Operando spectroscopy

Operando spectroscopy is an analytical methodology wherein the spectroscopic characterization of materials undergoing reaction is coupled simultaneously with measurement of catalytic activity and selectivity. The primary concern of this methodology is to establish structure-reactivity/selectivity relationships of catalysts and thereby yield information about mechanisms. Other uses include those in engineering improvements to existing catalytic materials and processes and in developing new ones. In the context of organometallic catalysis, an in situ reaction involves the real-time measurement of a catalytic process using techniques such as mass spectrometry, NMR, infrared spectroscopy, and gas chromatography to help gain insight into functionality of the catalyst. Approximately 90% of industrial precursor chemicals are synthesized using catalysts. Understanding the catalytic mechanism and active site is crucial to creating catalysts with optimal efficiency and maximal product yield. In situ reactor cell designs typically are incapable of pressure and temperature consistency required for true catalytic reaction studies, making these cells insufficient. Several spectroscopic techniques require liquid helium temperatures, making them inappropriate for real-world studies of catalytic processes. Therefore, the operando reaction method must involve in situ spectroscopic measurement techniques, but under true catalytic kinetic conditions. Operando (Latin for working) spectroscopy refers to continuous spectra collection of a working catalyst, allowing for simultaneous evaluation of both structure and activity/selectivity of the catalyst. The term operando first appeared in catalytic literature in 2002. It was coined by Miguel A. Bañares, who sought to name the methodology in a way that captured the idea of observing a functional material — in this case a catalyst — under actual working, i.e. device operation, conditions.