28 CHROMATOGRAPHY


Left: The SEC-NMR system from Professor Manfred Wilhelm’s development team from Karlsruhe Institute of Technology


REFERENCES 1


Development of a chemically sensitive online SEC detector based on FTIR spectroscopy, Timo F Beskers, Thorsten Hofe and Manfred Wilhelm, Polym. Chem., 2015, 6, 128, DOI: 10.1039/c4py01043d


2


NMR-SEC COMBINATION SUCCESS


The Polymeric Materials Group at Karlsruhe Institute of Technology used an innovative benchtop NMR system to develop new chemical detectors for size-exclusion chromatography


M


anfred Wilhelm is professor and chair of the polymeric materials group at the Institute for Chemical


Technology & Polymer Chemistry at the Karlsruhe Institute of Technology. His research is driven by the desire to understand the mechanical and rheological properties of polymers to better enable their processing and application. One key goal is to gain a better understanding of the polymer’s molecular structure as this goes hand-in- hand with its mechanical properties. T is in turn has led to developing a better means of online chemical detection and identifi cation of monomers at resolutions previously not available. Earlier work from Professor Wilhelm focused on how to improve the detectors used in size exclusion chromatography (SEC) to characterise polymers. T e traditional detection methods included UV, RI, viscosity and light scattering but these did not provide suffi cient information on the eluting polymers.


www.scientistlive.com


His fi rst area of success employed the use of FT-IR. Published in Polymer Chemistry in 20151


, the group reported on


the development of a chemically sensitive online SEC detector based on FTIR spectroscopy. While being quite successful, it lacked the ability to quantify the relative concentration without external calibration. So, with a PhD background in solid state NMR, Professor Wilhelm sought to push the barriers further to provide users with an easy-to-use technique that delivered results at lower levels of concentration. T e arrival of low cost, low maintenance benchtop NMR systems proved to be the basis for his work. T is culminated in the use of a cryo-free Magritek 60MHz benchtop 1H-NMR spectrometer as a new and powerful detector for SEC. T e NMR was required to be very responsive (measurements in less than two minutes) and to not require the use of deuterated solvents, now possible thanks to the use of pulse


Medium Resolution 1H-NMR at 62 MHz as a New Chemically Sensitive Online Detector for Size-Exclusion Chromatography (SEC NMR), Johannes Höpfner, Karl-Friedrich Ratzsch, Carlo Botha, and Manfred Wilhelm, Macromol. Rapid Commun. 2018, 1700766, DOI: 10.1002/ marc.201700766


sequences that provide effi cient solvent suppression. According to Professor Wilhelm, key to the success of the Magritek system was its excellent signal to noise ratio coupled to superior shim and line width performance. Recently published in Macromolecular Rapid Communications2


, Wilhelm and


his colleagues demonstrated excellent performance on standard polymers such as polystyrene and PMMA. T e NMR spectra provided chemical assignment with absolute integration and may be fully quantitative. T e results have demonstrated an impressive improvement in all key parameters thereby strongly increasing the usefulness of this method.


Further opportunities While going on to demonstrate the new online detection method on more real- world polymer mixes, Professor Wilhelm still sees more development opportunities for the NMR-SEC combination. He believes a further 10x improvement in signal to noise will be possible. He envisages making changes to the chromatography columns while on the NMR front, making use of the new 80MHz benchtop system with further improvements to pulse sequences and improving the design of the fl ow cell. In all, these will meet the needs of both the NMR spectroscopist and the polymer scientist, providing rapid and highly sensitive detection ability.


For more information visit www.magritek.com.


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