Your search keyword '"Sommertune, J"' showing total 11 results

1. Impact of protein surface coverage and layer thickness on rehydration characteristics of milk serum protein/lactose powder particles

Author

Andersson, I.M., Millqvist-Fureby, A., Sommertune, J., Alexander, M., Hellström, N., Glantz, M., Paulsson, M., and Bergenståhl, B.

Published

2019

2. Carbon Fibers from Lignin-Cellulose Precursors : Effect of Carbonization Conditions

Author

Bengtsson, Andreas, Hecht, P., Sommertune, J., Ek, Monica, Sedin, M., Sjöholm, E., Bengtsson, Andreas, Hecht, P., Sommertune, J., Ek, Monica, Sedin, M., and Sjöholm, E.

Abstract

Carbon fibers (CFs) are gaining increasing importance in lightweight composites, but their high price and reliance on fossil-based raw materials stress the need for renewable and cost-efficient alternatives. Kraft lignin and cellulose are renewable macromolecules available in high quantities, making them interesting candidates for CF production. Dry-jet wet spun precursor fibers (PFs) from a 70/30 w/w blend of softwood kraft lignin (SKL) and fully bleached softwood kraft pulp (KP) were converted into CFs under fixation. The focus was to investigate the effect of carbonization temperature and time on the CF structure and properties. Reducing the carbonization time from 708 to 24 min had no significant impact on the tensile properties. Increasing the carbonization temperature from 600 to 800 °C resulted in a large increase in the carbon content and tensile properties, suggesting that this is a critical region during carbonization of SKL:KP PFs. The highest Young's modulus (77 GPa) was obtained after carbonization at 1600 °C, explained by the gradual transition from amorphous to nanocrystalline graphite observed by Raman spectroscopy. On the other hand, the highest tensile strength (1050 MPa) was achieved at 1000 °C, a decrease being observed thereafter, which may be explained by an increase in radial heterogeneity., QC 20200611

Published

2020

3. The impact of N,N-dimethyldodecylamine N-oxide (DDAO) concentration on the crystallisation of sodium dodecyl sulfate (SDS) systems and the resulting changes to viscosity, crystal structure, shape and the kinetics of crystal growth

Author

Summerton, E, Hollamby, M, Zimbitas, G, Snow, T, Smith, A, Sommertune, J, Bettiol, J, Jones, C, Britton, M, and Bakalis, S

Subjects

QD, TP155

Abstract

Hypothesis\ud At low temperatures stability issues arise in commercial detergent products when surfactant crystallisation occurs, a process which is not currently well-understood. An understanding of the phase transition can be obtained using a simple binary SDS (sodium dodecyl sulfate) + DDAO (N,N-dimethyldodecylamine N-oxide) aqueous system. It expected that the crystallisation temperature of an SDS system can be lowered with addition of DDAO, thus providing a route to improve detergent stability.\ud \ud Experiments\ud Detergent systems are typically comprised of anionic surfactants, non-ionic surfactants and water. This study explores the crystallisation of a three component system consisting of sodium dodecyl sulfate (SDS), N,N–dimethyldodecylamine N-oxide (DDAO), and water using wide-angle X-ray scattering (WAXS), differential scanning calorimetry (DSC) and confocal Raman microscopy.\ud \ud Findings\ud The presence of DDAO lowered the crystallisation temperature of a 20 wt% SDS system. For all aqueous mixtures of SDS + DDAO at low temperatures, SDS hydrated crystals, SDS.1/2H2O or SDS·H2O, formed. SDS hydrates comprising of layers of SDS separated by water layers. DDAO tended to reside in the vicinity of these SDS crystals. In the absence of DDAO an additional intermediary hydrate structure, SDS.1/8H2O, formed whereas for mixed SDS + DDAO systems no such structure was detected during crystallisation.

