition feature allows for the detection, identification, and characterization of short-lived electrochemically-generated species/intermediates, providing a detailed investigation of the mechanistic pathways of redox processes. This level of detail and insight is crucial for advancing research in fields such as electrochemistry, materials science, and environmental studies.