In‐line monitoring of hydrogen peroxide in two‐phase reactions using raman spectroscopy

Ebrahimi, Fatemeh; Viell, Jörn; Mitsos, Alexander; Mhamdi, Adel; Brandhorst, Markus

doi:10.1002/aic.15754

Cited by 7 publications

(5 citation statements)

References 31 publications

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“…Therefore, the results demonstrated that the 633 nm laser line is the optimal excitation wavelength for SERS measurements and quantitative analysis. Among them, the peak at 876 cm −1 during the GPx4-like catalytic cycle of EGCG was assigned to O − O from H 2 O 2 was observed once H 2 O 2 was added compared to other spectra, which was similar to previous studies ( Ebrahimi, Viell, Mitsos, Mhamdi, & Brandhorst, 2017 ; Ghosh, Prasad, & Mugesh, 2019 ; Molinari & Wachs, 2010 ). During the GPx-like catalytic cycle of EGCG was measured by in-situ SERS spectrum (ranging from 400 to 1800 cm −1 ) and SERS bands were observed at 443, 762, 806, 876, 914, 1178, 1370, and 1620 cm −1 ( Fig.…”

Section: Resultssupporting

confidence: 87%

Se site targeted-two circles antioxidant in GPx4–like catalytic peroxide degradation by polyphenols (−)-epigallocatechin gallate and genistein using SERS

Zhang,

Liu,

Gao

et al. 2024

Food Chemistry: X

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Section: Resultssupporting

confidence: 87%

Se site targeted-two circles antioxidant in GPx4–like catalytic peroxide degradation by polyphenols (−)-epigallocatechin gallate and genistein using SERS

Zhang,

Liu,

Gao

et al. 2024

Food Chemistry: X

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“…4 In addition, owing to its powerful capability of providing rich information on molecular structure and chemical composition without destruction and preparation of the sample, in-line Raman spectroscopy has been adopted to obtain real-time information in a number of industries such as pharmaceutical, [5][6][7] bioengineering, 8,9 and chemical. 10,11 In polymer fields, the Raman spectroscopy technique has been reported for on-line measurement of crystallinity, [12][13][14] for monitoring polymerization reactions, 15,16 for on-line measurement of polyethylene pellet density, 17 etc. However, due to the harsh environment of the polymer blending processing line and the influence of fluctuating fluorescence background, using in-line Raman spectroscopy to analyze the dispersion uniformity of polymer blends, which is a relatively novel and less studied field, remains to be further explored and developed.…”

Section: Introductionmentioning

confidence: 99%

Application of Raman Spectroscopy for In-Line Measurement of Dispersion Uniformity of Polypropylene–Polystyrene Blends During Melt Extrusion

et al. 2018

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At present, there is a widespread phenomenon that product quality is difficult to monitor during the process of polymer melt modification such as blending, filling, and reinforcement. In consideration of this problem, this paper proposes an in-line Raman spectroscopy technique for measuring dispersion uniformity of polystyrene (PS) in polypropylene (PP)/PS blends during melt extrusion. On the basis of the optimal partial least squares (PLS) calibration model for quantitative determination of PS content in PP/PS, the fluctuations of PS content in extruding PP/PS with a mass percentage of 70 : 30 at different screw rotation speeds were predicted. The coefficient of variation (CV) of PS content at each screw rotation speed was obtained to accurately compare the dispersion uniformity, which was in agreement with the PS dispersion result characterized by the scanning electron microscope (SEM). In addition, the sensitivity of the measurement was validated by calculating the CV of PP/PS with mass percentages of 69 : 31 and 71 : 29. All of the above demonstrated that the in-line measurement system of Raman spectroscopy was able to accurately measure the dispersion uniformity of PS during the blending extrusion of PP/PS and demonstrated good sensitivity to minor changes in the blends composition.

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“…Details on the construction of both spectral mixture hard models together with further information on the theoretical concept of spectral complemental hard modeling and spectral indirect hard modeling are provided in the Supporting Information. The advantages of spectral indirect hard modeling over other multivariate chemometric models, such as often-used partial least squares regression, are the physically meaningful deconvolution of highly overlapping peaks in the spectra of multicomponent mixtures, the compensation of nonlinear effects such as peak shifts or peak deformations due to the interaction of chemical species, the robustness against noise, , a reduced demand of calibration samples, , and the improved range of extrapolation, e.g., in composition and temperature dimension , that have been reported in the literature and are mostly explained by the physically motivated structure of the spectral indirect hard modeling.…”

Section: Methodsmentioning

confidence: 99%

Integrated Humin Formation and Separation Studied In Situ by Centrifugation

Echtermeyer,

Viell

2024

ACS Omega

Self Cite

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We present a novel method for studying the integrated formation and separation of humins formed during the Brønsted acid-catalyzed conversion of fructose (here, at 90 °C with 20 wt % fructose and 5 wt % sulfuric acid). For the first time, we report the reaction carried out in situ during systematic centrifugation experiments, which allows combining humin formation and separation along with investigation of the phase behavior of humins. Analysis of the formed humin deposits employing scanning electron microscopy reveals deposits that are formed from a layer of monodisperse microspheres with a narrow diameter range of 0.9−1.9 μm. In the centrifugal force field, the microspheres partially coalesce, which increases with time and relative centrifugal force up to the formation of a thin and uniform layer of microspheres covering a continuous humin bulk phase with 80−90 μm thickness. These findings give evidence that humin spheres are highly viscous droplets rather than solid particles during formation. Our result is in line with the often-reported spherical and planar deposits formed during acidic carbohydrate conversion in technical systems and supports the development of strategies for deposit prevention, on the one hand, and humin preparation for material utilization, on the other hand.

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In‐line monitoring of hydrogen peroxide in two‐phase reactions using raman spectroscopy

Cited by 7 publications

References 31 publications

Se site targeted-two circles antioxidant in GPx4–like catalytic peroxide degradation by polyphenols (−)-epigallocatechin gallate and genistein using SERS

Se site targeted-two circles antioxidant in GPx4–like catalytic peroxide degradation by polyphenols (−)-epigallocatechin gallate and genistein using SERS

Application of Raman Spectroscopy for In-Line Measurement of Dispersion Uniformity of Polypropylene–Polystyrene Blends During Melt Extrusion

Integrated Humin Formation and Separation Studied In Situ by Centrifugation

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