Monitoring metal ion separations in real time is essential for optimizing ion exchange column–based processes in diverse fields, including water treatment, chemical and pharmaceutical processing, nuclear fuel reprocessing, isotope production, and environmental remediation. (1−8) Ion exchange chromatography systems separate and purify ions from complex mixtures and often involve dynamic speciation, complexation equilibria, and resin interactions that evolve under flowing conditions. Traditional monitoring approaches typically rely on effluent sampling or transmission-mode spectroscopy, which can obscure spatial gradients, delay the detection of breakthrough events, and fail to capture transient species or localized saturation effects. (9) As a result, there is a growing need for noninvasive, spatially resolved techniques that can probe chemical changes directly within the column. (10,11)

Anion exchange columns are widely used for purifying Pu and rely on the speciation behavior of Pu(IV) in HNO₃. (12,13) In dilute HNO₃, Pu(IV) predominantly exists as an aquo complex, but as the acid concentration increases, nitrate ligands increasingly coordinate with the Pu(IV) center to form various nitrato complexes. In concentrated HNO₃, Pu(IV) forms complexes with nitrate ions to yield anionic species such as Pu(NO₃)62–, which interact strongly with the positively charged sites on the resin and allow Pu to be retained while other noncomplexed or positively charged contaminants pass through. (14) The sorbed Pu can subsequently be eluted in dilute HNO₃, effectively separating the Pu from fission products and other actinides such as U(VI). (9,15) The efficacy of these anion exchange columns to purify Pu depends on maintaining the proper acid conditions. Techniques such as UV–vis–NIR absorption spectroscopy, which is often combined with multivariate analysis, can detect electronic transitions associated with different Pu(IV) species to provide insights into their relative populations and monitor Pu in process analytical applications. (16−20)

To better understand Pu(IV) speciation on an anion exchange column and improve in situ monitoring capabilities, we introduce a fiber-optic UV–vis–NIR reflectance spectroscopic method that enables direct, in situ measurements on a glass column during Pu(IV) loading and elution. This approach integrates spectroscopic monitoring directly into the column environment to provide continuous insight into chemical changes as they occur. Reflectance spectroscopy measures a material’s absorption properties from the light reflected off its surface; thus, this technique offers a noninvasive method to probe the column interior without disrupting the separation process. (20−23)

In this article, we demonstrate the ability to monitor an ion exchange column directly with a reflection probe and identify unique Pu(IV) species on the resin before elution. The absorption spectra acquired on the anion exchange column are compared with solution analogs over a range of HNO₃ concentrations from 0.5 to 13 M...

Figure 1. Images of the reflection probe location and column at various stages: (left) Pu load in 7 M HNO3, (middle) initial switch to 0.5 M HNO3, and (right) elution with 0.5 M HNO3.

Figure 3. UV–vis–NIR reflectance spectra of Pu(IV) (a) during the loading of Pu(IV) in 7 M HNO3 and (b) during the 0.5 M HNO3 elution. The color palette starts with black and moves toward orange.

This article describes a novel application of UV–vis–NIR reflectance spectroscopy for direct, in situ monitoring of metal ions on a glass column using a fiber-optic probe. By capturing spatially resolved spectra during dynamic loading and elution, the method enables real-time observation of Pu(IV) speciation transitions, including the shift from nitrato complexes to free ionic forms. PCA provides a robust framework for extracting relative concentration profiles and differentiating spectral features without requiring precise knowledge of penetration depth or species identity. This approach provides a practical solution for characterizing metal–resin interactions and tracking ion migration behavior under dynamic conditions.

The ability to probe chemical changes directly on a glass column surface offers significant advantages over traditional effluent-based flow cell approaches. In situ spectral data reveal spatial gradients, resin saturation behavior, and breakthrough dynamics. The fiber-compatible design supports deployment in remote systems, making it well-suited for challenging environments such as radiochemical separations and nuclear process monitoring. In dynamic systems in which the scores trajectory follows a consistent pattern through processing conditions, deviations from the expected trajectory could be used as early indicators of process shifts, making the method useful for real-time monitoring and prediction...