TY - JOUR A1 - Kutlug, Oezgür A1 - Hass, Roland A1 - Reck, Stephan A1 - Hartwig, Andreas T1 - Inline characterization of dispersion formation of a solvent-borne acrylic copolymer by Photon Density Wave spectroscopy JF - Colloids and surfaces : an international journal devoted to the principles and applications of colloid and interface science ; A, Physicochemical and engineering aspects N2 - Most investigations on phase inversion (PI) of resins upon addition of water have been carried out by dynamic light scattering (DLS), torque, and viscosity measurements. The main problem, however, is analytic discontinuity due to sample removal and a changing matrix due to dilution during the preparation of the aqueous resin dispersions. This work presents Photon Density Wave (PDW) spectroscopy as a tool for the inline characterization of the acetone process for an acrylic copolymer with high acrylic acid (AA) content. PDW spectroscopy revealed different trends for optical properties compared to torque during water feed. Also the absence of PI due to dissolution of copolymer in the solvent/water mixture is observed by PDW spectroscopy. PI for the investigated copolymer did not occour during water feed but during removal of solvent. Different feeding rates of water gave similar trends while a change in temperature and degree of AA neutralization led to changes in optical properties and torque. Thermal processing showed that the optical properties of mixtures prior and after removal of solvent were completely different caused by changes of solubility. KW - Acetone process KW - Dispersion KW - Photon Density Wave spectroscopy KW - Radical polymerization KW - Torque KW - Turbid media Y1 - 2018 U6 - https://doi.org/10.1016/j.colsurfa.2018.08.011 SN - 0927-7757 SN - 1873-4359 VL - 556 SP - 113 EP - 119 PB - Elsevier CY - Amsterdam ER - TY - JOUR A1 - Hass, Roland A1 - Munzke, Dorit A1 - Ruiz, Salome Vargas A1 - Tippmann, Johannes A1 - Reich, Oliver T1 - Optical monitoring of chemical processes in turbid biogenic liquid dispersions by Photon Density Wave spectroscopy JF - Analytical & bioanalytical chemistry N2 - In turbid biogenic liquid material, like blood or milk, quantitative optical analysis is often strongly hindered by multiple light scattering resulting from cells, particles, or droplets. Here, optical attenuation is caused by losses due to absorption as well as scattering of light. Fiber-based Photon Density Wave (PDW) spectroscopy is a very promising method for the precise measurement of the optical properties of such materials. They are expressed as absorption and reduced scattering coefficients (mu (a) and mu (s)', respectively) and are linked to the chemical composition and physical properties of the sample. As a process analytical technology, PDW spectroscopy can sense chemical and/or physical processes within such turbid biogenic liquids, providing new scientific insight and process understanding. Here, for the first time, several bioprocesses are analyzed by PDW spectroscopy and the resulting optical coefficients are discussed with respect to established mechanistic models of the chosen processes. As model systems, enzymatic casein coagulation in milk, temperature-induced starch hydrolysis in beer mash, and oxy- as well as deoxygenation of human donor blood were investigated by PDW spectroscopy. The findings indicate that also for very complex biomaterials (i.e., not well-defined model materials like monodisperse polymer dispersions), obtained optical coefficients allow for the assessment of a structure/process relationship and thus for a new analytical access to biogenic liquid material. This is of special relevance as PDW spectroscopy data are obtained without any dilution or calibration, as often found in conventional spectroscopic approaches. KW - Photon Density Wave spectroscopy KW - Enzymatic milk coagulation KW - Beer mashing KW - Human donor blood KW - Process analytical technology KW - Light scattering Y1 - 2015 U6 - https://doi.org/10.1007/s00216-015-8513-9 SN - 1618-2642 SN - 1618-2650 VL - 407 IS - 10 SP - 2791 EP - 2802 PB - Springer CY - Heidelberg ER -