Published

2018

4. Standardization methods for the synthesis of single-core and multi-core magnetic nanoparticles for medical applications

Author

Gavilán, Helena, Costo, Rocío, Heinke, D., Sugunan, A., Sommertune, J., Fornara, A., Gehrke, N., Grüttner, C., Westphal, F., Veintemillas-Verdaguer, S., Johansson, and Morales, M. P.

Abstract

Oral presentation given at the International Magnetics Conference (INTERMAG Europe 2017), held in Dublin (Ireland) on April 24-28th, 2017., The number of biomedical applications using colloidal magnetic iron oxide nanoparticles has been increasing exponentially over the past few years [1]. Several approaches exist to obtain single-core and multi-core particles but the production of particles with good control of the number of magnetic cores per particle, and the degree of polydispersity of both, particle and core sizes is still a difficult task [2-5]. In addition, the magnetic properties of the nanoparticles may change significantly depending on their aggregation degree (and further agglomeration), which depends to a large extent on the synthesis method [6]. The complexity of the problem of understanding the different magnetic properties of single-core and multi-core nanoparticles underlies the importance of reliable synthesis methods able to reproduce nanoparticle size, shape and structural homogeneity. Here, we present different synthesis strategies in organic, polyol and aqueous media for colloidal single-core and multi-core iron oxide nanoparticles for biomedical applications (Fig. 1). We explore the factors determining the monodispersity in terms of size and shape and the core assembly, and discuss their implication on the resulting structural, colloidal and magnetic properties. We will show that reliable and reproducible analysis methods are also needed to characterize the different magnetic particle systems [7]. For example, in order to compare size parameters precisely determined from different methods and models, it is crucial to establish standardized analysis methods and models to extract reliable parameters from the data, which are necessary both for defining magnetic nanoparticle systems and for quality control during the synthesis of magnetic nanoparticles. Many parameters of the synthesis procedure may have a strong effect on the particles obtained, including temperature, reaction time, reagent concentrations, and stirring conditions. This is one of the reasons why scaling-up of some of these synthesis routes is extremely complicated. Indeed, one of the difficulties that particle synthesis faces is batch-to batch reproducibility. Other important difficulty is the fundamental and pressing need to develop more sustainable protocols, using less toxic reagents in a more efficacious manner.

Published

2017

5. Structural and magnetic properties of multi-core nanoparticles analysed using a generalised numerical inversion method

Author

Bender, P., primary, Bogart, L. K., additional, Posth, O., additional, Szczerba, W., additional, Rogers, S. E., additional, Castro, A., additional, Nilsson, L., additional, Zeng, L. J., additional, Sugunan, A., additional, Sommertune, J., additional, Fornara, A., additional, González-Alonso, D., additional, Barquín, L. Fernández, additional, and Johansson, C., additional

Published

2017

6. SERS Hotspot Engineering by Aerosol Self-Assembly of Plasmonic Ag Nanoaggregates with Tunable Interparticle Distance.

Author

Li H, Merkl P, Sommertune J, Thersleff T, and Sotiriou GA

Subjects

Aerosols, Reproducibility of Results, Silver chemistry, Spectrum Analysis, Raman methods, Metal Nanoparticles chemistry

Abstract

Surface-enhanced Raman scattering (SERS) is a powerful sensing technique. However, the employment of SERS sensors in practical applications is hindered by high fabrication costs from processes with limited scalability, poor batch-to-batch reproducibility, substrate stability, and uniformity. Here, highly scalable and reproducible flame aerosol technology is employed to rapidly self-assemble uniform SERS sensing films. Plasmonic Ag nanoparticles are deposited on substrates as nanoaggregates with fine control of their interparticle distance. The interparticle distance is tuned by adding a dielectric spacer during nanoparticle synthesis that separates the individual Ag nanoparticles within each nanoaggregate. The dielectric spacer thickness dictates the plasmonic coupling extinction of the deposited nanoaggregates and finely tunes the Raman hotspots. By systematically studying the optical and morphological properties of the developed SERS surfaces, structure-performance relationships are established and the optimal hot-spots occur for interparticle distance of 1 to 1.5 nm among the individual Ag nanoparticles, as also validated by computational modeling, are identified for the highest signal enhancement of a molecular Raman reporter. Finally, the superior stability and batch-to-batch reproducibility of the developed SERS sensors are demonstrated and their potential with a proof-of-concept practical application in food-safety diagnostics for pesticide detection on fruit surfaces is explored., (© 2022 The Authors. Advanced Science published by Wiley-VCH GmbH.)

