WHAT IS ATR-SEIRAS?
WHAT IS SPECTROELECTROCHEMISTRY?
Electrochemists use applied electrical potentials and currents to control and study chemical processes on or near electrodes. Spectroscopy is the gather of information about the structure of matter by studying how it interacts with light. Spectroelectrochemistry uses spectroscopic tools to tease out details of electrochemical processes.
Infrared spectroelectrochemistry is a non-destructive technique which is highly sensitive to molecular structure.
ATR-SEIRAS ENHANCES SURFACE SIGNALS
ATR-SEIRAS stands for attenuated total reflectance surface-enhanced infrared absorption spectroscopy. It is a surface-sensitive technique similar to surface-enhanced Raman spectroscopy (SERS).
ATR-SEIRAS uses a silicon prism with one surface coated with a thin (~ 30 nm) gold film. Infrared light passes through the prism and is totally internally reflected at the Au/air interface. At the interface, the evanescent wave excites surface plasmon polaritons at the Au/air interface.
The increased electric field is confined to the interface, so absorption probabilities of surface molecules increase by an order of magnitude or more!
Wondering what the difference is between external and internal reflection techniques for infrared spectroelectrochemistry? Read on for a short introduction and to learn why ATR-SEIRAS is our technique of choice for surface-sensitive measurements.
Studying the molecular composition of the boundary between two materials, such as an electrode|electrolyte interface, is an inherently challenging problem due to the relatively small numbers of molecules at a surface compared to those in a bulk phase. Mechanisms that preferentially increase surface molecule sensitivity are highly desirable for such studies and there are two limiting approaches for surface enhanced infrared spectroelectrochemistry.
EXTERNAL REFLECTION
External reflection geometry. Infrared radiation is transmitted through a crystal and reflects off an electrode which is pushed close to the crystal.
In external reflection techniques, a highly polished metal electrode is pushed close to a suitably IR-transparent crystal forming a thin (ca. 10 µm) pocket of electrolyte. IR light transmitted through the crystal, reflects from the metal surface and is sent to the detector.
In external reflection, the electric field distribution is easily quantified as a function of angle of incidence and gap thickness between the crystal and electrode. Overall surface enhancement is very low.
Upon reflection at the metal-solution interface, the electric field of p-polarized light undergoes a 180° phase shift whereas s-polarized light does not. Thus, at the interface, a theoretical enhancement factor, (E/Eo)2= 4, can be generated for p-polarized light (see Figure below). The contribution of solution based species to the measured p-polarized absorbance can be removed by subtracting the equivalent measurement made with s-polarized light. External reflection methods are often performed with either static wire grid polarizers (SNIFTIRS : subtractively normalized interfacial Fourier Transform Infrared Spectroscopy) or rapidly electromodulated crystals (PM-IRRAS : polarization modulation infrared reflection absorption spectroscopy).
Advantages
- electric field distribution at the interface can be accurately calculated
- quantitative information on surface concentrations and molecular orientation can be extracted
Disadvantages
- low surface enhancement factor (up to 4)
- infrared light has to pass through the highly absorbing electrolyte solution
INTERNAL REFLECTION
ATR-SEIRAS (attenuated total reflection surface enhanced infrared absorption spectroscopy) in an internal reflection technique that overcomes the problems associated with solvent absorption. In ATR-SEIRAS a high refractive index internal reflection element (IRE) such as ZnSe, Ge or Si is modified by a thin film of nano-textured metal. As is the case in ATR, an evansecent wave is generated at angles above the crtical angle and this evansecent wave is coupled into localized plasmon polariton modes of the metallic film.
ATR-SEIRAS, an external reflection, overcomes the strong IR absorption of the electrolyte by exploiting total internal reflection of IR radiation off a plasmonic metal film. ATR-SEIRAS can generate enhancement factors of up to 100x.
In simplistic terms, ATR-SEIRAS is analogous to its vibrational cousin SERS although it is important to note that surface enhancement in ATR-SEIRAS can be generated at almost all metals (see forthcoming note on the ATR-SEIRAS mechanism). Unlike external reflection methods, the enhancement is highly localized to the very surface of the metal and, as a good rule of thumb, the electric field enhancement drops off very rapidly beyond distances greater than 5-10 nm from the metal surface.
Advantages
- High surface enhancement factors (up to 100)
- Excellent surface sensitivity
- Not limited to plasmonic metals
Disadvantages
- Surface enhancement factors are hard to quantify
- Metal film preparation can be difficult