Published

2022

7. The role of water in the reversibility of thermal denaturation of lysozyme in solid and liquid states.

Author

Phan-Xuan T, Bogdanova E, Sommertune J, Fureby AM, Fransson J, Terry AE, and Kocherbitov V

Abstract

Although unfolding of protein in the liquid state is relatively well studied, its mechanisms in the solid state, are much less understood. We evaluated the reversibility of thermal unfolding of lysozyme with respect to the water content using a combination of thermodynamic and structural techniques such as differential scanning calorimetry, synchrotron small and wide-angle X-ray scattering (SWAXS) and Raman spectroscopy. Analysis of the endothermic thermal transition obtained by DSC scans showed three distinct unfolding behaviors at different water contents. Using SWAXS and Raman spectroscopy, we investigated reversibility of the unfolding for each hydration regime for various structural levels including overall molecular shape, secondary structure, hydrophobic and hydrogen bonding interactions. In the substantially dehydrated state below 37 wt% of water the unfolding is an irreversible process and can be described by a kinetic approach; above 60 wt% the process is reversible, and the thermodynamic equilibrium approach is applied. In the intermediate range of water contents between 37 wt% and 60 wt%, the system is phase separated and the thermal denaturation involves two processes: melting of protein crystals and unfolding of protein molecules. A phase diagram of thermal unfolding/denaturation in lysozyme - water system was constructed based on the experimental data., Competing Interests: We declare no conflict of interest., (© 2021 The Authors.)

Published

2021

8. Surfactant-Free Stabilization of Aqueous Graphene Dispersions Using Starch as a Dispersing Agent.

Author

Zhao W, Sugunan A, Gillgren T, Larsson JA, Zhang ZB, Zhang SL, Nordgren N, Sommertune J, and Ahniyaz A

Abstract

Attention to graphene dispersions in water with the aid of natural polymers is increasing with improved awareness of sustainability. However, the function of biopolymers that can act as dispersing agents in graphene dispersions is not well understood. In particular, the use of starch to disperse pristine graphene materials deserves further investigation. Here, we report the processing conditions of aqueous graphene dispersions using unmodified starch. We have found that the graphene content of the starch-graphene dispersion is dependent on the starch fraction. The starch-graphene sheets are few-layer graphene with a lateral size of 3.2 μm. Furthermore, topographical images of these starch-graphene sheets confirm the adsorption of starch nanoparticles with a height around 5 nm on the graphene surface. The adsorbed starch nanoparticles are ascribed to extend the storage time of the starch-graphene dispersion up to 1 month compared to spontaneous aggregation in a nonstabilized graphene dispersion without starch. Moreover, the ability to retain water by starch is reduced in the presence of graphene, likely due to environmental changes in the hydroxyl groups responsible for starch-water interactions. These findings demonstrate that starch can disperse graphene with a low oxygen content in water. The aqueous starch-graphene dispersion provides tremendous opportunities for environmental-friendly packaging applications., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

9. Functionalized magnetic particles for water treatment.

Author

Baresel C, Schaller V, Jonasson C, Johansson C, Bordes R, Chauhan V, Sugunan A, Sommertune J, and Welling S

Abstract

In this study, we have taken the concept of water treatment by functionalized magnetic particles one step forward by integrating the technology into a complete proof of concept, which included the preparation of surface modified beads, their use as highly selective absorbents for heavy metals ions (Zinc, Nickel), and their performance in terms of magnetic separation. The separation characteristics were studied both through experiments and by simulations. The data gathered from these experimental works enabled the elaboration of various scenarios for Life Cycle Analysis (LCA). The LCA showed that the environmental impact of the system is highly dependent on the recovery rate of the magnetic particles. The absolute impact on climate change varied significantly among the scenarios studied and the recovery rates. The results support the hypothesis that chelation specificity, magnetic separation and bead recovery should be optimized to specific targets and applications.

Published

2019

10. The impact of N,N-dimethyldodecylamine N-oxide (DDAO) concentration on the crystallisation of sodium dodecyl sulfate (SDS) systems and the resulting changes to crystal structure, shape and the kinetics of crystal growth.

Author

Summerton E, Hollamby MJ, Zimbitas G, Snow T, Smith AJ, Sommertune J, Bettiol J, Jones C, Britton MM, and Bakalis S

Abstract

Hypothesis: At low temperatures stability issues arise in commercial detergent products when surfactant crystallisation occurs, a process which is not currently well-understood. An understanding of the phase transition can be obtained using a simple binary SDS (sodium dodecyl sulfate) + DDAO (N,N-dimethyldodecylamine N-oxide) aqueous system. It expected that the crystallisation temperature of an SDS system can be lowered with addition of DDAO, thus providing a route to improve detergent stability., Experiments: Detergent systems are typically comprised of anionic surfactants, non-ionic surfactants and water. This study explores the crystallisation of a three component system consisting of sodium dodecyl sulfate (SDS), N,N-dimethyldodecylamine N-oxide (DDAO), and water using wide-angle X-ray scattering (WAXS), differential scanning calorimetry (DSC) and confocal Raman microscopy., Findings: The presence of DDAO lowered the crystallisation temperature of a 20 wt% SDS system. For all aqueous mixtures of SDS + DDAO at low temperatures, SDS hydrated crystals, SDS.1/2H 2 O or SDS·H 2 O, formed. SDS hydrates comprising of layers of SDS separated by water layers. DDAO tended to reside in the vicinity of these SDS crystals. In the absence of DDAO an additional intermediary hydrate structure, SDS.1/8H 2 O, formed whereas for mixed SDS + DDAO systems no such structure was detected during crystallisation., (Copyright © 2018. Published by Elsevier Inc.)

Published

2018

11. Polymer/Iron Oxide Nanoparticle Composites--A Straight Forward and Scalable Synthesis Approach.

Author

Sommertune J, Sugunan A, Ahniyaz A, Bejhed RS, Sarwe A, Johansson C, Balceris C, Ludwig F, Posth O, and Fornara A

Subjects

Magnetic Resonance Imaging methods, Particle Size, Ferric Compounds chemistry, Magnetite Nanoparticles chemistry, Polymers chemistry

Abstract

Magnetic nanoparticle systems can be divided into single-core nanoparticles (with only one magnetic core per particle) and magnetic multi-core nanoparticles (with several magnetic cores per particle). Here, we report multi-core nanoparticle synthesis based on a controlled precipitation process within a well-defined oil in water emulsion to trap the superparamagnetic iron oxide nanoparticles (SPION) in a range of polymer matrices of choice, such as poly(styrene), poly(lactid acid), poly(methyl methacrylate), and poly(caprolactone). Multi-core particles were obtained within the Z-average size range of 130 to 340 nm. With the aim to combine the fast room temperature magnetic relaxation of small individual cores with high magnetization of the ensemble of SPIONs, we used small (<10 nm) core nanoparticles. The performed synthesis is highly flexible with respect to the choice of polymer and SPION loading and gives rise to multi-core particles with interesting magnetic properties and magnetic resonance imaging (MRI) contrast efficacy.

Published

2015